Abstract: An apparatus includes a substrate having a metallic surface, a structure, and a dielectric object facing the metallic top surface. The structure is configured to optically produce surface plasmon polaritons that propagate on the metallic surface. The dielectric object is controllable to adjust values of the dielectric constant at an array of different positions along and near to the metallic surface.

Abstract: Apparatus including substrate, pusher assembly, and flexor assembly adjacent to pusher assembly. Pusher assembly includes hot and cold pusher arms. First ends of hot and cold pusher arms are anchored over substrate. Second ends of hot and cold pusher arms are coupled together and suspended for lateral displacement over substrate. Flexor assembly includes flexor arm, and conductor having actuator contact. First end of flexor arm is anchored over substrate. Pusher assembly is configured for causing lateral displacement of second end of flexor arm and of actuator contact over the substrate. Method includes providing apparatus and causing pusher assembly to laterally displace second end of flexor arm and actuator contact over substrate.

Abstract: A representative embodiment of the invention provides a thermal actuator for a MEMS-based relay switch. The thermal actuator has an “active” arm that is movably mounted on a substrate. The “active” arm has (i) a thermal expansion layer and (ii) a resistive heater that is electrically isolated from the thermal expansion layer. The thermal expansion layer is adapted to expand in response to a temperature change induced by a control current flowing through the resistive heater, thereby bending the “active” arm and moving that arm with respect to the substrate. Due to the fact that mechanical and electrical characteristics of the “active” arm are primarily controlled by the thermal expansion layer and the resistive heater, respectively, those characteristics can be optimized independently to obtain better operating characteristics for MEMS-based relay switches of the invention compared to those attained in the prior art.

Abstract: Apparatus including a chip substrate having a first chip surface facing away from a second chip surface; an array of microelectronic elements on the first chip surface; and an array of conductors each in communication with one of the microelectronic elements, the conductors passing through the chip substrate and fully spanning a distance between the first and second chip surfaces.

Abstract: An apparatus comprising a microelectromechanical system (MEMS) device. The MEMS device includes a substrate having an anchoring pad thereon and a structural element. The structural element has a beam that includes a first part and a second part. The first part is attached to both the anchoring pad and to the second part. The second part is movable with respect to the substrate and made of an electrically conductive material. Additionally, at least one of the following conditions hold: the first part is made of a material having: a first yield stress that is greater than a second yield stress of the electrically conductive material of the second part; a fatigue resistance that is greater than a second fatigue resistance of the electrically conductive material of the second part; or, a creep rate that is less than a second creep rate of the electrically conductive material of the second part.

Abstract: A representative embodiment of the invention provides an infrared (IR) detector having a movable plate supported at an offset distance from a substrate by a suspension arm. In response to a temperature difference between the plate and the substrate generated by the incident IR radiation, the suspension arm deforms and changes the offset distance for the plate. In one embodiment, the suspension arm has three rod-shaped bimorph transducers that lie within a plane that is parallel to the substrate. The transducers are also parallel to one another, with the transducer that is attached to an anchor of the suspension arm being located between the two transducers that are attached to the plate.

Abstract: A method forms an image with a reconfigurable array of mirrors. The method includes configuring the array by translating some of the mirrors such that distances of the mirrors of the array from a reference plane have a non-uniform spatial distribution. The method includes illuminating the configured array with a coherent light beam such that part of the light beam is reflected off the array and is projected on a planar viewing screen.

Abstract: An apparatus includes a mechanical switch. The mechanical switch includes a bilayer with first and second stable curved states. A transformation of the bilayer from the first state to the second state closes the switch.

Abstract: A MEMS device that has desirable tip and tilt properties employs at least two electrostatic drives, each of which has its axis of rotation aligned with the center of a post attachment point, the post attachment point being coupled to a post that is further coupled to the plate that is to be tipped and tilted. Preferably, the electrostatic drives are comb drives arranged so that their axes of rotation are at right angles. Also preferably, in at least one direction, two comb drives are coupled to provide greater torque about a single axis.

Abstract: A heat-sensitive apparatus includes a substrate with a top surface, one or more bars being rotatably joined to the surface and having bimorph portions, and a plate rotatably joined to the surface and substantially rigidly joined to the one or more bars. Each bimorph portion bends in response to being heated. The one or more bars and the plate are configured to cause the plate to move farther away from the top surface in response to the one or more bimorph portions being heated.

Abstract: Multiple drives are coupled together to cause rotation about a single axis by an arrangement in which two moveable electrode plates flank a fixed electrode plate such that the opposite direction rotations of the two moveable electrode plates are combined. To this end, at least one arm from at least one of the moveable electrode plates is connected to at least one arm of a moveable electrode plate on the opposite side of the fixed electrode plate, e.g., by a spring. The electrode plates may have comb projections. A post may be coupled at one of its ends to the top of one of the moveable electrode plates, and the post's other end is coupled to a plate, e.g., a mirror or other structure to be moved.

Abstract: The planes of chips in a flip-chip arrangement, when at least one of the chips has an insulating layer running through it, may be electrically connected together by incorporating into the top chip a flexible metalized structure which is pinned to the top layer of the bottom chip using a wire bond ball which is connected to a wire that is attached to a pad on the top layer of the upper chip. A single connection connects both layers of the top chip to the layer on the bottom chip. The flexible structure may be similar to a collapsible cup with a hole in the middle or it may be a tiltable micro mirror.

