Abstract: A MEMS switch includes a substrate, at least one signal line and at least one electrode formed on the substrate, and a moving beam disposed in a spaced-apart relation with respect to the substrate above the substrate so as to be connected with or disconnected from the signal line according to an operation of the electrode. The moving beam includes at least one body, and at least one support to support the body. The body has a modulus of elasticity larger than that of the support. The MEMS switch prevents the moving beam from being stuck and increases a contact force generating between the moving beam and the signal line, thereby enabling a signal to be stably transmitted.

Abstract: A micro electro mechanical system switch and a method of fabricating the same. The micro electro mechanical system switch includes a substrate a plurality of signal lines formed at sides an upper surface of the substrate and including switching contact points and a plurality of immovable electrodes on the upper surface of the substrate and between the plurality of signal lines. An inner actuating member performs a seesaw based on a center of the substrate and together with an outer actuating member. Pushing rods are formed at ends of an upper surface of the inner actuating member with ends protruding from and overlapping with an upper portion of the outer actuating member. Contacting members are formed on a lower surface of the outer actuating member so as to be pushed by the pushing rods and contacting the switching contact points of the signal lines.

Abstract: A piezoelectric Micro Electro Mechanical System (MEMS) switch includes a substrate, first and second fixed signal lines symmetrically formed in a spaced-apart relation to each other on the substrate to have a predetermined gap therebetween, a piezoelectric actuator disposed in alignment with the first and the second fixed signal lines in the predetermined gap, and having a first end supported on the substrate to allow the piezoelectric actuator to be movable up and down, and a movable signal line having a first end connected to one of the first and the second fixed signal lines, and a second end configured to be in contact with, or separate from the other of the first and second fixed signal lines, the movable signal line at least one side thereof being connected to an upper surface of the piezoelectric actuator.

Abstract: A downward type micro electro mechanical system (EMS) switch and a method of fabricating the same is provided. The downward type MEMS switch includes first and second cavities formed in a substrate, first and second actuators formed on upper portions of the first and second cavities, first and second fixing lines formed on an upper surface of the substrate and not overlapped with the first and second cavities, and a contact pad which is spaced apart at a predetermined distance from surfaces of the first fixing line and the second fixing line but which can be contacted with the first fixing line and the second fixing line when the first actuator and the second actuator are driven. The contact pad, which is actuated downward by piezoelectricity, is fabricated as it shares a layer with a RF signal line, after the RF signal line is fabricated.

Abstract: A MEMS (micro electro mechanical system) switch, which includes a substrate; a fixed electrode formed on an upper side of the substrate; a signal line formed on both sides of the fixed electrode; a contact member formed on an upper side of the signal line at a distance from said fixed electrode and contacting an edging portion of the signal line; a supporting member supporting the contact member to be movable; and a moving electrode disposed on an upper side of the supporting member.

Abstract: A micro electro mechanical system switch and a method of fabricating the same. The micro electro mechanical system switch includes a substrate a plurality of signal lines formed at sides an upper surface of the substrate and including switching contact points and a plurality of immovable electrodes on the upper surface of the substrate and between the plurality of signal lines. An inner actuating member performs a seesaw based on a center of the substrate and together with an outer actuating member. Pushing rods are formed at ends of an upper surface of the inner actuating member with ends protruding from and overlapping with an upper portion of the outer actuating member. Contacting members are formed on a lower surface of the outer actuating member so as to be pushed by the pushing rods and contacting the switching contact points of the signal lines.

Abstract: A Micro Electro Mechanical System (MEMS) switch includes a substrate, a fixed signal line formed on the substrate, a movable signal line spaced apart from one of an upper surface and a lower surface of the fixed signal line, and at least one piezoelectric actuator connected to a first end of the movable signal line so as to bring or separate the movable signal line in contact with or from the fixed signal line. The piezoelectric actuator includes a first electrode, a piezoelectric layer formed on the first electrode, a second electrode formed on the piezoelectric layer, and a connecting layer formed on the second electrode and connected with the movable signal line.

