Abstract: Provided are a method for generating a summary and a system therefor. The method according to some embodiments may include calculating a likelihood loss for a summary model using a first text sample and a first summary sentence corresponding to the first text sample, calculating an unlikelihood loss for the summary model using a second text sample and the first summary sentence, the second text sample being a negative sample generated from the first text sample, and updating the summary model based on the likelihood loss and the unlikelihood loss.

Abstract: A method for transmitting specific data whose data format is unknown at a relay from a first blockchain network to a second blockchain network via the relay is provided. The method includes steps of: the relay (a) in response to detecting that a blockchain communication message for transmitting the specific data from the first blockchain network following a first data format to the second blockchain network following a second data format is generated, generating a relay message including the blockchain communication message and verification information; and (b) transmitting the relay message to the second blockchain network, thereby instructing the second blockchain network to (i) verify the relay message by using the verification information included in the relay message and (ii) convert the specific data included in the relay message into the second data format to generate converted specific data and then transmit the converted specific data to a receiving party.

Abstract: An electrostatic discharge (ESD) protection device includes an N-type laterally diffused metal oxide semiconductor (LDMOS) transistor including a source electrode, a gate electrode, and a well bias electrode that are connected to a first pad receiving a first voltage, and a drain electrode connected to a middle node. The ESD protection device further includes a silicon controlled rectifier (SCR) connected between the middle node and a second pad receiving a second voltage higher than the first voltage.

Abstract: In an ESD protection device, a first well of a first conductivity type and a second well of a second conductivity type are formed in a substrate to contact each other. A first impurity region of the first conductivity type and a second impurity region of the second conductivity type are formed in the first well, and are electrically connected to a first electrode pad. The second impurity region is spaced apart from the first impurity region in a direction of the second well. A third impurity region is formed in the second well, has the second conductivity type, and is electrically connected to a second electrode pad. A fourth impurity region is formed in the second well, is located in a direction of the first well from the third impurity region to contact the third impurity region, has the first conductivity type, and is electrically floated.

Abstract: In an ESD protection device, a first well of a first conductivity type and a second well of a second conductivity type are formed in a substrate to contact each other. A first impurity region of the first conductivity type and a second impurity region of the second conductivity type are formed in the first well, and are electrically connected to a first electrode pad. The second impurity region is spaced apart from the first impurity region in a direction of the second well. A third impurity region is formed in the second well, has the second conductivity type, and is electrically connected to a second electrode pad. A fourth impurity region is formed in the second well, is located in a direction of the first well from the third impurity region to contact the third impurity region, has the first conductivity type, and is electrically floated.

Abstract: In an ESD protection device, a first well of a first conductivity type and a second well of a second conductivity type are formed in a substrate to contact each other. A first impurity region of the first conductivity type and a second impurity region of the second conductivity type are formed in the first well, and are electrically connected to a first electrode pad. The second impurity region is spaced apart from the first impurity region in a direction of the second well. A third impurity region is formed in the second well, has the second conductivity type, and is electrically connected to a second electrode pad. A fourth impurity region is formed in the second well, is located in a direction of the first well from the third impurity region to contact the third impurity region, has the first conductivity type, and is electrically floated.

Abstract: An electrostatic discharge (ESD) protection device includes an N-type laterally diffused metal oxide semiconductor (LDMOS) transistor including a source electrode, a gate electrode, and a well bias electrode that are connected to a first pad receiving a first voltage, and a drain electrode connected to a middle node. The ESD protection device further includes a silicon controlled rectifier (SCR) connected between the middle node and a second pad receiving a second voltage higher than the first voltage.

Abstract: In an ESD protection device, a first well of a first conductivity type and a second well of a second conductivity type are formed in a substrate to contact each other. A first impurity region of the first conductivity type and a second impurity region of the second conductivity type are formed in the first well, and are electrically connected to a first electrode pad. The second impurity region is spaced apart from the first impurity region in a direction of the second well. A third impurity region is formed in the second well, has the second conductivity type, and is electrically connected to a second electrode pad. A fourth impurity region is formed in the second well, is located in a direction of the first well from the third impurity region to contact the third impurity region, has the first conductivity type, and is electrically floated.

