Patent application number | Description | Published |
20130322508 | Antenna Selection Technique For Fast Diversity - A fast diversity technique using either an EESM or a capacity computation can determine antenna selection in a wireless communication device. A fast Fourier transform (FFT) for the EESM/capacity computation can be performed with consecutive samples of a single symbol period of a short training field (STF) of a packet received by each antenna. The effective signal-to-noise ratio (SNR) for each antenna can be calculated using the results of the EESM or capacity computation. The antenna with the highest effective SNR is selected. | 12-05-2013 |
20140071955 | Dynamic Sounding Control In Wifi - A method of performing dynamic sounding in a wireless communication device includes determining whether to perform sounding based on an age of current channel state information (CSI). An achievable throughput can be recorded as a reference throughput after performing the sounding. A current achievable throughput can be compared with the reference throughput. A CSI timestamp can be reset when the current throughput is above the reference throughput by a first predetermined amount, thereby prolonging a lifespan of the current CSI. The CSI timestamp can be reduced when the current throughput is below the reference throughput by a second predetermined amount, thereby reducing the lifespan of the current CSI. | 03-13-2014 |
20140219110 | Method And System For Dynamic AMPDU Duration Control In A Wireless Communication System - A method of providing aggregated MAC protocol data unit (AMPDU) duration control in a wireless communication device includes setting an AMPDU duration. Pass/fail statistics are collected for each MPDU of an AMPDU in a time window, W. A packet error rate (PER) difference is calculated between first and last sets of MPDUs for each AMPDU in the window. An average PER difference is calculated across all AMPDUs in the window. When the average PER difference is greater than a first threshold, then the AMPDU duration is decreased. When the difference is less than a second threshold, then the AMPDU duration is increased. When the difference is within the first and the second thresholds, then the method returns to the step of collecting for a next time window. The AMPDU duration can also be adjusted based on detected Doppler and line-of-sight transmissions. | 08-07-2014 |
20140269655 | Dynamic Rate Control In WiFi Systems - A wireless device is configured to switch data rates to account for temporary channel conditions or device configuration errors. Pre-selected data rates, more likely to achieve maximum goodput, are stored in a data rate table. The data rate table contains candidate data rates for each pre-selected data rate in the data rate table. When probe transmissions using the preselected data rates fail, dynamic rate probing is utilized to determine a possible cause and extent of the problem. The dynamic rate probing scheme transmits probe transmissions using the candidate data rates and tracks success or failure of these probe transmissions. An analysis of the probe transmissions is used to indicate a possible cause and/or extent of the problematic condition and to determine whether there is a need to reconfigure the data rates in the data rate table. | 09-18-2014 |
20140269964 | SMART ANTENNA ARRAY CONFIGURATION FOR MULTIPLE-INPUT MULTIPLE-OUTPUT COMMUNICATIONS - An access point can include an array of antennas and a smart antenna selector. The smart antenna selector is configured to select a subset of antennas from the antenna array for use in multi-user multiple-input multiple-output (MU MIMO) data transmissions. Stations that are communicatively coupled to the access point can be selected for inclusion in a multi-user group based, at least in part, on performance measurements of the stations. Performance measurements are determined directly and indirectly from data transmissions sent in response to sounding packets. Antennas for use in MU MIMO data transmissions are selected for the antenna array based, at least in part, on previous antenna selections used for single user data transmissions. | 09-18-2014 |
20150023245 | MULTI-BAND MANAGEMENT OF WIRELESS RELAYING NETWORKS - Methods, systems, devices, and apparatuses are described for wireless communications in which first type of traffic may be transmitted from a gateway access point (AP) directly to a station. Beacon signals transmitted to the station are transmitted as part of the first type of traffic. A second type of traffic may be transmitted from the gateway AP to the station via at least one relay AP. The first type of traffic may include low-throughput traffic and may be transmitted over a long-range radio link (e.g., 2 GHz band link or sub-1 GHz band link). The second type of traffic may include high-throughput traffic and may be transmitted over at least one short-range radio link (e.g., 5 GHz band link). The gateway AP may receive low-throughput traffic directly from the station and high-throughput traffic from the station via the at least one relay AP. | 01-22-2015 |
Patent application number | Description | Published |
20130114231 | COMBINED TYPE STORAGE CASE FOR ELECTRONIC DEVICE ACCESSORIES - A combined type storage case for electronic device accessories has a first case, a second case and a third case. The first case includes a first receptacle and a pivotable first plug. The first receptacle and the first plug are electrically connected with each other and allow an electronic device to be charged. The second case is detachably mounted on the first case and includes a chamber defined inside the second case for receiving | 05-09-2013 |
