Abstract: A system, method and apparatus for contact-less charging of battery operated devices is presented. There is a host charger with a power converter and resonant tank circuit and a portable device where the battery is located, with a battery charging control IC. The method obviates the need for a voltage controller in each of both the host and the portable stages, thus decreasing complexity and increasing efficiency. The charging of the battery in the portable device is controlled by a charging controller therein, which is in continual electric communication with the host, whose output power the control IC dynamically monitors and controls. Two embodiments for the charging circuitry in the portable device are presented. In one embodiment component count is minimized but battery charging is not optimized when the battery voltage is very low. In the other embodiment charging efficiency is maximized regardless of the output voltage of the battery, but additional components are utilized.

Abstract: Disclosed is a scaffold including a semi-permeable membrane on an outer surface thereof. The present invention also discloses a method of preparing a scaffold covered with a semi-permeable membrane, including loading one or more scaffolds into a mold with a predetermined form and size; and adding a semi-permeable agent and a cross-linking agent to the mold and cross-linking the semi-permeable agent to form the semi-permeable membrane on the outer surface of each of the scaffolds. The scaffold covered with the semi-permeable membrane selectively introduces nutrients into the scaffold by allowing penetration of only external nutrients into the scaffold and excreting metabolic wastes generated by tissue cells to the outside of the scaffold. In addition, the scaffold has the morphology of a biological tissue of interest by cross-linking the small-sized scaffolds, thereby allowing uniform proliferation of tissue cells throughout the whole scaffold.

Abstract: Disclosed is an optical fiber comprising a center core which forms a passageway for transmitting optical signals and has a refractive index N1, and a cladding which encloses the center core and has a refractive index N0. The optical fiber further comprises an upper core, which has a distribution of refractive indices increased starting from a refractive index N2 (>N0) at its outer circumference to the refractive index N1 at its internal circumference, and a minutely depressed refractive index region, which is interposed between said upper core and cladding and has a refractive index N3. The refractive index N3 is lower than the refractive index N0.

Abstract: A wide band dispersion-controlled fiber which comprises a core forming an optical signal transmission path and having a peak refractive index, and a cladding surrounding the core and having a peak refractive index lower than the peak refractive index of the core. The wide band dispersion-controlled fiber further comprises at least one dispersion control layer arranged between the core and the cladding and having a refractive index profile such that its refractive index increases from an inner periphery to an outer periphery. The minimum refractive index of the dispersion control layer is less than the peak refractive indices of the core and cladding.

Abstract: An optical fiber having a core that has a graded refractive index profile is disclosed. A clad surrounds the core and traps light within the core. A difference between differential mode delays (DMDs) at wavelengths of about 1300 nm and about 850 nm within the core is increased in a radial direction. The difference between the DMDs at both the wavelengths basically has a value equal to or less than 0.6 ns/km between a position corresponding to 50% of a radius of the core and a center of the core.

Abstract: SRAM cell and method for fabricating the same, the SRAM cell including a first local interconnection connected between first terminals of the first access transistor, the first load transistor, and the first drive transistor, and gates of the second load transistor, and the second drive transistor electrically, and a second local interconnection connected between first terminals of the second access transistor, the second load transistor, and the second drive transistor, and gates of the first load transistor, and the first drive transistor electrically, thereby reducing an area of the SRAM cell.

Abstract: An optical fiber having a core that has a graded refractive index profile is disclosed. A clad surrounds the core and traps light within the core. A difference between differential mode delays (DMDs) at wavelengths of about 1300 nm and about 850 nm within the core is increased in a radial direction. The difference between the DMDs at both the wavelengths basically has a value equal to or less than 0.6 ns/km between a position corresponding to 50% of a radius of the core and a center of the core.

Abstract: SRAM cell and method for fabricating the same, the SRAM cell including a first local interconnection connected between first terminals of the first access transistor, the first load transistor, and the first drive transistor, and gates of the second load transistor, and the second drive transistor electrically, and a second local interconnection connected between first terminals of the second access transistor, the second load transistor, and the second drive transistor, and gates of the first load transistor, and the first drive transistor electrically, thereby reducing an area of the SRAM cell.

Abstract: Disclosed is an optical fiber comprising a center core which forms a passageway for transmitting optical signals and has a refractive index N1, and a cladding which encloses the center core and has a refractive index N0. The optical fiber further comprises an upper core, which has a distribution of refractive indices increased starting from a refractive index N2 (>N0) at its outer circumference to the refractive index N1 at its internal circumference, and a minutely depressed refractive index region, which is interposed between said upper core and cladding and has a refractive index N3. The refractive index N3 is lower than the refractive index N0.

Abstract: A wide band dispersion-controlled fiber which comprises a core forming an optical signal transmission path and having a peak refractive index, and a cladding surrounding the core and having a peak refractive index lower than the peak refractive index of the core. The wide band dispersion-controlled fiber further comprises at least one dispersion control layer arranged between the core and the cladding and having a refractive index profile such that its refractive index increases from an inner periphery to an outer periphery. The minimum refractive index of the dispersion control layer is less than the peak refractive indices of the core and cladding.

Abstract: A barrel assembly of a zoom camera includes a zoom ring at which a front lens group is installed and which is moved back and forth along the optical axis, a rear lens group frame at which a rear lens group is installed along the same optical axis as the front lens group and which is coupled to the zoom ring, and a cam means for correcting the optical position of the rear lens group with respect to the front lens group during operation of zoom.

Abstract: A zoom lens barrel structure of a zoom camera includes a fixed barrel fixed to the camera, a double helicoid ring having first and second helicoid portions having different lead angles, a front lens group support body coupled to the first helicoid portion of the double helicoid ring, a rear lens group support body coupled to the second helicoid portion of the double helicoid ring, and guide means for guiding the front lens group support body and the rear lens group support body to move along the optical axis of the camera, the guide means having a cam portion formed along a path where the rear lens group support body is coupled to the second helicoid portion.

Abstract: The present invention related to a method of fabricating capacitors which fabricates a plurality of capacitors of which capacitances are different one another on a semiconductor substrate.

Abstract: A composition comprising 1.0 to 40 wt. % of a cyclosporin A, 0.1 to 30 wt. % of an emulsifier and 5 to 80 wt. % of a porous dextrin, based on the total weight of the composition has a remarkably improved dissolution rate and superior bioavailability.