Patent application number | Description | Published |
20090081771 | SYSTEM AND METHOD FOR HEATING, COOLING AND HEAT CYCLING ON MICROFLUIDIC DEVICE - An integrated heat exchange system on a microfluidic card. According to one aspect of the invention, the portable microfluidic card has a heating, cooling and heat cycling system on-board such that the card can be used portably. The microfluidic card includes one or more reservoirs containing exothermic or endothermic material. Once the chemical process of the reservoir material is activated, the reservoir provides heat or cooling to specific locations of the microfluidic card. Multiple reservoirs may be included on a single card to provide varying temperatures. The assay chemicals can be moved to the various reservoirs to create a thermal cycle useful in many biological reactions, for example, Polymerase Chain Reaction (PCR) or rtPCR. According to another aspect of the invention, the integrated heat exchanger is an adjacent microfluidic circuit containing fluid that is either independently heated or cooled, or is an exothermic or endothermic material, such that the fluid in the adjacent circuit imparts a change in temperature to the assay fluid in an independent circuit. According to yet another aspect of the invention, a thermal electric cooler (TEC) is used for thermocycling the amplification chamber of a disposable microfluidic card. | 03-26-2009 |
20090148847 | RAPID MAGNETIC FLOW ASSAYS - Disclosed is an improvement in methods for nucleic acid and immunological bioassays. The methods comprise a step for “sweeping” paramagnetic bead: target molecule complexes so as to capture them with an affinity capture agent on a test pad by moving a magnetic force field from outside to inside the test pad area so as to bring into contact the paramagnetic complexes with the capture agent, while sweeping any unbound paramagnetic material off the test pad by moving the magnetic field from inside to outside the test pad area. Surprisingly, the paramagnetic complexes are rapidly affinity-extracted from the moving magnetic field. | 06-11-2009 |
20090148933 | INTEGRATED NUCLEIC ACID ASSAYS - Integrated microfluidic cartridges for nucleic acid extraction, amplification, and detection from clinical samples are disclosed. The devices are single-entry, sanitary, and disposable. The devices enable simplex or multiplex nucleic acid target detection, as for example: assay panels for multiple infectious agents, or assay panels for cancerous cell types. Methods for use of microfluidic cartridges in a fully automated, pneumatically controlled apparatus are also disclosed. | 06-11-2009 |
20090325276 | INTEGRATED MICROFLUIDIC ASSAY DEVICES AND METHODS - Combinations of microfluidic diagnostic testing modules for simultaneous evaluations of serological and molecular biological targets are provided, and include panel testing for both antibodies (or antigens) and nucleic acid targets in one single-use device. These improvements are directed to evaluating the overall progress and activity of a pathogenic process in real time, at the point of care, not merely the presence or absence of a particular diagnostic marker, which can often be incomplete or misleading. | 12-31-2009 |
20120329142 | INTEGRATED NUCLEIC ACID ASSAYS - Integrated microfluidic cartridges for nucleic acid extraction, amplification, and detection from clinical samples are disclosed. The devices are single-entry, sanitary, and disposable. The devices enable simplex or multiplex nucleic acid target detection, as for example: assay panels for multiple infectious agents, or assay panels for cancerous cell types. Methods for use of microfluidic cartridges in a fully automated, pneumatically controlled apparatus are also disclosed. | 12-27-2012 |
Patent application number | Description | Published |
20130067725 | Handheld Medical Devices Including Microwave Amplifier Unit At Device Handle - A method of manufacturing a medical device includes the initial steps of providing a handle assembly and providing a microwave-signal-amplifying module. The handle assembly includes a handle body defining a chamber therein. The handle body is configured to support an energy applicator at the distal end thereof. The microwave-signal-amplifying module includes a microwave amplifier unit adapted to amplify a high-frequency input signal to generate a high-frequency output signal. The microwave-signal-amplifying module includes one or more connector portions including one or more electrical connectors adapted to be removeably coupleable to one or more electrical conductors associated with the handle body. The method also includes the step of positioning the microwave-signal-amplifying module into the chamber to bring the one or more electrical connectors of the one or more connector portions into electrical engagement with one or more electrical connectors associated with the handle body. | 03-21-2013 |
20130072920 | Handheld Medical Devices Including Microwave Amplifier Unit At Device Handle - A medical device includes a handle assembly including a distal end, a probe extending distally from the distal end of the handle assembly, and a microwave amplifier unit disposed within the handle assembly. The microwave amplifier unit is adapted to amplify a high-frequency input signal to generate a high-frequency output signal to be transmitted to the probe. | 03-21-2013 |
