Abstract: Disclosed is an electrode assembly, a battery, and a battery pack and a vehicle including the same. In the electrode assembly, a first electrode, a second electrode, and a separator interposed therebetween are wound based on a winding axis to define a core and an outer circumference. The first electrode includes a first active material portion coated with an active material layer and a first uncoated portion not coated with an active material layer along a winding direction. At least a part of the first uncoated portion is defined as an electrode tab by itself. The first uncoated portion includes a first portion adjacent to the core of the electrode assembly, a second portion adjacent to the outer circumference of the electrode assembly, and a third portion interposed between the first portion and the second portion. The first portion or the second portion has a smaller height than the third portion in the winding axis direction.

Abstract: Disclosed is an electrode assembly, a battery, and a battery pack and a vehicle including the same. In the electrode assembly, a first electrode, a second electrode, and a separator interposed therebetween are wound based on an axis to define a core and an outer circumference. The first electrode includes an uncoated portion at a long side end thereof and exposed out of the separator along a winding axis direction of the electrode assembly. A part of the uncoated portion is bent in a radial direction of the electrode assembly to form a bending surface region that includes overlapping layers of the uncoated portion, and in a partial region of the bending surface region, the number of stacked layers of the uncoated portion is 10 or more in the winding axis direction of the electrode assembly.

Abstract: A high-voltage battery control apparatus includes a plurality of high-voltage battery controllers configured to respectively monitor states of a plurality of high-voltage batteries included in one high-voltage battery pack depending on a predetermined period for monitoring the high-voltage battery pack, wherein the high-voltage battery controllers are configured to transition state of the plurality of high-voltage battery controllers together to an end state when a high-voltage battery controller among the high-voltage battery controllers, which has completed a monitoring operation, first waits until all monitoring operations of the high-voltage battery controllers that have not yet completed monitoring operations are completed and then all the monitoring operations of the high-voltage battery controllers are completed.

Abstract: A recombinant vector according to an embodiment is for genome editing without inserting a replicon into the plant genome in a T0 generation plant. The recombinant vector includes a geminivirus-based replicon between the sequence of LB (left border) and sequence of RB (right border) of Ti plasmid. A method of genome editing without inserting a replicon into the plant genome in a T0 generation plant according to an embodiment includes transforming a plant cell by inserting a foreign gene to the aforementioned recombinant vector.

Abstract: An exemplary embodiment provides an intruder detection method capable of accurately detecting an intruder and estimating an abnormal behavior of the intruder even when viewpoints of acquired images are different from each other. An intruder detection method is suitable for being performed by an intruder detection device for detecting an intruder based on images and includes: receiving input images acquired by multiple cameras; extracting feature maps associated with a plurality of viewpoints by applying the input images to a plurality of convolutional neural networks provided separately for the plurality of viewpoints of the images; and detecting the intruder based on the feature maps associated with the plurality of viewpoints.

Abstract: A semiconductor device can include a semiconductor chip, a protective layer pattern, an under bump metallurgy (UBM) layer, and conductive bumps. The semiconductor chip can include a pad and a guard ring. The protective layer pattern can be formed on the semiconductor chip to expose the pad and the guard ring. The UBM layer can be formed on the protective layer and can directly make contact with the pad and the guard ring. The conductive bumps can be formed on a portion of the UBM layer on the pad. Thus, the UBM layer and the guard ring can directly make contact with each other, so that a uniform current can be provided to the UBM layer on the pad regardless of a thick difference of different portions of the UBM layer.

Abstract: A semiconductor device can include a semiconductor chip, a protective layer pattern, an under bump metallurgy (UBM) layer, and conductive bumps. The semiconductor chip can include a pad and a guard ring. The protective layer pattern can be formed on the semiconductor chip to expose the pad and the guard ring. The UBM layer can be formed on the protective layer and can directly make contact with the pad and the guard ring. The conductive bumps can be formed on a portion of the UBM layer on the pad. Thus, the UBM layer and the guard ring can directly make contact with each other, so that a uniform current can be provided to the UBM layer on the pad regardless of a thick difference of different portions of the UBM layer.

Abstract: A semiconductor device can include a semiconductor chip, a protective layer pattern, an under bump metallurgy (UBM) layer, and conductive bumps. The semiconductor chip can include a pad and a guard ring. The protective layer pattern can be formed on the semiconductor chip to expose the pad and the guard ring. The UBM layer can be formed on the protective layer and can directly make contact with the pad and the guard ring. The conductive bumps can be formed on a portion of the UBM layer on the pad. Thus, the UBM layer and the guard ring can directly make contact with each other, so that a uniform current can be provided to the UBM layer on the pad regardless of a thick difference of different portions of the UBM layer.

Abstract: Erasure methods for a nonvolatile memory cell that includes a gate electrode on a substrate, source and drain regions in the substrate at respective sides of the gate electrode, and a charge storage layer interposed between the gate electrode and the substrate. A nonzero first voltage is applied to the source region starting at a first time. While continuing to apply the first nonzero voltage to the source region, a second voltage having an opposite polarity to the first voltage is applied to the gate electrode starting at a second time later than the first time. The second voltage may increase in magnitude, e.g., stepwise, linearly and/or along a curve, after the second time.

Abstract: A nonvolatile memory device and method thereof are provided. The example method may include applying a first bias voltage to a gate electrode, applying a second bias voltage to a substrate to obtain a first voltage potential difference between the gate electrode and the substrate and applying a third bias voltage to a first impurity region to obtain a second voltage potential difference between the substrate and the first impurity region, the first and third bias voltages being positive and the second bias voltage being negative.

Abstract: Erasure methods are provided for a nonvolatile memory cell that includes a gate electrode on a substrate, source and drain regions in the substrate at respective sides of the gate electrode, and a charge storage layer interposed between the gate electrode and the substrate. A nonzero first voltage is applied to the source region starting at a first time. While continuing to apply the first nonzero voltage to the source region, a second voltage having an opposite polarity to the first voltage is applied to the gate electrode starting at a second time later than the first time. The second voltage may increase in magnitude, e.g., stepwise, linearly and/or along a curve, after the second time.