Abstract: A freely rotatable micromechanical plate is achieved by employing at least three rotatable plates that are each suspended from a substrate via respective springs, and are coupled via other respective springs to at least three moveable plate attachment points, so that rotation of the rotatable plates about an axis transfers motion to the moveable plate attachment points. Respective posts couple the movement of each respective moveable plate attachment point to a moveable plate. In operation, the rotatable plates may be individually rotated, and the resulting motion of each rotatable plate is passed to its respective moveable plate attachment point. The combined motion of the moveable plate attachment points is passed to the moveable plate via the posts. Using proper control, the plate may be made to tip, tilt and piston. Advantageously, the piston motion may achieve a high vertical movement frequency response.

Abstract: An ion trap device comprises a wafer that supports at least one plate forming an ion trapping region therebetween. The plate has an electrically insulating surface and a multiplicity of electrodes disposed on the insulating surface. The electrodes form at least one ion trap in the trapping region when suitable voltages are applied to the electrodes via conductors coupled to the wafer. The device has a multiplicity of ports for introducing ions into the trapping region and for extracting ions from that region. In embodiments that include a multiplicity of such plates, a first one of the plates is oriented at a non-zero angle to the major surface of the wafer and is rotateably mounted on that surface. In one embodiment, at least two of the plates form an elongated micro-channel having an axis of ion propagation, and the electrodes on at least one of the two plates are segmented along the direction of the axis, thereby forming a multiplicity of ion traps along the axis. A controller applies suitable voltage (e.

Abstract: A method and apparatus are disclosed for adjusting the phase of an optical signal by varying the path length of the optical signal using one or more moveable mirrors. The phase adjustment techniques of the present invention may be employed in various optical devices, including 1×n optical switches. The position of the mirrors may be controlled, for example, using micromachined control elements that physically move the mirror along the lightpath. An exemplary 2-by-2 optical switch includes two waveguides configured to include a coupler region. A mirror is positioned at the output of each waveguide. The position of at least one of the mirrors may be adjusted along the optical path and the mirrors reflect the light exiting from the end of the waveguides back into the same waveguide after an adjustable phase delay due to the round trip through an adjustable air gap between the waveguides and corresponding mirrors.

Abstract: The planes of chips in a flip-chip arrangement, when at least one of the chips has an insulating layer running through it, may be electrically connected together by incorporating into the top chip a flexible metalized structure which is pinned to the top layer of the bottom chip using a wire bond ball which is connected to a wire that is attached to a pad on the top layer of the upper chip. A single connection connects both layers of the top chip to the layer on the bottom chip. The flexible structure may be similar to a collapsible cup with a hole in the middle or it may be a tiltable micro mirror.

Abstract: A channelized Wavelength Division Multiplex (WDM) equalizer enables the gain of each WDM channel to be individually controlled, enabling power adjustments of each channel over the equalizer's entire dynamic range. The gain equalizer includes a demultiplexer with each of its outputs interfaced to a different microelectromechanical system (MEMS) reflective device which adjusts optical power in response to a received control signal. The equalizer can be implemented to operate in a reflective mode or in a transmission mode.

Abstract: A method and apparatus are disclosed for adjusting the phase of an optical signal by varying the path length of the optical signal using one or more moveable mirrors. The phase adjustment techniques of the present invention may be employed in various optical devices, including 1×n optical switches. The position of the mirrors may be controlled, for example, using micromachined control elements that physically move the mirror along the lightpath. An exemplary 2-by-2 optical switch includes two waveguides configured to include a coupler region. A mirror is positioned at the output of each waveguide. The position of at least one of the mirrors may be adjusted along the optical path and the mirrors reflect the light exiting from the end of the waveguides back into the same waveguide after an adjustable phase delay due to the round trip through an adjustable air gap between the waveguides and corresponding mirrors.

Abstract: A micro-electro-mechanical system (MEMS) actuator device is disclosed. The MEMS actuator device has an actuated element that is rotatably connected to a support structure via torsional members. The torsional members provide a restoring force to keep the actuated element planar to the surface of an underlying substrate. The surface of the substrate has electrodes formed thereon. The electrodes are adapted to receive an electrical potential. When an electrical potential is applied to certain of the electrodes, an electrostatic force is generated which causes the actuated element to rotate out of plane. The electrodes have three components. At least a portion of two of the components is within the tilting area of the actuated element. The third is outside the tilting area of the actuated element. The tilting area is defined as the surface area of the actuated element as projected onto the underlying substrate.

Abstract: A micro-electro-mechanical system (MEMS) actuator device is disclosed. The MEMS actuator device has an actuated element that is rotatably connected to a support structure via torsional members. The torsional members provide a restoring force to keep the actuated element planar to the surface of an underlying substrate. The surface of the substrate has electrodes formed thereon. The electrodes are adapted to receive an electrical potential. When an electrical potential is applied to certain of the electrodes, an electrostatic force is generated which causes the actuated element to rotate out of plane. The electrodes have three components. At least a portion of two of the components is within the tilting area of the actuated element. The third is outside the tilting area of the actuated element. The tilting area is defined as the surface area of the actuated element as projected onto the underlying substrate.