Abstract: A device for detecting micro particles in gas, which comprises: an inlet through which a gaseous sample including micro particles flows in; an outlet through which the sample flows out; a channel through which the sample flows from the inlet toward the outlet; a cooling layer which cools and condenses the sample flowing in the channel; a reservoir which is positioned on the cooling layer and collects the condensed sample; a detector which is positioned in the reservoir on the cooling layer and detects the micro particles included in the collected sample; and a heater which heats the outlet portion to produce a pressure difference between the inlet portion and the outlet portion, so that the sample flows through the channel from the inlet toward the outlet. The device for detecting micro particles in gas provides the advantage that micro particles included in gaseous sample can be detected without having to use additional pump or collector, detection time can be reduced, and detection accuracy can be improved.

Abstract: A device for separating micro particles is provided. The separating device comprises a sample inlet into which a sample containing micro particles is injected; fluid inlets into which fluid is injected to form a flow sheath for the sample; a plurality of outlets through which the micro particles are separated and discharged out; a channel through which the sample and the fluid flow; and a first electrode and a second electrode longitudinally disposed in parallel in the channel. The first and the second electrodes are provided in such a manner that an electrode gap between the first and the second electrodes has a curved shape. The micro particles in the sample are easily separated using a dielectrophoresis characteristic.

Abstract: Provided are a patterned magnetic recording medium which has an extremely planarized surface and a method of manufacturing the same. The medium includes a patterned magnetic layer including a plurality of magnetic columns that are arranged with a predetermined pitch therebetween; a substrate that supports the patterned magnetic layer; and a boundary layer, which is filled in gaps between the magnetic columns of the patterned magnetic layer. Thus, an air bearing due to stable airflow is created over the magnetic layer, and magnetic recording/reproduction are easily achieved at ultrahigh density.

Abstract: A Doherty power amplifying apparatus includes a harmonic-controlled Doherty amplifier; and an input matching unit and an output matching unit for input matching and output matching the harmonic-controlled Doherty amplifier, respectively. The harmonic-controlled Doherty amplifier includes a carrier amplifier; a peaking amplifier arranged in parallel to the carrier amplifier; and a harmonic control circuit, arranged in front of the output matching unit, for controlling a harmonic component of an output of the Doherty amplifier to enable the Doherty amplifier to perform a switching or saturation operation.

Abstract: Provided are a fingerprint sensor and a fabrication method thereof. The fingerprint sensor includes: a complementary metal-oxide semiconductor structure which is formed on a substrate that is doped with a first type dopant; an insulating layer which is formed on the complementary metal-oxide semiconductor structure; a lower electrode which is formed in a central portion of the insulating layer; a piezoelectric region which is formed on the lower electrode; an upper electrode which is formed on the piezoelectric layer; and a fingerprint contact layer which is formed to cover a portion of an upper surface of the insulating layer on which the lower electrode has not been formed, the lower electrode, the piezoelectric region, and the upper electrode.

Abstract: A method of manufacturing a micromirror array and a method of manufacturing an optical device having a micromirror. The method of manufacturing a micromirror array includes forming an adhesion layer on a substrate and a magnetic layer on the adhesion layer, patterning the adhesion layer and magnetic layer, magnetizing the magnetic layer and forming a bonding layer on each side of the adhesion layer and the magnetic layer. The substrate is severed into units, each unit including the adhesion layer, the magnetic layer, and the bonding layer. A mirror surface is formed on a side of the substrate to form a unit micromirror structure. The unit micromirror structure is then placed in a holder to form a micromirror array.

Abstract: The present invention relates to an apparatus for maintaining freshness by applying a displacement current. Application of the displacement current to an object of preservation interrupts an ion channel of a living microorganism present in the object of preservation, thereby preventing the microorganism from proliferating and subsequently maintaining the freshness of the object of preservation. The apparatus for maintaining freshness by applying a displacement current includes: a displacement current control unit which regulates the displacement current at less than 1 A and less than 3 GHz; and a displacement current applying unit, comprising a first electrode, and a second electrode which faces the first electrode.

Abstract: A system for maintaining the freshness of an object of preservation comprising an electrode made of a flexible conducting polymer. The system includes: an electrode module comprising a first electrode and a second electrode which face each other; and an electric field supply module generating an electric field between the first electrode and the second electrode by supplying a voltage to the electrode module, and where the first electrode is comprised of a flexible conducting polymer material.

Abstract: Provided is a fuse option device in a semiconductor integrated circuit. In the fuse option device, a pad receives an external fuse program signal, a program signal driving circuit is connected to the pad through a signal line and generates a program activation signal in response to the fuse program signal and an address validity signal. A fuse circuit is electrically programmed in response to the program activation signal, and a pull-down resistor is connected between the signal line and ground.

Abstract: Provided are a method and an apparatus for reproducing information using a semiconductor probe.

Abstract: An oscillator operable in various frequencies includes an oscillation unit generating a sine wave having a predetermined oscillation frequency, a feedback unit feeding the sine wave back to the oscillation unit, and a frequency control unit controlling an operating frequency of the feedback unit by controlling an amount of current flowing through the feedback unit in response to a frequency control signal. The oscillator can operate in various frequencies by controlling the operating frequency thereof. Consequently, the oscillator can sufficiently secure itself against a power noise margin.