20130072921 | Handheld Medical Devices Including Microwave Amplifier Unit At Device Handle - A medical device includes a handle assembly and a probe-and-amplifier assembly. The handle assembly includes a handle body defining a chamber therein. The probe-and-amplifier assembly includes a probe and a microwave amplifier unit. The probe extends distally from the distal end of the handle assembly. The microwave amplifier unit is disposed within the chamber. The microwave amplifier unit and the probe are mechanically coupled to one another to form a unitary body. The probe-and-amplifier assembly is selectively removable from the handle assembly. | 03-21-2013 |
20130072922 | Handheld Medical Devices Including Microwave Amplifier Unit At Device Handle - A system includes a microwave signal generator and a medical device. The medical device includes a handle assembly, a microwave-signal-amplifying module, and a probe. The microwave-signal-amplifying module includes a microwave amplifier unit. The microwave amplifier unit is adapted to amplify a high-frequency input signal to generate a high-frequency output signal. The microwave amplifier unit is disposed within the handle assembly. The probe extends distally from the distal end of the handle assembly and is operably coupled to an output of the microwave-signal-amplifying module. | 03-21-2013 |
20130072923 | Handheld Medical Devices Including Microwave Amplifier Unit At Device Handle - A method of directing energy to tissue includes the steps of providing a handheld device including an energy applicator and a handle assembly configured to support the energy applicator at a distal end thereof, and transmitting energy from an output of a microwave amplifier unit disposed within the handle assembly through the energy applicator to tissue. | 03-21-2013 |
20130144284 | Vessel Sealing Using Microwave Energy - The present disclosure provides for an end effector assembly for microwave forceps. The end effector assembly includes a pair of opposing jaw members movable from a first position in spaced relation relative to one another to at least one subsequent position wherein the jaw members cooperate to grasp tissue therebetween. Each of the jaw members includes a microwave antenna assembly and a shielding member including a metallic plate coupled to ground and a dielectric material. The end effector assembly also includes a splitter configured to receive an active signal from a source of microwave energy and split the active signal into a first signal transmitted to the microwave antenna assembly in one of the jaw members and a second signal transmitted in the microwave antenna assembly in the other jaw member. | 06-06-2013 |
20130180104 | Printed Circuit Boards Including Strip-Line Circuitry and Methods of Manufacturing Same - A method of manufacturing a printed circuit board includes the initial steps of providing a first layer stack and providing a second layer stack. The first layer stack includes a first electrically-insulating layer. The first electrically-insulating layer includes a first surface and one or more electrically-conductive traces disposed on the first surface. The second layer stack includes a second electrically-insulating layer and a first electrically-conductive layer. The second electrically-insulating layer includes a first surface and an opposite second surface. The first electrically-conductive layer is disposed on the first surface of the second electrically-insulating layer. The second layer stack further includes a cut-out area defining a void that extends therethrough. The cut-out area is configured to receive therein at least a portion of a device to be coupled to the first surface of the first electrically-insulating layer and electrically-coupled to one or more of the one or more electrically-conductive traces. | 07-18-2013 |
20130180105 | Printed Circuit Boards Including Strip-Line Circuitry and Methods of Manufacturing Same - A method of manufacturing a printed circuit board includes the steps of providing a first layer stack including a first electrically-conductive layer and a first electrically-insulating layer and providing a second layer stack including a second electrically-insulating layer. The first electrically-conductive layer is disposed on the first surface of the first electrically-insulating layer. The second electrically-insulating layer includes one or more electrically-conductive traces disposed on a first surface thereof. The method also includes mounting a device on the first surface of the second electrically-insulating layer such that the device is electrically-coupled to at least one of the one or more electrically-conductive traces, and providing the first layer stack with a cut-out area defining a void that extends from the second surface of the first electrically-insulating layer to the first surface of the first electrically-conductive layer. The cut-out area is configured to receive at least a portion of the device therein. | 07-18-2013 |
