Abstract: A platform for a semi-submersible floating type offshore structure according to an exemplary embodiment of the present invention includes a main body which is installed on the sea and has an arrangement structure in which a plurality of pontoons is combined to form a plurality of polygonal shapes; and a protrusion member connecting unit which extends from each corner of the main body and connects a protrusion member outwardly protruding from the main body to the main body.

Abstract: An offshore wind power plant designed to reduce a fatigue load of a wind turbine according to an exemplary embodiment of the present invention includes an offshore structure, a plurality of wind turbines which is installed above the offshore structure to be spaced apart from each other with a predetermined distance and is supplied with a power through wind to produce electrical energy; and a turbine controller which controls at least one of a pitch movement and a yaw movement for the plurality of wind turbines.

Abstract: Semiconductor devices are provided including a first fin-shaped pattern having first and second sidewalls facing one another and a field insulating film contacting at least a portion of the first fin-shaped pattern. The first fin-shaped pattern includes a lower portion of the first fin-shaped pattern contacting the field insulating film; an upper portion of the first fin-shaped pattern not contacting the field insulating film; a first boundary between the lower portion of the first fin-shaped pattern and the upper portion of the first fin-shaped pattern; and a first fin center line perpendicular to the first boundary and meeting the top of the upper portion of the first fin-shaped pattern. The first sidewall of the upper portion of the first fin-shaped pattern and the second sidewall of the upper portion of the first fin-shaped pattern are asymmetric with respect to the first fin center line.

Abstract: A semiconductor device is provided. The semiconductor device includes a field insulating film on a substrate, a first fin type pattern which is formed on the substrate and protrudes upward from an upper surface of the field insulating film, and a gate electrode which intersects with the first fin type pattern on the field insulating film and includes a first portion and a second portion, the first portion being located on one side of the first fin type pattern and including a first terminal end of the gate electrode, and the second portion being located on the other side of the first fin type pattern, wherein a height from the substrate to a lowest part of the first portion is different from a height from the substrate to a lowest part of the second portion.

Abstract: A method of manufacturing a semiconductor device includes forming first sacrificial cores on a first region of a lower structure and second sacrificial cores on a second region of the lower structure, forming spacers on side walls of the first sacrificial cores and side walls of the second sacrificial cores, forming a protective pattern covering the second sacrificial cores on the second region of the lower structure, removing the first sacrificial cores from the first region, and etching the lower structure using the spacers on the first region, and the second sacrificial cores and the spacers on the second region. By using only spacers as an etching mask in the first region and the sacrificial cores with the spacers as an etching mask in the second region, patterns with different widths are formed simultaneously on the first and second regions.

Abstract: A platform for a semi-submersible floating type offshore structure according to an exemplary embodiment of the present invention includes a main body which is installed on the sea and has an arrangement structure in which a plurality of pontoons is combined to form a plurality of polygonal shapes; and a protrusion member connecting unit which extends from each corner of the main body and connects a protrusion member outwardly protruding from the main body to the main body.

Abstract: A semiconductor device -is provided. The semiconductor device includes a field insulating film on a substrate, a first fin type pattern which is formed on the substrate and protrudes upward from an upper surface of the field insulating film, and a gate electrode which intersects with the first fin type pattern on the field insulating film and includes a first portion and a second portion, the first portion being located on one side of the first fin type pattern and including a first terminal end of the gate electrode, and the second portion being located on the other side of the first fin type pattern, wherein a height from the substrate to a lowest part of the first portion is different from a height from the substrate to a lowest part of the second portion.

Abstract: Semiconductor devices are provided including a first fin-shaped pattern having first and second sidewalls facing one another and a field insulating film contacting at least a portion of the first fin-shaped pattern. The first fin-shaped pattern includes a lower portion of the first fin-shaped pattern contacting the field insulating film; an upper portion of the first fin-shaped pattern not contacting the field insulating film; a first boundary between the lower portion of the first fin-shaped pattern and the upper portion of the first fin-shaped pattern; and a first fin center line perpendicular to the first boundary and meeting the top of the upper portion of the first fin-shaped pattern. The first sidewall of the upper portion of the first fin-shaped pattern and the second sidewall of the upper portion of the first fin-shaped pattern are asymmetric with respect to the first fin center line.

Abstract: Semiconductor devices are provided including a first fin-shaped pattern having first and second sidewalls facing one another and a field insulating film contacting at least a portion of the first fin-shaped pattern. The first fin-shaped pattern includes a lower portion of the first fin-shaped pattern contacting the field insulating film; an upper portion of the first fin-shaped pattern not contacting the field insulating film; a first boundary between the lower portion of the first fin-shaped pattern and the upper portion of the first fin-shaped pattern; and a first fin center line perpendicular to the first boundary and meeting the top of the upper portion of the first fin-shaped pattern. The first sidewall of the upper portion of the first fin-shaped pattern and the second sidewall of the upper portion of the first fin-shaped pattern are asymmetric with respect to the first fin center line.

Abstract: A method of manufacturing a semiconductor device includes forming first sacrificial cores on a first region of a lower structure and second sacrificial cores on a second region of the lower structure, forming spacers on side walls of the first sacrificial cores and side walls of the second sacrificial cores, forming a protective pattern covering the second sacrificial cores on the second region of the lower structure, removing the first sacrificial cores from the first region, and etching the lower structure using the spacers on the first region, and the second sacrificial cores and the spacers on the second region.

