Abstract: A system, in a first radio frequency (RF) device, dynamically selects a plurality of reflector devices along a non-line-of-sight (NLOS) radio path based on a first set of criteria. The plurality of reflector devices comprises at least an active reflector device and a passive reflector device. The first RF device further controls the dynamically selected plurality of reflector devices based on a second set of criteria. A plurality of RF signals transmitted by the controlled plurality of reflector devices is received at a second RF device. A first type of signal associated with the received plurality of RF signals is converted to a second type of signal. Transmission of the second type of signal to one or more electronic devices associated with the second RF device is controlled based on one or more device characteristics of the one or more electronic devices or the second RF device.

Abstract: A full duplex transceiver includes a phased array antenna panel transmitter and a phased array antenna panel receiver. The full duplex transceiver may include at least one dummy antenna row situated between the phased array antenna panel transmitter and the phased array antenna panel receiver, the at least one dummy antenna row having at least one dummy antenna connected to a terminating resistor. The phased array antenna panel transmitter forms a desired radio frequency (RF) transmit beam at a target angle, and forms a null at an angle so as to minimize reception of offending transmit signals at said phased array antenna panel receiver. The phased array antenna panel receiver may receive offending transmit signals from the phased array antenna panel transmitter and a desired receive signal at a combined input power level.

Abstract: A phased array antenna panel includes an array of antenna cells. Optionally, the phased array antenna panel includes a frame with multiple shielding fences housing the array of antenna cells. Each antenna cell includes a raised antenna patch with air dielectric. In one example, the raised antenna patch may include four projections having outwardly increasing widths, and four supporting legs, each of the four supporting legs situated between a pair of adjacent projections. A first differential feed port may be coupled to first and second supporting legs of the raised antenna patch through first and second transformers, and a second differential feed port may be coupled to third and fourth supporting legs of the raised antenna patch through third and fourth transformers. A return loss in a frequency range of between 27.5 GHz and 29.5 GHz of each antenna cell is less than about ?10 dB.

Abstract: A system and apparatus is provided to reduce signal routing, area and signal loss in double-pole, double-throw (DPDT) switch implementations in wireless and millimeter-wave front ends. A cyclic staggered arrangement of receivers, transmitters and antenna ports connecting with DPDT switches reduce signal cross-over and allow for compact, low-loss multi-antenna configurations.

Abstract: A stacked synthesizer for wide local oscillator (LO) generation using a dynamic divider. The phase locked loop can include a plurality of voltage controlled oscillators (VCOs), and a selector that can be configured to select an output of one of the plurality of VCOs. The selected output of one of the plurality of VCOs can be provided to an on-chip dynamic divider and to an off-chip dynamic divider for LO sharing. The dynamic dividers can be configured to generate synthesizer outputs based on a multiplication of the selected output of one of the plurality of VCOs by a factor (1+1/M), where M is a variable number.

Abstract: An electronic device includes circuitry configured to determine an antenna operation mode for one or more antenna arrays. The circuitry is further configured to control the one or more antenna arrays to operate in a combined antenna mode via a Wilkinson combiner. The circuitry is also configured to control the one or more antenna arrays to operate in an isolated antenna mode via a single-pole, multi-throw switch.

Abstract: A wireless receiver includes a plurality of RF front end chips that receive phase shift signals or amplitude control signals, and output V-combined and H-combined signals. The wireless receiver also includes groups of antennas surrounding each of the plurality of RF front end chips. Each of the plurality of RF front end chips can be surrounded by a group of four antennas in an H-configuration, a group of six antennas in a rectangular- or a hexagonal-configuration, or a group of eight antennas in a rectangular- or an octagonal-configuration. Each of the group of four, six or eight antennas is coupled to a corresponding RF front end chip through antenna feed lines having substantially equal lengths. In another implementation, a pair of RF front end chips uses differential signals to communicate with at least two antennas of a group of antennas surrounding the pair of RF front end chips.

Abstract: A stacked synthesizer for wide local oscillator (LO) generation using a dynamic divider. The phase locked loop can include a plurality of voltage controlled oscillators (VCOs), and a selector that can be configured to select an output of one of the plurality of VCOs. The selected output of one of the plurality of VCOs can be provided to an on-chip dynamic divider and to an off-chip dynamic divider for LO sharing. The dynamic dividers can be configured to generate synthesizer outputs based on a multiplication of the selected output of one of the plurality of VCOs by a factor (1+1/M), where M is a variable number.