20130180762 | Printed Circuit Boards Including Strip-Line Circuitry and Methods of Manufacturing Same - A multi-layer printed circuit board includes a first layer stack and a second layer stack coupled to the first layer stack. The first layer stack includes a first electrically-insulating layer, a second electrically-insulating layer, and a first electrically-conductive layer disposed between the first and second electrically-insulating layers. The second layer includes a third electrically-insulating layer and a second electrically-conductive layer. The first layer stack and/or the second layer stack include a cut-out area defining a void that extends therethrough. The multi-layer printed circuit board further includes a first signal layer disposed in association with the first electrically-insulating layer of the first layer stack or the third electrically-insulating layer of the second layer stack, a second signal layer disposed in association with the second electrically-insulating layer of the first layer stack, and a device at least partially disposed within the cut-out area and electrically-coupled to the first and second signal layers. | 07-18-2013 |
20130180763 | Printed Circuit Boards Including Strip-Line Circuitry and Methods of Manufacturing Same - A printed circuit board includes a first layer stack and a second layer stack coupled to the first layer stack. The first layer stack includes a first electrically-insulating layer, a first electrically-conductive layer, and a cut-out area defining a void that extends therethrough. The first electrically-insulating layer includes a first surface and an opposite second surface. The first electrically-conductive layer is disposed on the first surface of the first electrically-insulating layer. The second layer stack includes a second electrically-insulating layer. The second electrically-insulating layer includes a first surface and an opposite second surface. One or more electrically-conductive traces are disposed on the first surface of the second electrically-insulating layer. The printed circuit board further includes a device at least partially disposed within the cut-out area. The device is electrically-coupled to one or more of the one or more electrically-conductive traces disposed on the first surface of the second electrically-insulating layer. | 07-18-2013 |
20140002056 | SYSTEMS AND METHODS FOR MEASURING THE FREQUENCY OF SIGNALS GENERATED BY HIGH FREQUENCY MEDICAL DEVICES | 01-02-2014 |
20150131246 | PRINTED CIRCUIT BOARDS INCLUDING STRIP-LINE CIRCUITRY AND METHODS OF MANUFACTURING SAME - A printed circuit board includes a first layer stack and a second layer stack coupled to the first layer stack. The first layer stack includes a first electrically-insulating layer, a first electrically-conductive layer, and a cut-out area defining a void that extends therethrough. The first electrically-insulating layer includes a first surface and an opposite second surface. The first electrically-conductive layer is disposed on the first surface of the first electrically-insulating layer. The second layer stack includes a second electrically-insulating layer. The second electrically-insulating layer includes a first surface and an opposite second surface. One or more electrically-conductive traces are disposed on the first surface of the second electrically-insulating layer. The printed circuit board further includes a device at least partially disposed within the cut-out area. The device is electrically-coupled to one or more of the one or more electrically-conductive traces disposed on the first surface of the second electrically-insulating layer. | 05-14-2015 |
Patent application number | Description | Published |
20110078786 | Providing a User Input Interface Prior to Initiation of an Operating System - A processor-based system, including systems without keyboards, may receive user inputs prior to booting. This may done using the graphics controller to generate a window which allows the user to input information. The system firmware may then compare any user inputs, such as passwords, and may determine whether or not to actually initiate system booting. | 03-31-2011 |
20120159219 | VR POWER MODE INTERFACE - In some embodiments, a control interface and associated control entity are provided to synchronize CPU activities to CPU power delivery network such as VR mode of operation, based on CPU power demands or the prediction of actual CPU current consumption. In some embodiments, the synchronization is controlled in such timely fashion so that the power states or power-related events are entered by a CPU (or core) based on characteristics of a VR supplying power to the CPU (or core). | 06-21-2012 |
20140001849 | UNIVERSAL CHARGER | 01-02-2014 |
20140183974 | UNIVERSAL POWER INTERFACE - An electronic device is provided that may include an input port to couple to an external device, and a universal power interface to determine a type of the external device connected to the input port based at least on a voltage of a voltage supply line. The universal power interface may provide a power delivery path based on the determined type of the external device. | 07-03-2014 |
20140184137 | CHARGING SYSTEM FOR ELECTRONIC DEVICE - A charging system may include a switching device to receive an output voltage from an alternative power source and to provide an output voltage of the charging system, and an algorithm device to provide a control signal to the switching device based on a sensed power from the power source and a sensed output voltage from the charging system. | 07-03-2014 |
20140184160 | ELECTRONIC DEVICE TO BE POWERED BY ALTERNATIVE POWER SOURCE - A mobile device may be provided that includes an input port, an adjusting device, and a voltage regulator. The input port may receive power from an alternative power source or a DC power supply. The mobile device may receive the power from the input port, adjust a power characteristic of the power, and provide the power having the adjusted power characteristic. The voltage regulator may receive the adjusted power and provide a regulated voltage to a load. | 07-03-2014 |