Abstract: An electrostatic discharge (ESD) protection circuit includes a substrate, and a plurality of unit bipolar transistors formed in the substrate. Each of the plurality of unit bipolar transistors may include a first-conductivity-type buried layer formed in the substrate, a first-conductivity-type well formed over the first-conductivity-type buried layer, a second-conductivity-type well formed in the first-conductivity-type well, a first-conductivity-type vertical doping layer vertically formed from the surface of the substrate to the first-conductivity-type buried layer so as to surround the first-conductivity-type well, and a first-conductivity-type doping layer and a second conductivity-type doping layer formed in the second-conductivity-type well. The first-conductivity-type doping layer of any one of the adjacent unit bipolar transistors and the first-conductivity-type vertical doping layer of another one of the adjacent unit bipolar transistors may be connected to each other.

Abstract: An electrical device, including a semiconductor device such an electrostatic discharge protection semiconductor device, and a method for manufacturing the same. An electrostatic discharge protection semiconductor device may include a substrate and a gate in and/or over the substrate. The gate may be multi-layered, and may include a gate oxide layer and a gate electrode. An electrostatic discharge protection semiconductor device may include a source region formed in and/or over a predetermined area of the substrate on a side of the gate, and a plurality of drain regions which may be sequentially multi-layered in and/or over the substrate on an opposing side of the gate in a vertical direction. At least one drain region may be overlapped with the gate in a horizontal direction.

Abstract: An electrostatic discharge (ESD) protection circuit includes a substrate, and a plurality of unit bipolar transistors formed in the substrate. Each of the plurality of unit bipolar transistors may include a first-conductivity-type buried layer formed in the substrate, a first-conductivity-type well formed over the first-conductivity-type buried layer, a second-conductivity-type well formed in the first-conductivity-type well, a first-conductivity-type vertical doping layer vertically formed from the surface of the substrate to the first-conductivity-type buried layer so as to surround the first-conductivity-type well, and a first-conductivity-type doping layer and a second conductivity-type doping layer formed in the second-conductivity-type well. The first-conductivity-type doping layer of any one of the adjacent unit bipolar transistors and the first-conductivity-type vertical doping layer of another one of the adjacent unit bipolar transistors may be connected to each other.

Abstract: A method is provided for measuring interface trap density in a semiconductor device. In the method, measurement parameters are input to a host computer. A pulse condition is set at a pulse generator using the measurement parameters. A pulse of a predetermined frequency generated by the pulse generator is applied to a gate of a transistor, and a charge pumping current is measured from a bulk of the transistor. A charge pumping current measurement may be repeated for a plurality of frequencies while changing the frequency until a set frequency is reached. A pure charge pumping current is calculated for each frequency where a gate tunneling leakage current is removed from the charge pumping current measured for each frequency. Interface trap density is calculated from the calculated pure charge pumping current for each frequency.

Abstract: A method is provided for measuring interface trap density in a semiconductor device. In the method, measurement parameters are input to a host computer. A pulse condition is set at a pulse generator using the measurement parameters. A pulse of a predetermined frequency generated by the pulse generator is applied to a gate of a transistor, and a charge pumping current is measured from a bulk of the transistor. A charge pumping current measurement may be repeated for a plurality of frequencies while changing the frequency until a set frequency is reached. A pure charge pumping current is calculated for each frequency where a gate tunneling leakage current is removed from the charge pumping current measured for each frequency. Interface trap density is calculated from the calculated pure charge pumping current for each frequency.

Abstract: An exemplary wheeled footwear with a spring suspension system is provided. In one embodiment, the footwear includes an upper, a midsole positioned in a midsole region, and an outsole. The spring suspension system is positioned in the midsole region of the footwear, and includes plurality of spring members, each having a first end and a second end, a top layer operable to support at least a portion of the plurality of spring members at the first end, and a bottom layer operable to support at least a portion of the plurality of spring members at the second end. The bottom layer may include an opening or openings formed in the bottom layer that may receive at least a portion of a wheel or wheels that may be positioned below the top layer and operable for rolling.

Abstract: An example of a test pattern includes a test element, a plurality of test pads spaced apart from and formed around the test element, a plurality of metal wires configured to connect the test element with the test pads, a fuse configured to connect the test pads having the same electrical potential with each other, and a voltage pulse generator configured to generate a voltage pulse. The fuse is configured to be cut when the voltage pulse generated by the voltage pulse generator is applied to the fuse.