Abstract: A pneumatic micro electro mechanical system switch includes a substrate, a pneumatic actuating unit disposed on the substrate; the pneumatic actuating unit having a plurality of variable air cavities communicating such that when one of the plurality of variable air cavities is compressed, the rest are expanded; a signal line having a plurality of switching lines, each of which passes through a corresponding one of the plurality of variable air cavities and has switching ends disposed in a spaced-apart relation with each other in the corresponding one of the plurality of variable air cavities; a movable switching unit to connect the first and the second switching ends of each of the plurality of switching lines if one of the plurality of variable air cavities is compressed; and a driving unit to drive the pneumatic actuating unit so as to selectively compress the plurality of variable air cavities.

Abstract: A MEMS (micro electro mechanical system) switch, which includes a substrate; a fixed electrode formed on an upper side of the substrate; a signal line formed on both sides of the fixed electrode; a contact member formed on an upper side of the signal line at a distance from said fixed electrode and contacting an edging portion of the signal line; a supporting member supporting the contact member to be movable; and a moving electrode disposed on an upper side of the supporting member.

Abstract: A piezoelectric RF micro electro mechanical system (MEMS) device and a method of fabricating the same are provided, in which the RF MEMS device is driven upward at a low voltage based on a piezoelectric effect. The piezoelectric RF MEMS device includes an upper substrate provided with an RF output signal line, a piezoelectric actuator positioned below the RF output signal line, and a lower substrate provided with a cavity so that one end of the piezoelectric actuator is fixed to the lower substrate and its other end is movably spaced apart from the upper and lower substrates, wherein the piezoelectric actuator is provided with an RF input signal line thereon, and a contact pad is provided to connect the RF output signal line with the RF input signal line when the piezoelectric actuator is driven upward.

Abstract: An RF MEMS switch and a method for fabricating the same are disclosed, in which the RF MEMS device is down driven at a low voltage using a piezoelectric effect. The RF MEMS switch includes a substrate provided with RF signal lines and a cavity, a cantilever positioned on the cavity, having one end fixed to the substrate, and a contact pad connecting the RF signal lines with the cantilever in contact with the RF signal lines when the cantilever is down driven.

Abstract: A vertical comb actuator radio frequency (RF) micro-electro-mechanical system (MEMS) switch. The RF MEMS switch includes a substrate; first and second signal lines spaced at a predetermined interval from each other and deposited on an upper surface of the substrate; an actuator positioned over the first and second signal lines when viewed from the upper surface of the substrate and spaced at a predetermined interval from the first and second signal lines; and a fixing portion positioned over the actuator when viewed from the upper surface of the substrate, wherein the fixing portion permits the actuator to come in contact with the first and second signal lines when a predetermined driving voltage is applied. Thus, it is possible to prevent the actuator from sticking to the substrate. In addition, the RF MEMS switch can be operated with a low voltage and insertion loss and power loss can be reduced.

Abstract: An RF MEMS switch having asymmetrical spring rigidity. The RF MEMS switch has supporting members spaced apart in a certain interval on a substrate, a membrane being a motion member suspended by plural spring members extended on both sides of the membrane, and a bottom electrode being a contact surface on an upper surface of the substrate facing a bottom surface of the membrane, wherein the plural spring members placed on opposite sides of the membrane have asymmetrical rigidity, and a portion of the membrane on a side of stronger spring rigidity is first separated from the contact surface when the RF MEMS switch is turned off. The present invention has an advantage of easy separation of the switch from the contact surface, when the switch is turned off, due to the different rigidity of the springs located on the sides of the membrane.

