Abstract: Provided are a pressurizing module and a blood pressure measuring device including the pressurizing module. The pressurizing module includes a driving block optionally discharging compressed air; and a bellows-type airbag formed to overlap with the driving block, and comprising an inner space accommodating the compressed air discharged from the driving block, a plurality of wrinkles flattened so as to expand the inner space, and a pressurizing surface formed at an end portion of the wrinkles and spaced apart from the driving block as the inner space expands.

Abstract: A small structure which uses bonding wires to prevent disturbance and provide support and a method of fabricating the same are provided. The small structure includes a floating body having a plurality of first contact pads, a base having a plurality of second contact pads, and a plurality of bonding wires electrically connecting the first and second contact pads and elastically supporting the floating body. The method of fabricating the small structure includes preparing a base, forming a sacrificial layer on the base, disposing a floating body on the sacrificial layer, connecting the base and the floating body with bonding wires, and removing the sacrificial layer. Thereby, fabrication costs of the small structure are reduced.

Abstract: A circuit and method for compensating for an electrode motion artifact in which the electrode motion artifact is generated because impedance between a subject and a measuring electrode changes during measurement of the subject's biosignal, and the electrode motion artifact can be differentially measured and an electrocardiogram signal can be compensated by introducing a predetermined voltage or an electric current to the subject. A circuit and method for compensating electrode motion artifact, which can differentially measure the difference information between impedance components by introducing a predetermined voltage or electric current to a subject, in association with the electrode motion artifact. In this instance, the impedance component is a component of electrode motion artifact and the electrode motion artifact is generated when measuring a biosignal.

Abstract: A biosignal measurement device includes an electrode and a signal processing member. The electrode includes an insulation sheet having a hole, a device contact portion provided on the top surface of the insulation sheet and a body contact portion provided on the bottom surface of the insulation sheet, the device contact portion and the body contact portion electrically connected to each other via the hole. The signal processing member includes an externally exposed terminal to make surface contact with the device contact portion, an analog signal processing unit, an A/D signal converter and a digital signal processing unit. Also, the device contact portion and the body contact portion are formed of a material which is both conductive and adhesive. Accordingly, the signal processing member may be directly attached. Noise may be reduced. Also, a biosignal may be accurately measured.

Abstract: A biosignal measurement device includes an electrode and a signal processing member. The electrode includes an insulation sheet having a hole, a device contact portion provided on the top surface of the insulation sheet and a body contact portion provided on the bottom surface of the insulation sheet, the device contact portion and the body contact portion electrically connected to each other via the hole. The signal processing member includes an externally exposed terminal to make surface contact with the device contact portion, an analog signal processing unit, an A/D signal converter and a digital signal processing unit. Also, the device contact portion and the body contact portion are formed of a material which is both conductive and adhesive. Accordingly, the signal processing member may be directly attached. Noise may be reduced. Also, a biosignal may be accurately measured.

Abstract: A motion detector and method with low power consumption in an inertia sensor. The motion detector is selectively supplied with power for operation of the inertia sensor according to a power control signal. While the inertia sensor is supplied with power, three-dimensional analog signals are sampled, A/D converted, and outputted via a controller. A pulse width of the power control signal is determined by reflecting the sampling and A/D conversion period and reflecting the operation preparing period of the inertia sensor from the A/D converted value.

Abstract: A pressure sensor includes at least one cantilever formed on an upper surface of a silicon substrate, a piezoresistor formed on a fixed end of the cantilever, and a metal wire and an electrode pad connected to both ends of the piezoresistor, wherein a stopper that limits a deformation of a free end of the cantilever is formed below the cantilever.

Abstract: A contact force sensor package includes a substrate layer having a vibration detection unit and a pair of first junction pads that are electrical connection ports which are provided on an upper surface of the substrate layer, a flexible circuit substrate layer having a pair of second junction pads provided at a position corresponding to the first junction pads and electrically connected to the first junction pad, a vibration transfer unit having one side contacting the vibration detection unit and the other side contacting a human body and transferring a sphygmus wave of the human body to the vibration detection unit, and an adhesion layer formed between the substrate layer and the flexible circuit substrate layer to reinforce a junction force between the substrate layer and the flexible circuit substrate layer, the adhesion layer being not formed in an area overlapping at least the vibration transfer unit.

Abstract: A method of wirelessly receiving a biological signal is provided. Thus, it is possible to considerably reduce power consumption of a wireless biological signal receiver by determining a transmission period of an externally received biological signal, setting an operation mode of the wireless biological signal receiver to an active mode in which it is possible to receive the biological signal for a predetermined time for each determined transmission period and receiving the biological signal, and changing the operation mode from the active mode to a low-power mode in which it is impossible to receive the biological signal, after the predetermined time is elapsed with respect to each determined transmission period.

Abstract: A body-temperature measuring device is provided. The device includes: a pad which is attachable to and detachable from a human body; a battery which is provided to the pad and includes a pair of battery terminals for supplying power; and a temperature sensing block which is attached to and detached from the pad and comprises units for contacting the human body to sense temperature and wirelessly transmitting a temperature sensing signal corresponding to the sensed temperature and a pair of connecting terminals which are electrically connected to the battery terminals only when attached to the pad, and a body-temperature measuring system including one or more of the body-temperature measuring devices and a receiver which receives the wirelessly transmitted temperature sensing signal, measures the temperature by using the received signal, and informs of a result of measuring the temperature.

