Abstract: An application specific heat sink assembly for dissipating heat from one or more electronic components is presented with a heat-dissipating substrate selected for one or more of its size, shape, mass, cost, thermal conductivity, or environmental resistance properties; and one or more heat-dissipating studs. Each heat-dissipating stud may be attached to the heat-dissipating substrate such that an electronic component may be attached to each heat-dissipating stud with the heat-dissipating stud providing CTE transition between the heat-dissipating substrate and the electronic component to be cooled. At least one of the heat-dissipating studs may have an upper layer with a CTE similar to the electronic component's CTE and one or more intermediate layers between the upper layer and the heat-dissipating substrate to provide CTE stepping between the CTE of the heat-dissipating substrate and the CTE of the upper layer of the heat-dissipating stud.

Abstract: An application specific heat sink assembly is presented in which a heat-dissipating substrate is selected of a particular size, shape and material in order to meet predetermined heat-dissipating requirements and a heat-dissipating stud is selected or formed of a particular size, shape and material in order to meet predetermined requirements. The heat-dissipating substrate and heat-dissipating stud form a heat sink assembly having application specific features selected to optimize the heat-dissipating, CTE matching, environmental resistance requirements, low mass requirements, size, machinability, cost structure and other desirable features of a particular application for dissipating heat from an electronic component.

Abstract: A method for depositing material on a channel plate such that the material is registered to one or more channels formed in the channel plate includes filling at least one of the channels with a resist that is not wetted by the material; depositing the material on at least a region of the channel plate that includes at least part of the resist; and then removing the resist. The method may be used, in one embodiment, to apply an adhesive or gasket material that is used in assembling a switch.

Abstract: An electrical relay that uses a conducting liquid in the switching mechanism. In the relay, a pair of moveable switching contacts is positioned between a pair of fixed electrical contact pads. A surface of each contact supports a droplet of a conducting liquid, such as a liquid metal. An actuator is energized to move the pair of switching contacts, closing the gap between one of the fixed contact pads and one of the switching contacts, thereby causing conducting liquid droplets to coalesce and form an electrical circuit. At the same time, the gap between the other fixed contact pad and the other switching contact is increased, thereby causing conducting liquid droplets to separate and break an electrical circuit. The actuator is then de-energized and the switching contacts return to their starting positions. The volume of liquid metal is chosen so that liquid metal droplets remain coalesced or separated because of surface tension in the liquid.

Abstract: A method and structure for an optical switch. According to the structure of the present invention, a liquid-filled chamber is housed within a solid material. A plurality of seal belts within the liquid-filled chamber are coupled to the solid material, while a plurality of piezoelectric elements are coupled to a plurality of membranes. The plurality of membranes are coupled to the liquid-filled chamber, and a plurality of optical waveguides are coupled to the liquid-filled chamber. The plurality of seal belts are coupled to a plurality of liquid metal globules. According to the method, one or more piezoelectric elements are actuated, causing one or more corresponding membrane elements to be deflected. The deflection of the membrane element changes a pressure of actuator liquid and the change in pressure of the actuator liquid breaks a liquid metal connection between a first contact and a second contact of the electrical switch.

Abstract: An optical relay is disclosed in which a liquid metal droplet is moved within a switching channel formed in relay housing. An optical path passing through the switching channel is blocked or unblocked by motion of the liquid metal droplet that coalesces with one of two additional liquid metal droplets. Motion of the liquid metal droplets is controlled by heaters that control the pressure of an actuation gas in the switching channel. The liquid metal droplets are held in place by surface tension acting on wettable contact pads within the switching channel. The surface tension of the liquid provides a latching mechanism for the relay. The pressure of the actuation gas is increased by direct heating of the gas or by heating a phase-change liquid to cause it to evaporate.

Abstract: A thin-film resistor device is disclosed. In one embodiment, the device comprises a substrate supporting first and second contacts. A compliant material is deposited on the substrate. A thin-film resistor is deposited on the compliant material and coupled between the first and second contacts.