Abstract: A semiconductor device is provided. The semiconductor device includes a field insulating film on a substrate, a first fin type pattern which is formed on the substrate and protrudes upward from an upper surface of the field insulating film, and a gate electrode which intersects with the first fin type pattern on the field insulating film and includes a first portion and a second portion, the first portion being located on one side of the first fin type pattern and including a first terminal end of the gate electrode, and the second portion being located on the other side of the first fin type pattern, wherein a height from the substrate to a lowest part of the first portion is different from a height from the substrate to a lowest part of the second portion.

Abstract: A floating type offshore wind power generation facility includes: a wind power generation unit which is installed to be horizontally rotatable about a vertical rotation center while being placed in an inclined state on an offshore structure or installed to be rotatable in two directions about a horizontal rotation center of the offshore structure, and converts rotational kinetic energy of blades caused by sea wind into electrical energy; and a driving unit which is connected to a lower end of the wind power generation unit in a state in which the driving unit is installed on the offshore structure, and changes a pivoting angle or a rotating angle of the wind power generation unit by generating driving power.

Abstract: A semiconductor device is provided. The semiconductor device includes a fin type pattern, a field insulating film on a part of a sidewall of the fin-type pattern, and a gate electrode intersecting with the fin-type pattern, on the fin-type pattern and the field insulating film. The gate electrode on the field insulating film includes a first portion, a second portion, and a third portion on the field insulating film. A first width of the first portion increases as a first distance from the field insulating film, increases width of the second portion decreases as a second distance from the field insulating film increases, and a third width of the third portion increases or is substantially constant as a third distance from the field insulating film increases.

Abstract: Semiconductor devices are provided including a first fin-shaped pattern having first and second sidewalls facing one another and a field insulating film contacting at least a portion of the first fin-shaped pattern. The first fin-shaped pattern includes a lower portion of the first fin-shaped pattern contacting the field insulating film; an upper portion of the first fin-shaped pattern not contacting the field insulating film; a first boundary between the lower portion of the first fin-shaped pattern and the upper portion of the first fin-shaped pattern; and a first fin center line perpendicular to the first boundary and meeting the top of the upper portion of the first fin-shaped pattern. The first sidewall of the upper portion of the first fin-shaped pattern and the second sidewall of the upper portion of the first fin-shaped pattern are asymmetric with respect to the first fin center line.

Abstract: A semiconductor device is provided. The semiconductor device includes a field insulating film on a substrate, a first fin type pattern which is formed on the substrate and protrudes upward from an upper surface of the field insulating film, and a gate electrode which intersects with the first fin type pattern on the field insulating film and includes a first portion and a second portion, the first portion being located on one side of the first fin type pattern and including a first terminal end of the gate electrode, and the second portion being located on the other side of the first fin type pattern, wherein a height from the substrate to a lowest part of the first portion is different from a height from the substrate to a lowest part of the second portion.

Abstract: A semiconductor device includes a first multi-channel active pattern, a field insulation layer disposed on the first multi-channel active pattern and including a first region and a second region, the first region having a top surface protruding from a top surface of the second region to a top surface of the first multi-channel active pattern, a first gate electrode crossing the first multi-channel active pattern, the first gate electrode being disposed on the field insulation layer, and a first source or drain disposed between the first gate electrode and the first region of the field insulation layer and including a first facet, the first facet being disposed adjacent to the first region of the field insulation layer at a point lower than the top surface of the first multi-channel active pattern.

Abstract: A semiconductor device is provided. The semiconductor device includes a fin type pattern, a field insulating film on a part of a sidewall of the fin-type pattern, and a gate electrode intersecting with the fin-type pattern, on the fin-type pattern and the field insulating film. The gate electrode on the field insulating film includes a first portion, a second portion, and a third portion on the field insulating film. A first width of the first portion increases as a first distance from the field insulating film, increases width of the second portion decreases as a second distance from the field insulating film increases, and a third width of the third portion increases or is substantially constant as a third distance from the field insulating film increases.

Abstract: Semiconductor devices are provided including a first fin-shaped pattern having first and second sidewalls facing one another and a field insulating film contacting at least a portion of the first fin-shaped pattern. The first fin-shaped pattern includes a lower portion of the first fin-shaped pattern contacting the field insulating film; an upper portion of the first fin-shaped pattern not contacting the field insulating film; a first boundary between the lower portion of the first fin-shaped pattern and the upper portion of the first fin-shaped pattern; and a first fin center line perpendicular to the first boundary and meeting the top of the upper portion of the first fin-shaped pattern. The first sidewall of the upper portion of the first fin-shaped pattern and the second sidewall of the upper portion of the first fin-shaped pattern are asymmetric with respect to the first fin center line.

Abstract: The present invention provides a marine structure platform including: horizontal connecting parts which are disposed under the seawater and connected to one another in a lattice structure; vertical connecting parts which are installed uprightly at four corners of the horizontal connecting parts and protrude from the seawater; and movement damping parts which are extended at the four corners from the vertical connecting parts along the horizontal connecting parts adjacent to one another, the movement damping parts having a plate shape so as to define a vertical gap therebetween.

Abstract: A semiconductor device is provided. The semiconductor device may include a field insulating film on a substrate, a first fin type pattern which is formed on the substrate and protrudes upward from an upper surface of the field insulating film, and a gate electrode which intersects with the first fin type pattern on the field insulating film. The gate electrode may include a first portion and a second portion, the first portion being located on one side of the first fin type pattern and including a first terminal end of the gate electrode, and the second portion being located on the other side of the first fin type pattern. A height from the substrate to a lowest part of the first portion may be different than a height from the substrate to a lowest part of the second portion.