Patent application number | Description | Published |
20100244978 | METHODS AND APPARATUS FOR MATCHING AN ANTENNA - A method and an arrangement for matching the antenna of a radio device in transmitting condition. The antenna impedance in the output of the power amplifier of a transmitter is adjusted by means of a π-shaped reactive matching circuit, the component values of which can be selected from a relatively wide array of the alternatives. The component values are selected by means of the multiple-way switches, which only are located in the transverse branches of the matching circuit. The switches are set ( | 09-30-2010 |
20120319918 | ANTENNA MATCHING APPARATUS AND METHODS - Apparatus and methods for matching the antenna of a radio device. In one embodiment, a capacitive sensor is arranged in the antenna structure and configured to detect the electric changes in the surroundings of the antenna. The mismatch caused by a change is rectified by means of the signal proportional to the sensor capacitance. This capacitance and the frequency range currently in use are input variables of a control unit. The antenna impedance is adjusted by means of a reactive matching circuit, the component values of which can be selected from a relatively wide array of alternatives by way of change-over switches, which are located in the transverse branches of the matching circuit. | 12-20-2012 |
20130088404 | MULTI-FEED ANTENNA APPARATUS AND METHODS - A space efficient multi-feed antenna apparatus, and methods for use in a radio frequency communications device. In one embodiment, the antenna assembly comprises three (3) separate radiator structures disposed on a common antenna carrier. Each of the three antenna radiators is connected to separate feed ports of a radio frequency front end. In one variant, the first and the third radiators comprise quarter-wavelength planar inverted-L antennas (PILA), while the second radiator comprises a half-wavelength grounded loop-type antenna disposed in between the first and the third radiators. The PILA radiators are characterized by radiation patterns having maximum radiation axes that are substantially perpendicular to the antenna plane. The loop radiator is characterized by radiation pattern having axis of maximum radiation that is parallel to the antenna plane. The above configuration of radiating patterns advantageously isolates the first radiator structure from the third radiator structure in at least one frequency band. | 04-11-2013 |
20140015719 | SWITCHED ANTENNA APPARATUS AND METHODS - Dynamically switchable antenna apparatus and associated methods. In one embodiment, a switching antenna configuration is used within a portable device (e.g. mobile phone). The switching antenna comprises at least one antenna element which operates at one or more resonant frequencies, and one or more switching elements. In one implementation, the switching elements are autonomously controlled to correct for detuning effects experienced by the antenna (e.g., body tissue loading) by modifying the electrical length of the antenna radiator(s) and/or correcting antenna impedance mismatch. In another implementation, the switching elements are controlled to effectuate band switching of the antenna. | 01-16-2014 |
20140125535 | CAPACITIVELY COUPLED ANTENNA APPARATUS AND METHODS - Capacitively coupled antenna apparatus and methods of operating and adaptively tuning the same. In one embodiment, the insertion loss component in “beside the hand/head” use scenarios is significantly reduced or eliminated such that the antenna experiences only absorptive losses (which generally cannot be avoided), and a very small insertion loss by the host device radio frequency tuner. The exemplary antenna apparatus may be configured for multi-band operation, and also has a very small form factor (e.g., 3 mm ground clearance only at the bottom of the PCB, 4 mm height in one implementation), thereby allowing for use in spatially compact host devices such as slim-line smartphones, tablets, and the like. The adaptive antenna arrangement (using capacitive feed) can be tuned such that the tuner is used in free space, and the user's hand/head tunes the antenna to the band of interest while in use. | 05-08-2014 |
20140253393 | COUPLED ANTENNA STRUCTURE AND METHODS - Antenna apparatus and methods of use and tuning. In one exemplary embodiment, the solution of the present disclosure is particularly adapted for small form-factor, metal-encased applications that utilize satellite wireless links (e.g., GPS), and uses an electromagnetic (e.g., capacitive) feeding method that includes one or more separate feed elements that are not galvanically connected to a radiating element of the antenna. In addition, certain implementations of the antenna apparatus offer the capability to carry more than one operating band for the antenna. | 09-11-2014 |
20140253394 | COUPLED ANTENNA STRUCTURE AND METHODS - Antenna apparatus and methods of use and tuning. In one exemplary embodiment, the solution of the present disclosure is particularly adapted for small form-factor, metal-encased applications that utilize satellite wireless links (e.g., GPS), and uses an electromagnetic (e.g., capacitive) feeding method that includes one or more separate feed elements that are not galvanically connected to a radiator element of the antenna. In addition, certain implementations of the antenna apparatus offer the capability to carry more than one operating band for the antenna. | 09-11-2014 |
20150138021 | CAPACITIVE GROUNDING METHODS AND APPARATUS FOR MOBILE DEVICES - Grounding apparatus for mobile devices and methods of utilizing and manufacturing the same. In one embodiment, an outer metallized surface of a mobile device is configured to capacitively couple a metal back cover to the device ground. Specifically, in one implementation, an exterior surface of the mobile device is metalized and coupled to the device ground via galvanic contacts. The exterior metalized surface is configured to be capacitively coupled a metal back cover of a mobile device to the device ground when the back cover is installed on the mobile device. By capacitively coupling the back cover to the device ground via the exterior metalized surface, the need to otherwise ground the back cover through the use of galvanic contacts is obviated, thereby reducing the number of components needed. | 05-21-2015 |