Abstract: An electrical relay that uses a conducting liquid in the switching mechanism. In the relay, a pair of moveable switching contacts is attached to the free end of a piezoelectric actuator and positioned between a pair of fixed electrical contact pads. The electrical connections to the switching contacts and the fixed electrical contact pads are ground shielded. A surface of each contact supports a droplet of a conducting liquid, such as a liquid metal. The piezoelectric actuator is energized to deform in a bending mode and move the pair of switching contacts, closing the gap between one of the fixed contact pads and one of the switching contacts, thereby causing conducting liquid droplets to coalesce and form an electrical circuit. At the same time, the gap between the other fixed contact pad and the other switching contact is increased, causing conducting liquid droplets to separate and break an electrical circuit.

Abstract: A method and apparatus for multiplexing and demultiplexing optical signals. The apparatus includes first and second optical waveguides coupled via an optical coupler. The optical coupler has a coupling waveguide and an optical switching wedge attached to a piezoelectric actuator. In operation, first and second optical signals are received by the first and second optical waveguides, respectively. If the signals are to be combined, the optical switching wedge is moved to a first position where it is optically coupled to the first optical waveguide. The first optical signal is then transmitted, via the coupling waveguide, to the second optical waveguide, where it is combined with the second optical signal. If the signals are not to be combined, the optical switching wedge is moved to a second position where it is optically uncoupled from the first optical waveguide.

Abstract: The present invention relates to an electrical relay in which a solid slug is moved within a channel and used to make or break an electrical connection. The solid slug is moved by electromagnets. In the preferred embodiment, the slug is wetted by a conducting liquid, such as liquid metal, that also adheres to wettable contact pads within the channel to provide a latching mechanism. The relay is amenable to manufacture by micro-machining techniques.

Abstract: An electrical relay having two wettable electrical contacts, each supporting a conducting liquid. A wettable switch finger is moved from a non-deflected position to first and second positions by action of an actuator. In the first position the switch finger touches the conducting liquid and causes it to wet between the contacts and the switch and thereby complete an electrical circuit between the contacts. When the switch finger is in the second position, the conducting liquid cannot wet between first and second contacts and the switch finger and the electrical circuit between the first and second contacts is broken. The switch finger may be located at the free end of a beam that is deflected or bent by the action of piezoelectric elements.

Abstract: A closed-loop piezoelectric pump is disclosed for use in a fluid delivery system. The pump housing includes a movable diaphragm that defines a pumping chamber within the pump housing, the pumping chamber having an inlet for admitting fluid and an outlet for emitting fluid. A piezoelectric transducer is coupled to the moveable diaphragm and operates to produce a pumping action by varying the volume of the pumping chamber. The piezoelectric transducer may be used to generate an acoustic pressure pulse within the fluid delivery system and to sense reflections of the acoustic pressure pulse caused by impedance changes downstream of the pump. Properties of the fluid path downstream of pump may be determined from the characteristics of the sensed reflections.

Abstract: A method and structure for an electrical switch. According to the structure of the present invention, a liquid-filled chamber is housed within a solid material. A plurality of switch contacts within the liquid-filled chamber are coupled to the solid material, while a plurality of piezoelectric elements are coupled to a plurality of membranes. The plurality of membranes are coupled to the liquid-filled chamber. The plurality of switch contacts are coupled to a plurality of liquid metal globules. According to the method, a piezoelectric element is actuated, causing a membrane element to be deflected. The deflection of the membrane element increases pressure of actuator liquid and the increase in pressure of the actuator liquid breaks a liquid metal connection between a first contact and a second contact of the electrical switch.

