Abstract: An adding apparatus according to an example of the present invention comprises: a time adder for outputting a time addition signal using time information of the first input signal and time information of the second input signal, if a first input signal synchronized according to a unit time delay and a second input signal synchronized with the unit time delay; and a carry digit processor for outputting a carry generation signal by conducting a carry-lookahead operation corresponding to the time addition signal according to the unit time delay.

Abstract: A liquid crystal display (LCD) device. The liquid crystal display device comprises a data driver including a first data driving unit, which is connected to first through third data lines, and a second data driving unit, which is connected to fourth through sixth data lines, a display panel including a first pixel group, which has first through third pixel units that are connected to the first data driving unit via the first through third data lines, respectively, and a second pixel group, which has fourth through sixth pixel units that are connected to the second data driving unit via the fourth through sixth data lines, respectively; and a switching circuit unit including a first transistor, a second transistor, and a third transistor, which is connected between the third and sixth data lines.

Abstract: The present invention relates to a novel dual-targeting protein comprising: a protein that binds specifically to delta-like ligand 4 (DLL4); and an antibody that binds specifically to vascular endothelial cell growth factor (VEGF).

Abstract: A display device may include a display panel, a light source configured to provide light to the display panel, a bottom chassis in which the light source is located, a top chassis coupled to the bottom chassis and covering an edge of the display panel, and a conductive tape attached to the bottom chassis and the top chassis. The conductive tape may have an uneven pattern.

Abstract: A timing controller includes: a top voltage generator configured to output first to third top voltages; a bottom voltage generator configured to output first to third bottom voltages; a first transmitting part configured to output a first data signal for a first data driving chip, based on the first top and bottom voltages; a second transmitting part configured to output a second data signal for a second data driving chip based on the second top and bottom voltages; and a third transmitting part configured to output a third data signal for a third data driving chip based on the third top and bottom voltages, where one of the first to third top voltages is different from another of the first to third top voltages, and one of the first to third bottom voltages is different from another of the first to third bottom voltages.

Abstract: A display device includes a display panel including a display area and a non-display area, a plurality of driver integrated circuits mounted on the non-display area of the display panel by a COG method, a printed circuit board (PCB) configured to provide a signal to the plurality of driver integrated circuits, and a flexible printed circuit (FPC) configured to transfer the signal from the PCB to the plurality of driver integrated circuits. The FPC has a first end portion and a second end portion opposite to the first end portion. The first end portion is attached on the non-display area of the display panel by a FOG method, and the second end portion is attached on the PCB. A width of the second end portion is different from a width of the first end portion.

Abstract: The present invention relates to a novel monoclonal antibody that binds specifically to delta-like ligand (DLL4), and more particularly to a monoclonal antibody that binds specifically to human delta-like ligand 4 to effectively inhibit the interaction between delta-like ligand 4 and Notch receptor, a polynucleotide encoding the monoclonal antibody, an expression vector comprising the polynucleotide, a transformant comprising the expression vector, a method for preparing the monoclonal antibody, a pharmaceutical composition for preventing or treating cancer comprising the monoclonal antibody, a composition for diagnosing cancer comprising the monoclonal antibody, a method for diagnosing cancer using the monoclonal antibody, and a pharmaceutical composition for preventing or treating autoimmune disease comprising the monoclonal antibody.

Abstract: A timing controller includes: a top voltage generator configured to output first to third top voltages; a bottom voltage generator configured to output first to third bottom voltages; a first transmitting part configured to output a first data signal for a first data driving chip, based on the first top and bottom voltages; a second transmitting part configured to output a second data signal for a second data driving chip based on the second top and bottom voltages; and a third transmitting part configured to output a third data signal for a third data driving chip based on the third top and bottom voltages, where one of the first to third top voltages is different from another of the first to third top voltages, and one of the first to third bottom voltages is different from another of the first to third bottom voltages.

Abstract: A converter includes a feedback part, a pulse width modulation (PWM) controller and a PWM generator. The feedback part is configured to output a feedback signal based on a driving voltage. The PWM controller is configured to output a PWM control signal based on the feedback signal and a first compensation signal. The PWM generator is configured to control the driving voltage based on the PWM control signal. The first compensation signal is determined according to an occurrence of a predetermined pattern of an input image data.

Abstract: A semiconductor package is presented which has a suitable structure for effectively shielding electromagnetic wave interference (EMI) in a cavity area to which a semiconductor chip is attached. The semiconductor package is assembled such that a lower substrate to which the semiconductor chip is attached is adhered to an EMI shielding & electric I/O body having various types of EMI shielding & electric I/O metal patterns by soldering. Further, the EMI shielding & electric I/O body is adhered to an upper substrate by soldering thereby simplifying assembling of the semiconductor package.