Abstract: A linear amplification with nonlinear components (LINC) power transmitter is provided. The LINC power transmitter includes a digital signal processing unit which controls the LINC power transmitter; a frequency modulation unit which modulates or converts a digital signal output from the digital signal processing unit into a radio-frequency (RF) signal; a signal amplification unit which amplifies the RF signal output from the frequency modulation unit using a gain amplifier and a power amplification module; and a direct current/direct current (DC/DC) conversion unit which controls bias of the power amplification module. Here, the DC/DC conversion unit controls a base bias and/or a collect bias of the power amplification module, and the power amplification module operates in saturation.

Abstract: A method for manufacturing a flexible MEMS transducer includes forming a sacrificial layer on a flexible substrate, sequentially depositing a membrane layer, a lower electrode layer, an active layer, and an upper electrode layer on the sacrificial layer by PECVD, sequentially patterning the upper electrode layer, the active layer, and the lower electrode layer, depositing an upper protective layer to cover the upper electrode layer, the lower electrode layer, and the active layer, patterning the upper protective layer to be connected to the lower electrode layer and the upper electrode layer, and then depositing a connecting pad layer and patterning the connecting pad layer to form a first connecting pad to be connected to the lower electrode layer and a second connecting pad to be connected to the upper electrode layer; and patterning the membrane layer to expose the sacrificial layer and removing the sacrificial layer.

Abstract: Provided is a digital feedback linearizing apparatus and method to linearize a power amplifier (PA), which is intended to improve the linearity of a mobile communication base station PA, and more particularly, a digital feedback linearizing apparatus and method to linearize a PA using a digital signal process (DSP) and a feedback technology, in which a predistorted signal required for linearization is generated by adding an input signal input through a predetermined path to an inverse distortion component corresponding to a distortion component of an PA and in which a linearly amplified output signal is obtained by passing the predistorted signal through the PA.

Abstract: A method of manufacturing a micromirror array and a method of manufacturing an optical device having a micromirror. The method of manufacturing a micromirror array includes forming an adhesion layer on a substrate and a magnetic layer on the adhesion layer, patterning the adhesion layer and magnetic layer, magnetizing the magnetic layer and forming a bonding layer on each side of the adhesion layer and the magnetic layer. The substrate is severed into units, each unit including the adhesion layer, the magnetic layer, and the bonding layer. A mirror surface is formed on a side of the substrate to form a unit micromirror structure. The unit micromirror structure is then placed in a holder to form a micromirror array.

Abstract: A probe head includes a sensor unit having: as sensor which records or reads data on or from a predetermined medium; first and second shields disposed on both sides of the sensor at a predetermined distance from each other; and first and second intermediate layers respectively interposed between the sensor and the first shield, and the sensor and the second shield. A method of fabricating the probe head includes: providing a substrate; forming an insulating layer on the substrate; forming a first shield on the insulating layer; forming a first intermediate layer on the first shield; forming a sensor on the first intermediate layer; forming a second intermediate layer on the sensor; forming a second shield on the second intermediate layer; and forming a protective layer on the second shield.

Abstract: A first power supply node supplies a first voltage level during a normal operational mode, and a second power supply node supplies a second voltage level during the normal operational mode. An input circuit, which is connected to the first power supply node, receives an input signal and generates a corresponding signal having the first voltage level during the normal operational mode. An output circuit, which is connected to the second power supply node, receives the signal having the first voltage level and generates a corresponding output signal having the second voltage level during the normal operational mode. A detection circuit detects an interruption in the supply of the first voltage level by the first power supply node, and electrically blocks at least one leakage current path in the output circuit during the interruption.

Abstract: A flexible wireless MEMS microphone includes a substrate of a flexible polymeric material, a flexible MEMS transducer structure formed on the substrate by PECVD, an antenna printed on the substrate for communicating with an outside source, a wire and interface circuit embedded in the substrate to electrically connect the flexible MEMS transducer and the antenna, a flexible battery layer electrically connected to the substrate for supplying power to the MEMS transducer, and a flexible bluetooth module layer electrically connected to the battery layer. The flexible MEMS transducer includes a flexible substrate, a membrane layer deposited on the substrate, a lower electrode layer formed on the membrane layer, an active layer formed by depositing a piezopolymer on the lower electrode layer, an upper electrode layer formed on the active layer, and a first and a second connecting pad electrically connected to the lower and upper electrode layers, respectively.

Abstract: An input/output buffer is operative in an analog mode and a digital mode. The buffer includes a pad, a digital signal line which includes a transmission gate connected to the pad, an analog signal line connected to the pad, an analog/digital mode controller which sets an output level of the digital signal line in the analog mode, and a transmission gate controller which controls the transmission gate when a signal voltage of the pad exceeds a reference voltage.

Abstract: Provided are a fingerprint sensor and a fabrication method thereof. The fingerprint sensor includes: a complementary metal-oxide semiconductor structure which is formed on a substrate that is doped with a first type dopant; an insulating layer which is formed on the complementary metal-oxide semiconductor structure; a lower electrode which is formed in a central portion of the insulating layer; a piezoelectric region which is formed on the lower electrode; an upper electrode which is formed on the piezoelectric layer; and a fingerprint contact layer which is formed to cover a portion of an upper surface of the insulating layer on which the lower electrode has not been formed, the lower electrode, the piezoelectric region, and the upper electrode.