20130134252 | Earphone Cord Winder - The earphone cord winder in accordance with the present invention allows the cord of an earphone device to be wound thereto in order to prevent damage due to excessive bending. The earphone cord winder has a body, a first, a second, and a third protrusion formed around the body at intervals forming an upper cord groove and a lower cord groove, two receiving slots recessed on a first surface of the body, a plug groove recessed on a second surface of the body, a middle groove connecting the opposite sides of the first protrusion, a remote control groove communicating with the upper cord groove, two first recessions communicating with the two receiving slots respectively, at least one second recession recessed on a side of the second protrusion, and at least one third recession recessed on a side of the third protrusion and communicating with the plug groove. | 05-30-2013 |
20130140394 | CABLE ORGANIZER AND ELECTRONIC APPLIANCE WITH SAME - A cable organizer in accordance with the present invention has a top seat, a separating plate and a base plate. The top seat has two plug slots, a winder and a longitudinal slot. The separating plate is mounted to a bottom of the winder and has a slit corresponding to and communicating with the longitudinal slot. The base plate is detachably mounted to a lower portion of the separating plate and has a spindle having a top mounted in the slit of the separating plate. The present invention also relates to an electronic appliance with the cable organizer. The electronic appliance has two sliding slots to which the base are slidably mounted, wherein the base plate has a mounting slot and the electronic appliance has a positioning bead selectively protruding from the side of the electronic appliance and detachably inserted in the mounting slot of the base plate. | 06-06-2013 |
Patent application number | Description | Published |
20090057876 | STACKED PACKAGE STRUCTURE FOR REDUCING PACKAGE VOLUME OF AN ACOUSTIC MICRO-SENSOR - A stacked package structure utilizes flip-chip technology to stack an acoustic micro-sensor on an integrated circuit (IC) device having a recess as a back chamber and cover the acoustic micro-sensor using a glass substrate or a planar substrate with an aperture. With the use of the stacked package structure, the package volume of the acoustic micro-sensor can be reduced effectively. | 03-05-2009 |
20100141362 | MULTI-ACTUATION MEMS SWITCH - A multi-actuation MEMS switch for high frequency signals includes a substrate, a heater disposed on the substrate, a co-planar waveguide disposed on a lowest metal layer, and a movable membrane including at least two metal layers, and an dielectric layer disposed between the co-planar waveguide and the movable membrane. The movable membrane is a fixed-fixed beam structure with a center indentation. When heat is generated and conducted to the movable membrane or electrostatic force is generated between the movable membrane and the co-planar waveguide or both forces are generated, the movable membrane will bend toward the co-planar waveguide. The position of the movable membrane change capacitance on signal line for switching the RF signal. | 06-10-2010 |
20110128094 | Resonator and Periodic Structure - A resonator includes a resonating body and at least one periodic structure having one end connected to the resonating body. The periodic structure includes at least two basic structure units with duplicated configuration. The periodic structure blocks wave propagation caused by the vibration of the resonating body. The resonating body has a resonance frequency f | 06-02-2011 |
20110133855 | RESONATOR, ELASTIC WAVE TRANSMISSION ELEMENT AND FABRICATION METHOD THEREOF - A resonator, an elastic wave transmission element and a method for fabricating the transmission element are provided. The elastic wave transmission element has a first side and a second side. The elastic wave transmission element includes a plurality of structures sequentially arranged along a direction from the first side toward the second side. Each of the structures has a different defect which is different to each other. The impedance of the structures decreases gradually along the direction. As such, the elastic wave transmission element has an impedance match function. | 06-09-2011 |
20120062340 | MICROELECTROMECHANICAL FILTER - A microelectromechanical filter is provided. The microelectromechanical filter includes an input electrode, an output electrode, one or several piezoelectric resonators, one or several high quality factor resonators, and one or several coupling beams. The input electrode and the output electrode are disposed on the piezoelectric resonators. The high quality factor resonator is silicon or of piezoelectric materials, and there is no metal electrode on top of the resonator. The coupling beam is connected between the piezoelectric resonator and the high quality factor resonator. The coupling beam transmits an acoustic wave among the resonators, and controls a bandwidth of filter. The microelectromechanical filter with low impedance and high quality factor fits the demand for next-generation communication systems. | 03-15-2012 |