Abstract: An apparatus and a method for a cluster-based power control at a macro base station in a wireless communication system are provided. The method includes broadcasting an interference allowance value determined based on a predefined aggregate interference to a femto cell, updating the interference allowance value with consideration of a channel activity for each femto cell group on a cluster basis, and when detecting a change in an aggregate interference generated due to femto cell power allocation, repeating determination of an interference allowance value so that a Quality of Service (QoS) of a macro cell user is met, and broadcasting the interference allowance value to a femto cell.

Abstract: An apparatus and operation method of a Base Station (BS) for allocating a radio resource in a Cognitive Radio (CR) wireless communication system includes, when a licensed system is activated, determining whether each of User Terminals (UTs) located in a cell satisfies Quality of Service (QoS). If all of the UTs satisfy the QoS, a binary message indicating ‘on’ is broadcasted to neighbor BSs. If at least one of the UTs does not satisfy the QoS, a binary message indicating ‘off’ is broadcasted to the neighbor BSs, and when the binary message indicating ‘off’ is received from at least one of the neighbor BSs, the binary message indicating ‘off’ is broadcasted to the UTs.

Abstract: The present invention relates to a data transmission/receiving method and apparatus for overcoming interference between multiple data streams, by relaying only part of multiple data streams that are received from a source node during collaborative data transmission employing relay nodes. The multiple data stream transmission method of the present invention comprises: receiving a plurality of data streams from a source node; decoding the plurality of data streams received; selecting a portion of the successful decoded data streams; encoding the selected portion of the data streams; and sending the encoded data stream portion to a destination node.

Abstract: A semiconductor device has a semiconductor die having a first surface and a second surface wherein at least one bond pad is formed on the first surface. A passivation layer is formed on the first surface of the semiconductor device, wherein a central area of the at least one bond is exposed. A seed layer is formed on exposed portions of the bond pad and the passivation layer. A conductive pillar is formed on the seed layer. The conductive pillar has a base portion wherein the base portion has a diameter smaller than the seed layer and a stress relief portion extending from a lateral surface of a lower section of the base portion toward distal ends of the seed layer. A solder layer is formed on the conductive pillar.

Abstract: A semiconductor device has a semiconductor die having a first surface and a second surface wherein at least one bond pad is formed on the first surface. A passivation layer is formed on the first surface of the semiconductor device, wherein a central area of the at least one bond is exposed. A seed layer is formed on exposed portions of the bond pad and the passivation layer. A conductive pillar is formed on the seed layer. The conductive pillar has a base portion wherein the base portion has a diameter smaller than the seed layer and a stress relief portion extending from a lateral surface of a lower section of the base portion toward distal ends of the seed layer. A solder layer is formed on the conductive pillar.

Abstract: A semiconductor device has a semiconductor die having a first surface and a second surface wherein at least one bond pad is formed on the first surface. A passivation layer is formed on the first surface of the semiconductor device, wherein a central area of the at least one bond is exposed. A seed layer is formed on exposed portions of the bond pad and the passivation layer. A conductive pillar is formed on the seed layer. The conductive pillar has a base portion wherein the base portion has a diameter smaller than the seed layer and a stress relief portion extending from a lateral surface of a lower section of the base portion toward distal ends of the seed layer. A solder layer is formed on the conductive pillar.

Abstract: An apparatus and a method for a cluster-based power control at a macro base station in a wireless communication system are provided. The method includes broadcasting an interference allowance value determined based on a predefined aggregate interference to a femto cell, updating the interference allowance value with consideration of a channel activity for each femto cell group on a cluster basis, and when detecting a change in an aggregate interference generated due to femto cell power allocation, repeating determination of an interference allowance value so that a Quality of Service (QoS) of a macro cell user is met, and broadcasting the interference allowance value to a femto cell.

Abstract: The present invention relates to a data transmission/receiving method and apparatus for overcoming interference between multiple data streams, by relaying only part of multiple data streams that are received from a source node during collaborative data transmission employing relay nodes. The multiple data stream transmission method of the present invention comprises: receiving a plurality of data streams from a source node; decoding the plurality of data streams received; selecting a portion of the successful decoded data streams; encoding the selected portion of the data streams; and sending the encoded data stream portion to a destination node.

Abstract: There are provided a method and apparatus for an effective multi-cell interference control service, to make it possible for users located at a cell boundary to dynamically select a suitable interference control technique by monitoring interference information collected by user terminals and network conditions of a serving base station and adjacent base stations to solve co-channel interference by adjacent cell users.

Abstract: An apparatus and operation method of a Base Station (BS) for allocating a radio resource in a Cognitive Radio (CR) wireless communication system includes, when a licensed system is activated, determining whether each of User Terminals (UTs) located in a cell satisfies Quality of Service (QoS). If all of the UTs satisfy the QoS, a binary message indicating ‘on’ is broadcasted to neighbor BSs. If at least one of the UTs does not satisfy the QoS, a binary message indicating ‘off’ is broadcasted to the neighbor BSs, and when the binary message indicating ‘off’ is received from at least one of the neighbor BSs, the binary message indicating ‘off’ is broadcasted to the UTs.