Abstract: Provided is a blood pressure measuring apparatus and a method of measuring blood pressure. The blood pressure measuring apparatus includes a plurality of blood pressure measuring units disposed on a substrate, a plurality of optical sensors disposed on the substrate to correspond to the blood pressure measuring units, and a control unit that measures blood pressure by analyzing signals received from the optical sensors and the blood pressure measuring units, wherein each of the blood pressure measuring units comprises a plurality of blood pressure sensors.

Abstract: A pressure sensor includes at least one cantilever formed on an upper surface of a silicon substrate, a piezoresistor formed on a fixed end of the cantilever, and a metal wire and an electrode pad connected to both ends of the piezoresistor, wherein a stopper that limits a deformation of a free end of the cantilever is formed below the cantilever.

Abstract: A tact switch module is provided. The tact switch module includes a tact switch to control a driving voltage to be supplied to a power supply by sensing an ON input by a user; and a power control unit having a power input port which is connected to the power supply and a power output port to output a first voltage when power is supplied to the power input port, wherein the driving voltage triggers the power supply to output the power, and the power supply supplies the power to the power input port while the first voltage is supplied from the power output of the power control unit.

Abstract: A biosignal amplifying device includes: an operational amplifier (op-amp); a capacitor load including a first capacitor connected with a first input terminal of the op-amp, and in which a first voltage is inputted from a first electrode, and a second capacitor which is connected with a second input terminal of the op-amp, and in which a second voltage is inputted from a second electrode; a feedback capacitor load including a first feedback capacitor connected with the first input terminal and an output terminal, and a second feedback capacitor connected with the second input terminal; and a feedback resistor load including a first feedback resistor connected with the first input terminal and the output terminal, and a second feedback resistor connected with the second input terminal.

Abstract: A respiration leading apparatus, method, and medium, which can displace a respiration leading apparatus corresponding to a drive signal which corresponds to a selection input from a user, or displace a respiration leading apparatus generating the drive signal which corresponds to a biological signal of the user, thereby leading a respiration of the user, is provided. A respiration leading apparatus includes: a member; a selection module which receives a selection input from a user; a drive control module which outputs a drive signal corresponding to the selection input; and a drive module which displaces the member corresponding to the drive signal in order to lead a respiration of the user. A respiration leading apparatus, which can provide a user with structural displacement by a drive signal corresponding to biological information of the user, and be portable for the user, is provided.

Abstract: A vertical offset structure and a method for fabricating the same. The vertical offset structure includes a substrate; a fixed electrode fixing portion formed on the substrate; a fixed electrode moving portion formed at a position away from an upper portion of the substrate by a predetermined distance; a spring portion for connecting the fixed electrode fixing portion and the fixed electrode moving portion to each other so that the fixed electrode moving portion moves into a direction substantially perpendicular to a plate surface of the substrate; a movable electrode located away from the upper portion of the substrate by a predetermined distance to have a predetermined interval horizontal to the fixed electrode moving portion; and a cap wafer bonded to a predetermined area of one of the fixed electrode moving portion and the movable electrode.

Abstract: A method for fabricating a vertical offset structure that forms a complete vertical offset on a wafer includes a first trench forming step of forming first trenches on a wafer; a first etching step of performing a first patterning for determining etching positions of second and third trenches by depositing a first thin film on the wafer, performing a second patterning for temporarily protecting the etching position of the third trench by depositing a second thin film on the first thin film and the wafer, and then forming the second trenches by etching the wafer; a second etching step of forming a protection layer on side surfaces of the second trenches and then vertically extending the second trenches by etching the wafer; a third etching step of removing the second thin film and then forming the third trench by etching a position from which the second thin film is removed; and a fourth etching step of horizontally extending the second trenches vertically extended at the second etching step and the third tren

Abstract: Apparatus and a method for driving and detecting a motion of MEMS structure using single electrode. Apparatus includes a driving signal generation part driving MEMS structure; a motion detection part detecting motion of MEMS structure and outputting a motion current signal; an amplification part amplifying motion current signal and outputting a motion voltage signal; a gain adjustment part amplifying driving signal and outputting an amplified driving signal; a differential circuit part adding and subtracting with respect to signals output from the amplifying part and the gain adjustment part and outputting a motion signal without the driving signal; and a motion signal detection part selecting and outputting a motion signal of a predetermined frequency from the motion signal output from the differential circuit part. The variable capacitor is configured by a movable electrode plate integrally formed with MEMS structure and a fixed electrode plate disposed opposite to the movable electrode plate.

Abstract: A health care apparatus and method are provided. The apparatus includes: a motion sensing unit; a bio-electric potential sensing unit sensing an electric potential signal of the health examinee corresponding to the sensed result; and an analysis unit analyzing the sensed result. By recognizing a current motion of the examinee and sensing an electric potential signal corresponding to the recognized current motion from the examinee, a more reliable health index of the examinee can be calculated. Even when information on the current motion of the health examinee is not given, the current motion can be recognized by the apparatus and method. Furthermore, since the health examinee is notified of the calculated health index in real time, the health examinee can be informed immediately if the physical condition is in an emergency state. As a result, the examinee can respond quickly to the emergency situation.

Abstract: A vertical offset structure and a method for fabricating the same. The vertical offset structure includes a substrate; a fixed electrode fixing portion formed on the substrate; a fixed electrode moving portion formed at a position away from an upper portion of the substrate by a predetermined distance; a spring portion for connecting the fixed electrode fixing portion and the fixed electrode moving portion to each other so that the fixed electrode moving portion moves into a direction substantially perpendicular to a plate surface of the substrate; a movable electrode located away from the upper portion of the substrate by a predetermined distance to have a predetermined interval horizontal to the fixed electrode moving portion; and a cap wafer bonded to a predetermined area of one of the fixed electrode moving portion and the movable electrode.