20120146458 | ULTRASONIC TRANSDUCER DETECTOR - An ultrasonic transducer detector having a high operating frequency is provided. The ultrasonic transducer detector comprises a substrate and an ultrasonic transducer array. The substrate has a plurality of openings, and the ultrasonic transducer array is disposed on the substrate. The ultrasonic transducer array has a plurality of resonance units, and the thickness of each resonance unit is equivalent to ½ wavelength of the operating frequency of the ultrasonic transducer. Each resonance unit comprises an oscillating element and a piezoelectric element. The oscillating element has a first surface adjacent to the substrate, and the piezoelectric element is disposed on the first surface and located in the corresponding opening. | 06-14-2012 |
20130140655 | MEMS ACOUSTIC TRANSDUCER AND METHOD FOR FABRICATING THE SAME - A MEMS acoustic transducer is provided, which includes a substrate, a MEMS chip, and a housing. The substrate has a first opening area and a lower electrode layer disposed over a surface of the substrate, wherein the first opening area includes at least one hole allowing acoustic pressure to enter the MEMS acoustic transducer. The MEMS chip is disposed over the surface of the substrate, including a second opening area and an upper electrode layer partially sealing the second opening area, wherein the upper electrode layer and the lower electrode layer, which are parallel to each other and have a gap therebetween, form an induction capacitor. The housing is disposed over the MEMS chip or the surface of the substrate creating a cavity with the MEMS chip or the substrate. In addition, a method for fabricating the above MEMS acoustic transducer is also provided. | 06-06-2013 |
20130147568 | INTER-DIGITAL BULK ACOUSTIC RESONATOR - An inter-digital bulk acoustic resonator including a resonating structure, one or more input electrodes, one or more output electrodes, a substrate, and a supporting structure disposed on the substrate is provided. The resonating structure includes one or more resonating beams and a coupling beam. The resonating beams are connected at opposite two sides of the coupling beam respectively. The input electrodes and the output electrodes are arranged among the resonating beams in interlace. The input electrodes, the output electrodes, and the resonating beams are parallel to each other. Two ends of the coupling beam are connected to the supporting structure, such that the resonating structure is supported on the substrate. | 06-13-2013 |
20130160554 | CAPACITIVE TRANSDUCER MANUFACTURING METHOD, AND MULTI-FUNCTION DEVICE - A capacitive transducer and manufacturing method thereof is provided. A multifunction device including a plurality of the capacitive transducers is also provided, where the capacitive transducers are disposed on a substrate and include at least one microphone and at least one pressure sensor or ultrasonic device. | 06-27-2013 |
20140175572 | MEMS DEVICE WITH MULTIPLE ELECTRODES AND FABRICATING METHOD THEREOF - A MEMS device with a first electrode, a second electrode and a third electrode is disclosed. These electrodes are disposed on a substrate in such a manner that (1) a pointing direction of the first electrode is in parallel with a normal direction of the substrate, (2) a pointing direction of the third electrode is perpendicular to the pointing direction of the first electrode, (3) the second electrode includes a sensing portion and a stationary portion, (4) the first electrode and the sensing portion are configured to define a sensing capacitor, and (5) the third electrode and the stationary portion are configured to define a reference capacitor. This arrangement facilitates the MEMS device such as a differential pressure sensor, differential barometer, differential microphone and decoupling capacitor to be miniaturized. | 06-26-2014 |
20140184029 | MICROELECTROMECHANICAL SYSTEM-BASED RESONATOR DEVICE - The disclosure provides a structure for a microelectromechanical system (MEMS)-based resonator device. The structure for the MEMS-based resonator device includes at least one resonator unit. The at least one resonator unit comprises a substrate having a trench therein. A pair of first electrodes is disposed on a pair of sidewalls of the trench. A piezoelectric material fills the trench, covering the pair of first electrodes. A second electrode is embedded in the piezoelectric material, separated from the pair of first electrodes by the piezoelectric material. The second electrode disposed in the trench is parallel to the pair of first electrodes. | 07-03-2014 |
20140313089 | MULTI-ANTENNA SYSTEM - A multi-antenna system including a substrate, a ground element, a first antenna element, a second antenna element and a decoupling element is provided. The ground element is disposed on a first surface of the substrate, and the decoupling element is disposed on a second surface of the substrate. Ground portions of the two antenna elements and a first connection terminal of the decoupling element are electrically connected to the ground element. The decoupling element is spaced a first decoupling distance from a part of the first ground portion, and the decoupling element is spaced a second decoupling distance from a part of the second ground portion. A phase difference relative to the two antenna elements is generated by the decoupling element, the first decoupling distance and the second decoupling distance so as to eliminate interference energy between the two antenna elements. | 10-23-2014 |