20140304528 | CONTROLLING SUPPLY OF POWER TO COMPUTING DEVICES WITH DYNAMICALLY VARIABLE ENERGY CAPACITY - Methods and apparatus relating to controlling the supply of power to computing devices with dynamically variable energy capacity are described. In one embodiment, logic causes modification to supply of power from a power source to one or more loads in response to a comparison of an output of the power source and a threshold value. The output of the power source may vary over a time period (e.g., oscillating) that causes the one or more loads to become inoperational. Other embodiments are also disclosed and claimed. | 10-09-2014 |
20160006350 | TECHNIQUES FOR REDUCING SWITCHING NOISE AND IMPROVING TRANSIENT RESPONSE IN VOLTAGE REGULATORS - Methods and apparatus relating to reducing switching noise and improving transient response in voltage regulators are described. In an embodiment, one or more pulses are inserted into an output waveform of a voltage regulator. The one or more pulses introduce multiple frequencies into the output waveform of the voltage regulator (e.g., to reduce acoustic noise). In another embodiment, the output voltage of a voltage regulator is modified in response to comparison of the output voltage with at least one of a plurality of threshold values. The plurality of threshold values includes an upper trigger point voltage value and a lower trigger point voltage value. Other embodiments are also disclosed and claimed. | 01-07-2016 |
Patent application number | Description | Published |
20090250597 | OPTICAL FIBER ASSEMBLY WRAPPED ACROSS ROLL-NOD GIMBAL AXES IN A DIRCM SYSTEM - A control mechanism pins an optical fiber assembly on and off gimbal and between gimbals to route the assembly from an off-gimbal optical source across the gimbal axis/axes to an on-gimbal optical element so that the fiber assembly moves with the rotation of the gimbals. To accommodate a relatively large range of motion, the control mechanism is suitably configured to route the fiber assembly in a “U-shaped” loop with one end pinned off-gimbal in a stationary guide track and the other end pinned on-gimbal point in a rotating guide track so that the loose fiber assembly is constrained in the concentric tracks on and off gimbal. As the gimbal rotates, the loop seats onto one guiding track and peels off of the other guiding track while always maintaining its U shape. To accommodate a relatively small range of motion in other gimbal configurations, the control mechanism is suitably configured to pin one end of the fiber assembly off-gimbal and pass the fiber assembly directly over the gimbal where it is pinned on the other side of the gimbal. In a multi-gimbal pointer, the fiber assembly preferably exhibits different mechanical stresses as it crosses the different gimbals. | 10-08-2009 |
20110315807 | ONE-PIECE NANO/NANO CLASS NANOCOMPOSITE OPTICAL CERAMIC (NNOC) EXTENDED DOME HAVING SEAMLESS NON-COMPLEMENTARY GEOMETRIES FOR ELECTRO-OPTIC SENSORS - A one-piece extended dome having a spanning angle greater than 180 degrees. The dome is integrally formed of a Nano/Nano class Nanocomposite Optical Ceramic (NNOC) material. The extended dome comprises seamless first and second non-complementary geometric shapes, such as a first spherical geometry and a second conical or ogive geometry. The Nano/Nano class NNOC material comprises two or more different chemical phases (nanograins) dispersed in one another, each type having a sub-micron grain dimension in at least the direction of light transmission. The material is a true NNOC material in that all of the constituent elements have sub-micron grain dimensions, there is no host matrix. | 12-29-2011 |
20130342921 | NANO-NANO-COMPOSITE OPTICAL CERAMIC LENSES - An optical component, for example a lens, integrally formed of a nano/nano class nanocomposite optical ceramic (NNCOC) material. The constituent nanograin materials of the NNCOC material are selected to tailor the thermal and optical properties of the lens so as to provide a lens with a substantially constant focal length over an operating temperature range and/or an optical system in which the image position does not change appreciably over the operating temperature range. | 12-26-2013 |
20140047867 | Brazed Joint for Attachment of Gemstones to Each Other and/or a Metallic Mount - The specification relates to a gemstone setting. The gemstone setting includes a gemstone, a mounting surface and a braze joint. The braze joint is formed from a reactive metallic alloy with the reactive metallic alloy adhering the gemstone to the mounting surface. The braze joint is substantially concealed from a direct line of sight from a top portion of the gemstone by preventing excessive alloy from getting outside a desired braze area. | 02-20-2014 |
20140205370 | VEHICLE HAVING A NANOCOMPOSITE OPTICAL CERAMIC DOME - A vehicle, such as a missile, is disclosed. The vehicle includes an optically transparent dome, a vehicle body, and a brazed joint directly coupling the dome to the vehicle body. The dome is formed of a Nanocomposite Optical Ceramic (NCOC) material comprising two or more different types of nanograins dispersed in one another. Each nanograin type has a coefficient of thermal expansion (CTE), and an aggregate CTE of the NCOC material is based on the CTE of each nanograin type. | 07-24-2014 |