| Entries |
| Document | Title | Date |
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| 20080284538 | PRINTED CIRCUIT BOARD - A printed circuit board includes a signal layer, a first reference plane layer, and a second reference plane layer. At least one transmission line is arranged on the signal layer. The transmission line includes a main transmission line, and two branch transmission lines connected to an end of the main transmission line. The first reference plane layer is disposed below the signal layer for the main transmission line. The second reference plane layer is disposed below the first reference plane layer for the branch transmission lines, to increase impedance of the two branch transmission lines. | 11-20-2008 |
| 20080284539 | HIGH FREQUENCY CIRCUIT, SEMICONDUCTOR DEVICE, AND HIGH FREQUENCY POWER AMPLIFICATION DEVICE - A small, high performance, multifunctional high frequency circuit that is multiband and multimode compatible reduces loss from a switch formed on the output side of a final stage amplification unit. The final stage amplification unit power amplifies an input signal and outputs an amplified signal. A first matching circuit impedance converts the amplified signal input thereto at a first input impedance, and outputs a first impedance-converted signal at a first output impedance. A control unit that generates a control signal denoting signal path selection information. A switch unit selects one of at least two signal paths based on the control signal, passes the first impedance-converted signal at an on impedance through the selected path, and outputs the pass signal. A second matching circuit impedance converts a pass signal input thereto at a second input impedance, and outputs a second impedance-converted signal at a second output. | 11-20-2008 |
| 20080303609 | POWER LINE COMMUNICATION SYSTEM AND CAPACITIVE SIGNAL COUPLING UNIT - In power line communications using carrier waves of high frequencies in the MHz range such as 2 to 30 MHz, when a coaxial cable for performing transmission of signals and a power line are signal-coupled using a capacitive signal coupling unit, even if an impedance matching circuit is installed in the capacitive signal coupling unit, we have found that leakage current of levels that cannot be neglected from leakage noise considerations flows through the outer sheath of the coaxial cable that transmits the signals, and, accordingly, leaking electromagnetic waves induced by the leakage current flowing through the coaxial cable due to impedance mismatch between the power line and the capacitive signal coupling unit are reduced by an impedance member showing high impedances at high frequencies in the MHz range. | 12-11-2008 |
| 20090021325 | FRONT-END MODULE - A front end module is disclosed. The front end module includes a plurality of antennas receiving different frequency band signals, respectively, an impedance matching circuit unit comprising a plurality of tuners respectively connected to the plurality of antennas to control impedance matching, a selection unit selecting one frequency band signal from multiple frequency band signals passing through the impedance matching circuit unit, a measuring unit measuring signal strength of a received signal selected at the selection unit, and a control unit controlling an operation of the selection unit and an impedance of the tuner according to the signal strength of the received signal measured at the measuring unit. | 01-22-2009 |
| 20090039978 | Variable Power Coupling Device - Systems and methods for a coupling device are shown. In various embodiments, a variable frequency divider comprises a first transmission line and a second transmission line. The first transmission line may comprise a first and a second end. The first end may comprise a first terminal and the second end may comprise a first branch and a second branch. The first transmission line may be configured to receive a first signal at a first frequency at the first terminal and divide the first signal to output the divided first signal at the first branch and the second branch. The second transmission line may be proximate the first transmission line and configured to receive a second signal at a second frequency to control the frequencies of the output divided first signal at the first branch and the second branch through electromagnetic influence between the first transmission line and the second transmission line. | 02-12-2009 |
| 20090273413 | POWER DIVIDER INTEGRATED CIRCUIT - A power divider integrated circuit is provided. The power divider integrated circuit includes a substrate and a power divider circuit formed on one side of the substrate. | 11-05-2009 |
| 20100013572 | APPARATUS FOR MULTIPLE FREQUENCY POWER APPLICATION - Apparatus and methods are provided for a power matching apparatus for use with a processing chamber. In one aspect of the invention, a power matching apparatus is provided including a first RF power input coupled to a first adjustable capacitor, a second RF power input coupled to a second adjustable capacitor, a power junction coupled to the first adjustable capacitor and the second adjustable capacitor, a receiver circuit coupled to the power junction, a high voltage filter coupled to the power junction and the high voltage filter has a high voltage output, a voltage/current detector coupled to the power junction and a RF power output connected to the voltage/current detector. | 01-21-2010 |