Abstract: A method and structure for an electrical switch. A gas-filled chamber is housed within a solid material. Contacts within the gas-filled chamber are coupled to the solid material, while a plurality of piezoelectric elements within the gas-filled chamber are also coupled to the solid material. A slug within the gas-filled chamber is coupled to one or more of the plurality of contacts and further coupled to one or more of the plurality of piezoelectric elements. A liquid metal within the gas-filled chamber is coupled to the slug, and coupled to the plurality of contacts. One or more of the piezoelectric elements are actuated, with the actuation of the one or more piezoelectric elements causing the slug coupled to the one or more piezoelectric elements to move from a first number of contacts to a second number of contacts wherein the first number of contacts and the second number of contacts are wetted by the liquid metal.

Abstract: An electromagnetic optical relay is disclosed in which a solid slug moves within a switching channel formed in relay housing. An optical path passing through the switching channel is blocked or unblocked by motion of the solid slug. Motion of the solid slug is controlled by at least two electromagnetic actuators, such as electrical coils surround the switching channel. Motion of the solid slug is resisted by a liquid, such as a liquid metal, that wets between the solid slug and at least one fixed contact pad in the switching channel. The surface tension of the liquid provides a latching mechanism for the relay. An optical signal may be reflected from the wetted surface of the solid slug and switched to an alternative optical path.

Abstract: An electrical relay that uses a conducting liquid in the switching mechanism. In the relay, a pair of moveable electrical contacts is attached to the free end of a piezoelectric actuator and positioned between pair of fixed electrical contacts. The contacts each support a droplet of a conducting liquid, such as a liquid metal. The piezoelectric actuator is energized to deform in a bending mode and move the pair of moveable contacts, closing the gap between one of the fixed contacts and one of the moveable contacts, thereby causing conducting liquid droplets to coalesce and form an electrical circuit. At the same time, the gap between the other fixed contact and the other moveable contact is increased, thereby causing conducting liquid droplets to separate and break an electrical circuit. The piezoelectric actuator is then de-energized and the moveable electrical contacts return to their starting positions.

Abstract: A method and structure for an optical switch. According to the structure of the present invention, a gas-filled chamber is housed within a solid material. A plurality of contacts within the gas-filled chamber are coupled to the solid material, while a plurality of piezoelectric elements within the gas-filled chamber are also coupled to the solid material. A slug within the gas-filled chamber is coupled to one or more of the plurality of contacts and further coupled to one or more of the plurality of piezoelectric elements. A liquid metal within the gas-filled chamber is coupled to the slug, and coupled to the plurality of contacts.

Abstract: A piezoelectric relay is disclosed in which a solid slug moves within a switching channel formed in relay housing. An electrical circuit passing between fixed contact pads in the switching channel is completed or broken by motion of the solid slug. Motion of the solid slug is controlled by at least two piezoelectric actuators within the switching channel. Motion of the solid slug is resisted by an electrically conductive liquid, such as a liquid metal, that wets between the solid slug and the contact pad in the switching channel. The surface tension of the, liquid provides a latching mechanism for the relay.

Abstract: In a method for forming one or more features in a thick-film ink deposited on a substrate, a photoimagable material is used to define a negative of the one or more features on the substrate. A thick-film ink is then deposited on at least part of the substrate, abutting at least some of the photoimagable material. The thick-film ink is cured, and the photoimagable material is removed. One embodiment of the method is used to produce a channel plate. Another embodiment of the method is used to produce a switch.

Abstract: An electrical relay that uses a conducting liquid in the switching mechanism. In the relay, a pair of moveable switching contacts is attached to the free end of a switch bar and positioned between a pair of fixed electrical contact pads. The connections to the switching contacts and the fixed contact pads are shielded by ground traces. A surface of each contact supports a droplet of a conducting liquid, such as a liquid metal. A piezoelectric actuator is energized to push or pull the switch bar and move the pair of switching contacts, closing the gap between one of the fixed contact pads and one of the switching contacts, thereby causing conducting liquid droplets to coalesce and form an electrical circuit. At the same time, the gap between the other fixed contact pad and the other switching contact is increased, causing conducting liquid droplets to separate and break an electrical circuit. The piezoelectric actuator is then de-energized and the switching contacts return to their starting positions.