Abstract: A MEMS (Micro Electro Mechanical Systems) switch actuated by electrostatic and piezoelectric forces, includes a substrate; a first contact point positioned in a predetermined first area on an upper surface of the substrate; a support layer suspended at a predetermined distance from the upper surface of the substrate; a second contact point formed on a lower surface of the support layer; a first actuator operative to move the support layer in a predetermined direction using an electrostatic force; and a second actuator operative to move the support layer in a predetermined direction using a piezoelectric force. The first actuator is used to turn on the MEMS switch. The second actuator can be used together with the first actuator to turn on the MEMS switch or can be separately used to turn off the MEMS switch. As a result, a stiction can be prevented from occurring between contact points.

Abstract: A MEMS switch including a substrate at least one fixed electrode formed on top of the substrate and at least one restoring electrode formed on top of the substrate and formed at a lateral surface of the fixed electrode. At least one signal line is formed on top of the substrate and has a switching contact part. A movable electrode is distantly connected from the top of the substrate at a predetermined space via an elastic connector on the substrate and at least one contact member formed on a bottom surface of the movable electrode or on a bottom surface of the elastic connector for attachment to or detachment from the switching contact part. At least one pivot boss is formed on either the bottom surface of the movable electrode or on the top of the substrate.

Abstract: A MEMS switch includes a lower substrate having a signal line on an upper surface of the lower substrate; an upper substrate, having a cavity therein, disposed apart from the upper surface of the lower substrate by a distance, and having a membrane layer on a lower surface of the upper substrate; a bimetal layer formed in the cavity of the upper substrate on the membrane layer; a heating layer formed on a lower surface of the membrane layer; and a contact member formed on a lower surface of the heating layer. The contact member can come into contact with or separate from the signal line. A method for manufacturing the MEMS switch includes preparing the upper and lower substrates and combining them so that a surface having the signal line faces a surface having the contact member and the upper and lower substrates are disposed apart by a distance.

Abstract: A spring structure for supporting a floating member and a micro-structure having the same. The spring structure includes: at least one support post unit fixed to a substrate; and at least one spring unit having a first spring connected to the support post unit and extending in a predetermined direction from the support post unit, a second spring member connected to a floating member and extending in the same direction as the first spring unit from the floating member, and a connection member arranged normal to the first and second spring members and interconnecting the tip ends of the first and second spring members. Because the first spring member and the second spring member are arranged to be expanded or contracted along with the floating member when the temperature changes, the first and second spring members are not subject to stress caused due to the difference in thermal expansion coefficient.

Abstract: A switch pad for switching signal flow and a micro-switch having the same. The switch pad comprises a body formed so that as approaching opposite end portions from a central portion of the body, the body is more remotely spaced from a horizontal plane containing a top surface of the electrostatic driving unit. With the body of the switch pad formed in this manner, the switch pad can be more stably driven.

Abstract: A micro electromechanical system (MEMS) switch and a method for manufacturing the same are provided. The MEMS switch includes a substrate; signal lines formed on the substrate; main electrodes spaced apart by a distance and formed over the substrate; an actuating beam installed above the main electrodes at a certain height; a support unit to support the actuating beam; and sub-electrodes formed above the actuating beam at a distance from the actuating beam and facing the corresponding main electrodes. The method includes depositing and patterning a metal layer on a substrate; depositing and patterning a sacrificial layer to form actuator beam support holes and first sub-electrode contact holes; depositing and patterning an actuating beam layer on the sacrificial layer, thereby forming spacers; depositing and patterning second sub-electrode contact holes from another sacrificial layer; depositing and patterning a sub-electrode layer on the sacrificial layer; and removing the two sacrificial layers.

Abstract: A micro electro mechanical system switch and a method of fabricating the micro electro mechanical system switch. The micro electro mechanical system switch includes a substrate, a plurality of signal lines formed on the substrate and including switching contact points and a plurality of immovable electrodes formed among the signal lines on the substrate. A plurality of anchors protrude from the substrate to predetermined heights and support at least two actuating beams installed on an identical plane so as to move up and down. A connecting unit connects the at least two actuating beams. A support unit provided on the substrate supports the connecting unit and contacting plates are installed on lower surfaces of the at least two actuating beams so as to contact the switching contact points.