| 20100109798 | FRONT-END ARCHITECTURE OF RF TRANSCEIVER AND TRANSCEIVER CHIP THEREOF - An RF front-end architecture is operated in either a transmitting or a receiving mode. The RF front-end architecture comprises an antenna, an impedance match network, a balun and a transceiver chip. The transceiver chip comprises first and second transmit/receive (TR) switches, a transmitter, and a receiver. Because two TR switches are integrated into the chip, the printed circuit board area, BOM cost and pin count of the transceiver chip can be greatly reduced. | 05-06-2010 |
| 20100188165 | ANTENNA DUPLEXER AND COMMUNICATION APPARATUS EMPLOYING THE SAME - A small antenna duplexer that includes antenna terminal, first filter electrically connected to this antenna terminal and passing a first frequency band, second filter electrically connected to antenna terminal and passing a second frequency band, and third filter electrically connected to antenna terminal and passing a third frequency band. First filter and third filter are used for one band, and second filter and third filter are used for another band. | 07-29-2010 |
| 20100194491 | MULTIBAND MATCHING CIRCUIT AND MULTIBAND POWER AMPLIFIER - A multiband matching circuit includes a first matching unit, a second matching unit, and a third matching unit, with all units being connected in series in a signal path. Matching with target impedance is established at a first frequency by appropriately designing the first matching unit and at a second frequency by appropriately designing the second and third matching units. The second matching unit and the third matching unit are designed to make the conversion ratio of the impedance viewed from the connection point between the second matching unit and the third matching unit to a circuit element to the target impedance smaller than the conversion ratio of the impedance viewed from the connection point between the first matching unit and the second matching unit to the circuit element to the target impedance, at the second frequency. | 08-05-2010 |
| 20100219904 | COMMUNICATION SYSTEM WITH FUNCTION OF PREVENTING SIGNAL REFLECTION AND NODE INCLUDED IN THE SAME - The communication system includes a trunk line constituted of first and second signal lines for transmitting differential signals, a plurality of branch lines each branching from the trunk line and connected with a node, and at least one reflection prevention circuit connected between the first and second signal lines. The reflection prevention circuit includes a rectifier circuit configured to inhibit a current from flowing between the first and second signal lines when a voltage between the differential signals is smaller than or equal to a predetermined voltage, and allow a current to flow between the first and second signal lines when the voltage between the differential signals is larger than the predetermined voltage, and a resistive element connected in series to the rectifier circuit between the first and second signal lines. | 09-02-2010 |
| 20100244981 | RADIO FREQUENCY POWER DIVIDER AND COMBINER CIRCUIT - A radio frequency (RF) power splitter circuit is disclosed. The circuit has a predefined operating frequency, and includes a first split port, a second split port, and a common port. A first inductor is connected to the first split port and the common port, and a second inductor is connected to the second split port and the common port. Additionally, there is a resonant capacitor and a compensation resistor connected in parallel across the first split port and the second split port. A parallel resonant circuit is thus defined at the predefined operating frequency. | 09-30-2010 |
| 20100259340 | Active termination and switchable passive termination circuits - According to one exemplary embodiment, an active termination circuit includes at least one active termination branch, where the at least one active termination branch includes at least one transistor for providing an active termination output. The at least one active termination branch further includes an amplifier driving the at least one transistor, where the amplifier has a non-inverting input coupled to the active termination output via a feedback network. The amplifier controls a current flowing through the at least one transistor so as to provide the active termination output. The active termination output can be provided at a drain of the at least one transistor, where a source of the at least one transistor is coupled to ground through a degeneration transistor and a tail current sink. | 10-14-2010 |
| 20100308934 | INVISIBLE BALUN AND METHOD OF MAKING SAME - An apparatus and method for reducing stray magnetic fields include a decoupling circuit includes a balun that comprises a transmission line. The transmission line includes a first spiral positioned substantially parallel to a first plane, the first spiral emanating from a inner portion of the first spiral in a first spiral direction. The transmission line also includes a second spiral positioned substantially parallel to the first plane, the second spiral emanating from a inner portion of the second spiral in the first spiral direction, wherein the inner portion of the first spiral is electrically coupled to the inner portion of the second spiral, and wherein the transmission line comprises a signal line and a ground line. The balun further comprises a first capacitor electrically coupled to the transmission line. | 12-09-2010 |
