Abstract: An electronic component includes a semiconductor chip and a leadframe. The leadframe includes a metal coating pattern on its underside to facilitate the application of solder to the electronic component. The metal coating pattern includes wetting regions that are wettable with solder material and anti-wetting regions that are unwettable with solder material, and the electronic component includes solder deposits formed on the wetting regions on the underside of the component.

Abstract: An electronic component includes a semiconductor chip with a chip topside, an integrated circuit, and a chip backside. The chip backside includes a magnetic layer. The electronic component further includes a chip carrier with a magnetic layer on its carrier topside. At least one of the two magnetic layers is permanently magnetic such that the semiconductor chip is magnetically fixed on the chip carrier.

Abstract: One embodiment of the invention relates to an electronic component having stacked semiconductor chips, and to a panel for production of the component. In one case, the stack has a flat conductor structure with a chip island on which a stacked semiconductor chip is arranged, while a first semiconductor chip is located underneath it. The chip island is surrounded by flat conductors which have contact pillars. These contact pillars have pillar contact pads which, together with the active upper face of the first semiconductor chip and the upper face areas of a plastic encapsulation compound form a coplanar overall upper face.

Abstract: The invention relates to an electronic module having plug contacts, which has a semiconductor chip embedded in a plastics composition with its rear side and its edge sides. An active top side of the semiconductor chip forms, together with the plastics composition, an overall top side, there being arranged on the latter a rewiring layer with plug contact areas and rewiring lines that connect the plug contact areas to contact areas of the top side of the semiconductor chip.

Abstract: The invention relates to an electronic component and a semiconductor wafer, and a method for producing them. The semiconductor wafer has strip-type separating regions. The separating regions are provided with through contacts in the direction of the rear side of the semiconductor wafer. The semiconductor chip separated from such a semiconductor wafer constitutes an electronic component with external contacts in the form of edge contacts. Such an electronic component of semiconductor chip size can be used in diverse ways.

Abstract: The description relates to gas-discharge lamps having electrode structures for dielectrically inhibited discharges, in which the electrodes are divided into separately operable groups for independently switchable operation.

Abstract: This application relates to a discharge lamp for producing dielectric impediments which has a new electrode configuration with a meandering shape. In this case, either the anode(s) or both the anode(s) and the cathode(s) are of meandering shape.

Abstract: A method for coating lamp tubes in which a local drying zone tracks a liquid level of the coating material at a constant time interval. The local drying zone may be a heater or air outlet that moves in coordination with the liquid level.

Abstract: The invention relates to a method for operating a discharge lamp, which has at least one dielectrically impeded electrode (2, 3), on a flyback converter, which applies periodically recurring voltage pulses to the discharge lamp (La1). If the discharge lamp (La1) has a starting aid (10), the voltage amplitude (US) of the voltage pulses is successively raised until a dielectrically impeded discharge is formed in the discharge lamp, and until the voltage amplitude (US) has reached the nominal operating voltage. If the discharge lamp (La1) has no starting aid, a first discharge which causes a partial ionization of the discharge medium is firstly ignited in the discharge lamp (La1). Immediately after the first discharge has been brought back to extinction, a dielectrically impeded discharge is ignited anew, and the voltage amplitude (US) of the voltage pulses is increased until the nominal operating voltage of the discharge lamp (La1) is reached.

Abstract: The invention relates to a method for operating a discharge lamp, which has at least one dielectrically impeded electrode (2, 3), on a flyback converter, which applies periodically recurring voltage pulses to the discharge lamp (La1). If the discharge lamp (La1) has a starting aid (10), the voltage amplitude (US) of the voltage pulses is successively raised until a dielectrically impeded discharge is formed in the discharge lamp, and until the voltage amplitude (US) has reached the nominal operating voltage. If the discharge lamp (La1) has no starting aid, a first discharge which causes a partial ionization of the discharge medium is firstly ignited in the discharge lamp (La1). Immediately after the first discharge has been brought back to extinction, a dielectrically impeded discharge is ignited anew, and the voltage amplitude (US) of the voltage pulses is increased until the nominal operating voltage of the discharge lamp (La1) is reached.

Abstract: A flat radiator having dielectrically impeded, strip-like cathodes (12;15) and anodes (8;9a) which are arranged alternately next to one another on the wall of the discharge vessel (14) has in each case an additional anode (9b) between neighbouring cathodes (12;12,15), that is to say an anode pair (9) is arranged in each case between the cathodes (12;12,15). The cathodes (15) have nose-like extensions (28) which face the respectively neighbouring anodes (8) and are arranged more densely in a spatially increasing fashion in the direction of the edges (26,27) of the flat radiator (13). As an alternative or in addition thereto, the two anode strips (9a,9b) of each anode pair (9) are widened in the direction of the edges (26,27) of the flat radiator (13) at one end in the direction of the respective partner strip (9b or 9b). Owing to these measures, the surface luminous density of the flat radiator (13) is largely constant towards the edges (26,27,29,30) in pulsed operation.

Abstract: A gas discharge lamp having a discharge vessel (202) which is at least partially transparent and filled with a gas filling, a number of essentially strip-shaped anodes (205, 206) and cathodes (203, 204) which extend on the walls of the discharge vessel and essentially parallel to each other, and a dielectric layer (215) between at least the anodes and the gas filling for a dielectrically impeded discharge in the discharge vessel between neighboring anodes and cathodes, characterized in that at least one anode pair (205) is arranged between two cathodes (203, 204) respectively adjacent to one anode pair.

Abstract: A flat radiator (4), suitable for a dielectrically impeded discharge and with a discharge vessel (5) made from an electrically non-conducting material has strip-like electrodes (6, 7) arranged on the wall of the discharge vessel (5), cathodes (6) and anodes (7a) being arranged alternately next to one another, and at least the anodes being separated from the interior of the discharge vessel (5) by a dielectric material (10). In each case one additional anode (7b) is arranged between neighbouring cathodes (6), that is to say in each case one anode pair (7a, 7b) is arranged between the neighbouring cathodes (6). The result is a uniform discharge structure accompanied by optimum utilization of the discharge vessel. FIG.

Abstract: A fluorescent lamp (1) having a tubular discharge vessel (2), filled with ert gas, and a fluorescent layer (6) has elongated electrodes (3; 4; 12; 14a-14d) arranged parallel to the longitudinal axis of the tubular discharge vessel (2), at least one electrode (4; 12; 14a-14d) being arranged on the inner wall of the discharge vessel (2). The tubular discharge vessel (2) is sealed in a gas-tight fashion at one or at both ends with a stopper (8) and by means of solder (9), the at least one inner wall electrode (4) being guided to the outside in a gas-tight fashion through the solder (9). Alternatively or also in addition, at least one electrode (16) is arranged inside the wall of the discharge vessel (2). Up to a maximum of the entire inside diameter can be used as striking distance, depending on the positioning of the associated counterelectrode(s). High luminous densities are achieved because of the large and, at the same time, constant striking distance along the discharge tube.