Patent application number | Description | Published |
20110102030 | SYSTEM AND METHOD FOR DYNAMICALLY SWITCHING BETWEEN LOW AND HIGH FREQUENCY REFERENCE CLOCK TO PLL AND MINIMIZING PLL OUTPUT FREQUENCY CHANGES - A circuit is provided for use with a clock signal having a plurality of clock pulses, each clock pulse having a rising edge and a falling edge. The circuit is operable to receive a reference signal and to output an output signal. The circuit includes an input divider portion, a feedback divider portion, a phase detector portion, a loop compensation filter portion and a voltage controlled oscillator portion. The input divider portion is arranged to receive the reference signal and is operable to output a divided reference signal. The feedback divider portion is arranged to receive the output signal and is operable to output a divided feedback signal. The phase detector portion is operable to output a phase detector signal based on the divided reference signal and the divided feedback signal. The loop compensation filter portion is operable to output a tuning signal based on the phase detector signal. The voltage controlled oscillator portion is operable to output the output signal based on the tuning signal. The phase detector portion is further operable to change the phase detector signal based on the input divider portion receiving the control signal and the feedback divider portion receiving the control signal, and further based on the control signal and a rising edge of a clock pulse. | 05-05-2011 |
20120293217 | FEEDFORWARD ACTIVE DECOUPLING - There are a variety of duty cycle systems, such as low noise amplifiers or LNAs, that have a large time varying current consumption, and parasitic inductances and resistance (usually from bondwires in the package) that can significantly affect supply currents. Thus, to compensate for these parasitics, a boost circuit is provided that allows for current to be supplied from a separate supply using a feedforward scheme to perform active decoupling. | 11-22-2012 |
20120299797 | HIGH IMPEDANCE SURFACE - An apparatus for emitting radiation is provided. The apparatus comprises an antenna formed on a substrate, and a high impedance surface (HIS). The HIS has a plurality of cells formed on the substrate that are arranged to form an array that substantially surrounds at least a portion of the antenna. Each cell generally includes a ground plane, first plate, second plate, and an interconnect. The ground plane is formed on the substrate, while the first plate (which is substantially rectangular) is formed over and coupled to the ground plane. The first plate for each cell is also arranged so as to form a first checkered pattern for the array. The second plate (which is substantially rectangular) is formed over and is substantially parallel to the first plate. The first and second plates are also substantially aligned with a central axis that extends generally perpendicular to the first and second plates hand have a interconnect formed therebetween. The second plate for each cell is also arranged so as to form a second checkered pattern for the array. | 11-29-2012 |
20120306574 | WIDE BANDWIDTH CLASS C AMPLIFIER WITH COMMON-MODE FEEDBACK - A method for providing common-mode feedback is provided. A common-mode current is applied to a common-gate amplifier, and the common-mode current is sensed. In response to the sensed common-mode current, a control voltage is generated. A first feedback current (which is generated in response to the control voltage) can then be applied to differential ground of the common-gate amplifier if the common-mode current is less than a predetermined threshold. Additionally, a second feedback current (which is generated in response to the control voltage) can be applied to input terminals of the common-gate amplifier if the common-mode current is greater than the predetermined threshold. | 12-06-2012 |
20130021208 | LOOP ANTENNA - A loop antenna is provided. The apparatus comprises a substrate, a first metallization layer, and a second metallization layer. The substrate has first and second feed terminals and a ground terminal. The first metallization layer is disposed over the substrate and includes a first window conductive region, a first conductive region, a second conductive region, and a third conductive region. The first conductive region is disposed over and is in electrical contact with the first feed terminal; it is also is substantially circular and located within the first window region. The second conductive region is disposed over and is in electrical contact with the second feed terminal; it is also substantially circular and is located within the first window region. The a third conductive region is disposed over and is in electrical contact with the ground terminal, and the third conductive region substantially surrounds the first window region. The second metallization layer is disposed over and is in electrical contact with the first, second, and third conductive regions of the first metallization layer, and the second metallization layer includes a second window region that is at least partially aligned with the first window region. | 01-24-2013 |
20130026586 | CROSS-LOOP ANTENNA - An antenna is provided. This antenna is contained within a package that is secured to an IC (which allows radiation to propagated away for a printed circuit board so as to reduce interference), and this antenna includes two loop antennas that are shorted to ground and that “overlap” and includes a “via wall.” With this configuration, circular polarization can be achieved by varying the relative phases of the input signals, and the “via wall” improves efficiency by reducing surface waves. | 01-31-2013 |
20130059551 | ROUTING FOR A PACKAGE ANTENNA - An apparatus is provided. A plurality of transceiver antennas are arranged to form a phased array, where each antenna include a differential transmit antenna and a differential receive antenna arranged in a first pattern. A plurality of transceivers are arranged in a second pattern that is substantially symmetrical, and each transceiver is associated with at least one of the transceiver antennas and includes a feed network. Each feed network has a power amplifier (PA), a first matching network that is coupled between the PA and its associated transmit antenna so as to translate the phase of each differential transmit signal, a low noise amplifier (LNA), and a second matching network that is coupled between the LNA and its associated receive antenna so as to translate the phase of each differential receive signal. | 03-07-2013 |
20140111394 | WAVEGUIDE COUPLER - An apparatus is provided. In the apparatus, there is an antenna package and an integrated circuit (IC). A circuit trace assembly is secured to the IC. A coupler (with an antenna assembly and a high impedance surface (HIS)) is secured to the circuit trace assembly. An antenna assembly has a window region, a conductive region that substantially surrounds the window region, a circular patch antenna that is in communication with the IC, and an elliptical patch antenna that is located within the window region, that is extends over at least a portion of the circular patch antenna, and that is in communication with the circular patch antenna. The HIS substantially surrounds the antenna assembly. | 04-24-2014 |
20140241581 | METHOD AND SYSTEM FOR AUTOMATICALLY COUNTING PHYSICAL OBJECTS - A periphery band is around an excluded region. For automatically counting physical objects within the periphery band and the excluded region, an imaging sensor captures: a first image of the periphery band and the excluded region; and a second image of the periphery band and the excluded region. In response to the first image, a first number is counted of physical objects within the periphery band and the excluded region. Relevant motion is automatically detected within the periphery band, while ignoring motion within the excluded region. In response to the second image, a second number is counted of physical objects within the periphery band and the excluded region. In response to determining that a discrepancy exists between the detected relevant motion and the second number, the discrepancy is handled. | 08-28-2014 |