| 20100321129 | CIRCUIT DEVICE AND METHOD OF COUPLING TO AN ANTENNA - In an embodiment, a circuit device for coupling to an antenna includes a first impedance matching circuit configured to couple to the antenna and a second impedance matching circuit configured to couple to the antenna. The circuit device further includes a power amplifier coupled to the first impedance matching circuit and includes a low-noise amplifier coupled to the second impedance matching circuit. Additionally, the circuit device includes a selectable impedance adjustment circuit coupled between the low-noise amplifier and the second impedance matching circuit, which selectable impedance adjustment circuit is configured to selectively adjust an impedance associated with the low-noise amplifier when the power amplifier is transmitting a signal through the antenna. | 12-23-2010 |
| 20110025430 | POWER SPLITTER - A power splitter and/or combiner is described. The power splitter may be provided as a broadband, passive, divide by N power splitter that may be advantageously employed in providing power to multiple electrodes within a plasma source. The power splitter comprises a transmission line and a plurality of N secondary windings arranged about the transmission lines. | 02-03-2011 |
| 20110121912 | ASYMMETRIC POWER DIVIDER - Disclosed herein is an asymmetric power divider. The asymmetric power divider includes a power dividing unit, a first matching network, and a second matching network. The power dividing unit supplies different amounts of power to a carrier amplifier and a peaking amplifier, which are connected in parallel. The first matching network is connected between the power dividing unit and the carrier amplifier so as to perform impedance matching between the power dividing unit and the carrier amplifier. The second matching network is connected between the power dividing unit and the peaking amplifier so as to perform impedance matching between the power dividing unit and the peaking amplifier. | 05-26-2011 |
| 20110169587 | SIGNAL TRANSMITTING/RECEIVING CIRCUIT INCLUDING AN IMPEDANCE MATCHING CIRCUIT - A signal transmitting/receiving circuit includes a transmitter, a receiver, a balun and an impedance matching circuit. The transmitter is utilized for transmitting an output signal. The receiver is utilized for receiving an input signal. The balun includes a first input terminal, a second input terminal and an output terminal. The impedance matching circuit, which is coupled between the transmitter, the receiver, and the balun, provides transmitting impedance when the transmitter transmits the output signal such that an output signal may be output at an output terminal of the balun via a transmitting path. Also, the impedance matching circuit provides transmitting impedance when the receiver receives the input signal such that the input signal may be transmitted from the output terminal of the balun to the receiver via a receiving path. | 07-14-2011 |
| 20110221543 | Impedance Matching Circuit for Matching Planar Antennas - A circuit includes a signal path having a node between a signal path input and a signal path output. A first inductive element is connected between the signal path input and the node and a first capacitive element whose capacitance is variably adjustable is connected between the node and the signal path output. A second variable-capacitance capacitive element is connected between the signal path input and ground. A second inductive element is connected between the node and ground, and a third inductive element is connected between the signal path output and ground. | 09-15-2011 |
| 20110273243 | COMBINER COMPRISING ACOUSTIC TRANSDUCERS - An electrical signal combiner includes at least one first element and a second element respectively connected to a first input port and to a second input port, and a third element connected to an output port, the electrical signals being propagated between the input and output ports. The combiner includes a medium; and the first, second and third elements are acoustic wave transducers, the electrical signals being carried by acoustic waves propagated between the input and output ports within the medium. Advantageously, the first transducer and the third transducer are separated by an acoustic distance of (2k+1)λ/4 with k an integer greater than or equal to 0 with λ the acoustic propagation wavelength; the second transducer and the third transducer are separated by an acoustic distance of (2k′+1)λ/4 with k′ an integer greater than or equal to 0; and the first and second transducers are separated by an acoustic distance of (2k″+2)λ/4 with k″ an integer greater than or equal to 0—in such a manner as to, on the one hand, generate constructive interference at the output port and, on the other hand, to isolate the first and second input ports by destructive interference of acoustic waves at the ports. | 11-10-2011 |
| 20110285476 | SYSTEM AND METHOD FOR RETAINING A DESIRED RETURN LOSS WHEN DYNAMICALLY VARYING A NUMBER OF ACTIVE PATHS - When dynamically varying a number of active paths in a system, a desired return loss is maintained. Certain embodiments enable dynamic varying of the impedance of parallel signal paths in a system responsive to the number of active ones of the parallel paths dynamically changing, in order to maintain a relatively constant impedance match between a source and the combination of parallel paths, thereby retaining a desired return loss. | 11-24-2011 |
| 20110291771 | APPARATUS FOR MULTIPLE FREQUENCY POWER APPLICATION - Apparatus and methods are provided for a power matching apparatus for use with a processing chamber. In one aspect of the invention, a power matching apparatus is provided including a first RF power input coupled to a first adjustable capacitor, a second RF power input coupled to a second adjustable capacitor, a power junction coupled to the first adjustable capacitor and the second adjustable capacitor, a receiver circuit coupled to the power junction, a high voltage filter coupled to the power junction and the high voltage filter has a high voltage output, a voltage/current detector coupled to the power junction and a RF power output connected to the voltage/current detector. | 12-01-2011 |
| 20120007691 | IMPEDANCE MATCHING APPARATUS AND METHOD OF ANTENNA CIRCUIT - An impedance matching apparatus is provided. The impedance matching apparatus includes a signal separation unit, an impedance detection unit, and an impedance matching unit. The signal separation unit separates a transmission and reception signal, and selectively passes a desired frequency corresponding to the transmission and reception signal. The impedance detection unit receives a signal outputted from the signal separation unit to detect first and second electric potentials between a plurality of impedances. The impedance matching unit compares the first and second electric potentials detected by the impedance detection unit to match the impedances. | 01-12-2012 |
| 20120182086 | SEMICONDUCTOR DEVICE - When a power amplifier mounted in mobile communications equipment, such as a mobile-phone, is composed of a balanced amplifier, technology with which the loss of the electric power composition in a power combiner can be reduced is provided. According to the technical idea of the present embodiment, by dividing an isolation capacitor element into two capacitor elements with high symmetry and coupled in parallel, it is possible to make almost equal parasitic capacitance arising from these capacitor elements, even when the capacitor elements are formed as interlayer capacitor elements of the wiring substrate. | 07-19-2012 |
| 20120212303 | METHOD, STRUCTURE, AND DESIGN STRUCTURE FOR A THROUGH-SILICON-VIA WILKINSON POWER DIVIDER - A method, structure, and design structure for a through-silicon-via Wilkinson power divider. A method includes: forming an input on a first side of a substrate; forming a first leg comprising a first through-silicon-via formed in the substrate, wherein the first leg electrically connects the input and a first output; forming a second leg comprising a second through-silicon-via formed in the substrate, wherein the second leg electrically connects the input and a second output, and forming a resistor electrically connected between the first output and the second output. | 08-23-2012 |
| 20120256700 | ALL-PASS NETWORK - A phase-shift network may include a first capacitor connected between a first input node and a first output node, and a second capacitor connected between a second input node and a second output node. Further, a first filter section may be connected between the first input node and the second output node, and a second filter section may be connected between the second input node and the first output node. One or both of the first and second filter sections may include a first inductance and an high-pass network. The high-pass network may include third and fourth capacitors and a first inductor. The first inductance and third and fourth capacitors may be connected in series between the respective input and output nodes. The first inductor may have a first end connected to an intermediate node between the third and fourth capacitors and a second end connected to a circuit ground. | 10-11-2012 |
| 20130135060 | ANTENNA TUNER AND METHOD FOR ADJUSTING ANTENNA IMPEDANCE - Disclosed are an antenna tuner and a method for adjusting antenna impedance. The antenna tuner includes a reference impedance resistor, a first coupler having an isolated port connected to one end of the reference impedance resistor, a second coupler having an input port connected to an output port of the first coupler and an output port connected to the antenna, and an impedance adjusting device group connected to the second coupler to adjust impedance of the antenna. An impedance controller generates an impedance adjustment control signal according to a first voltage applied to a coupled port of the first coupler, and a second voltage applied to a coupled port of the second coupler to provide the impedance adjustment control signal to the impedance adjusting device group. | 05-30-2013 |
| 20130169377 | HIGH FREQUENCY SIGNAL COMBINER - A high-frequency signal combiner comprises at least one first bridge coupler ( | 07-04-2013 |
| 20130257560 | COUPLING INTERFACES FOR COMMUNICATION TRANSCEIVERS OVER POWER LINES - A coupling interface couples a transceiver to one or more capacitive voltage dividers of a power transmission system. The coupling interface includes a first signal path including an adjustable inductance configured to form a resonance circuit with a capacitance associated with the one or more capacitive voltage dividers. The coupling interface may include a second signal path including an adjustable inductance configured to form a resonance circuit with the capacitance associated with the one or more capacitive voltage dividers. | 10-03-2013 |
| 20130321098 | ELECTRONIC DEVICE AND SEMICONDUCTOR DEVICE - A semiconductor device includes: a terminal configured to input a signal from a signal source; a receiver configured to receive the signal from the signal source through the terminal; and a terminal circuit configured to be coupled between the terminal and an input end of the receiver, and to suppress reflected wave caused by signal reflection at the receiver, wherein impedance of a wire line connecting the terminal and the input end of the receiver, and direct-current impedance of a resistance component included in the terminal circuit are set lower than impedance of an external wire line connected to the terminal. | 12-05-2013 |
| 20140167878 | IMPEDANCE MATCHING APPARATUS - Disclosed is an impedance matching apparatus performing impedance matching between a front-end module and an antenna. The impedance matching apparatus includes an RF front end providing a multi-band RF signal, a reflected power measuring module measuring a reflection coefficient for the RF input signal, a matching unit adjusting impedance so that the reflection coefficient is minimized, a first switch module provided in the RF front end to selectively switch the RF signal onto a bypass path, and a controller allowing the RF signal to be switched onto the bypass path if a specific frequency range is detected from the reflection coefficient. | 06-19-2014 |
| 20140266500 | Integrated Circuit for Transmitting and Receiving an RF Signal - An integrated circuit, comprising a single-ended pin for transmitting and/or receiving an RF signal. A first matching network is configured to match an impedance of the RF signal. A second matching network is configured to match an impedance of an on-chip differential circuit. A third matching network is configured to match an impedance of an on-chip single-ended circuit, wherein the third matching network is connectable to the first matching network. A transformer is connected or connectable to the second matching network and to the first matching network. Switches control an operating mode of the integrated circuit The second matching network is connected with the first matching network via the transformer, or the third matching network is connected with the first matching network. | 09-18-2014 |
| 20150028962 | RADIO FREQUENCY SIGNAL SPLITTER AND MATCHER - This application relates to systems and methods for splitting a current signal into at least two signals that are out of phase with each other. The power splitter may include a conductive element that may generate standing magnetic field that alternates at specified frequency. An inductor placed near or in the magnetic field may induce an alternating current at the specified frequency. Each end of the inductor may be coupled to a connector that may be coupled to an antenna that may be incorporated into a plasma processing chamber. | 01-29-2015 |
| 20150048898 | Tunable Impedance Matching Network - A tunable impedance matching network comprising shunt (e.g. parallel) tunable capacitors and other fixed reactive elements is presented. The tunable impedance matching network can be used as one component of an SPTM (scalable periphery tunable matching) amplifier. | 02-19-2015 |
| 20150048899 | COMBINER CIRCUIT FOR A CLASS-E OUTPHASING POWER AMPLIFIER - Lumped-element based class-E Chireix combiners are disclosed that are equivalents of a quarter-wave transmission line combiner. The proposed class-E equivalent power amplifier circuits that are used can be derived from a parallel tuned class-E implementation. The proposed low-pass equivalents can behave similarly in terms of class-E performance, but absorb the 90 degree to transmission line. | 02-19-2015 |
| 20160049910 | DOHERTY POWER AMPLIFIER COMBINER WITH TUNABLE IMPEDANCE TERMINATION CIRCUIT - Doherty power amplifier combiner with tunable impedance termination circuit. A signal combiner can include a balun transformer circuit having a first coil and a second coil. The first coil can be implemented between a first port and a second port. The second coil can be implemented between a third port and a fourth port. The first port and the third port can be coupled by a first capacitor. The second port and fourth port can be coupled by a second capacitor. The first port can be configured to receive a first signal. The fourth port can be configured to receive a second signal. The second port can be configured to yield a combination of the first signal and the second signal. The signal combiner can include a termination circuit that couples the third port to a ground. The termination circuit can include a tunable impedance circuit. | 02-18-2016 |
| 20160156328 | HIGH-FREQUENCY MODULE | 06-02-2016 |
| 20160156329 | HIGH-FREQUENCY MODULE | 06-02-2016 |