Abstract: Disclosed are a method of modeling a haptic signal from a haptic object, a display apparatus, and a driving method thereof, which realize a tactile sense having a shape and texture of a haptic object. The method includes obtaining measurement data corresponding to a shape of a texture object while moving a sensor unit with respect to a haptic object including the texture object, obtaining force measurement data corresponding to a level of pressure applied to the haptic object, calculating shape modeling data and impulse modeling data corresponding to the texture object, based on the measurement data, calculating friction force modeling data corresponding to the texture object, based on the force measurement data, generating setting information of a haptic signal corresponding to the haptic object, based on the shape modeling data, the impulse modeling data, and the friction force modeling data, and storing the setting information of the haptic signal.

Abstract: A system and apparatus is provided to reduce signal routing, area and signal loss in double-pole, double-throw (DPDT) switch implementations in wireless and millimeter-wave front ends. A staggered arrangement of receivers, transmitters and antenna ports connecting with DPDT switches reduce signal cross-over and allow for compact, low-loss multi-antenna configurations.

Abstract: A phased array antenna panel includes a first plurality of antennas, a first radio frequency (RF) front end chip, a second plurality of antennas, a second RF front end chip, and a combiner RF chip. The first and second RF front end chips receive respective first and second input signals from the first and second pluralities of antennas, and produce respective first and second output signals based on the respective first and second input signals. The combiner RF chip can receive the first and second output signals and produce a power combined output signal that is a combination of powers of the first and second output signals. Alternatively, a power combiner can receive the first and second output signals and produce a power combined output signal, and the combiner RF chip can receive the power combined output signal.

Abstract: A phased array antenna panel includes a central radio frequency (RF) front end chip, neighboring RF front end chips, and an antenna. The antenna has a proximal probe and a distal probe. The proximal probe has one end at a near corner of the antenna adjacent to the central RF front end chip, and reduces an insertion loss in signals processed by the central RF front end chip. The distal probe has one end at a far corner of the antenna adjacent to one of the neighboring RF front end chips, and increases the isolation between signals processed by the central RF front end chip and signals processed by the one of the neighboring RF front end chips.

Abstract: A wireless receiver includes an antenna receiving a right-handed circularly polarized (RHCP) signal and a left-handed circularly polarized (LHCP) signal, a first amplifier and a second amplifier coupled to the antenna, an intermediate summer coupled to the first and second amplifiers and providing a first intermediate signal, an intermediate subtractor coupled to the first and second amplifiers and providing a second intermediate signal. The wireless receiver also includes a V-signal summer providing a V-component output based on a sum of the first intermediate signal and the second intermediate signal, and an H-signal subtractor providing an H-component output based on a difference between the first intermediate signal and the second intermediate signal. The wireless receiver is configured to provide the V-component output and the H-component output without using a phase shifter.

Abstract: A wireless receiver is disclosed. The wireless receiver includes a phased array antenna panel having a plurality of antennas, and a low resolution analog-to-digital (A/D) converter coupled to each of the plurality of antennas, where the low resolution A/D converter is configured to provide a digital output based on comparing a reference value with a sum of noise value and signal value of an analog input received by the corresponding one of the plurality of antennas. Noise signals received by the plurality of antennas are uncorrelated, and a signal to noise ratio (SNR) of the analog input can be less than one. The low resolution A/D converter can be a one-bit A/D converter. The one-bit A/D converter can be a comparator receiving the sum of noise value and signal value as one comparator input, and receiving the reference value as another comparator input.

Abstract: A broadband antenna element for wireless communications includes one or more radiator layers to receive an electrical signal and to transmit a polarized electromagnetic (EM) wave. A feed layer including a feeding mechanism feeds the electrical signal generated by a transmitter into the radiator layer. A ground layer is coupled to a ground potential of the transmitter. The one or more radiator layers, the feed layer, and the ground layer are conductor layers of a multilayer substrate that includes metal layers and dielectric layers. The antenna element transmits with a broad bandwidth centered at a frequency of about 60 GHz, and maintains the broad bandwidth and polarization purity for scan angles up to a predefined value.

Abstract: A phased array antenna panel includes a plurality of antennas and a master chip. The antennas are arranged in a plurality of antenna rows. At least one antenna row in the plurality of antenna rows is configured to be slanted in a desired angle based on signals received from the master chip. Additionally, the phased array antenna panel can include a plurality of row-shaped lenses. At least one row-shaped lens has a corresponding antenna row, and is configured to increase a gain of the corresponding antenna row. The row-shaped lens can increase a total gain of the phased array antenna panel. The row-shaped lens is configured to be slanted in a desired angle based on signals received from the master chip.

Abstract: A lens-enhanced phased array antenna panel includes a phased array antenna panel and at least one lens situated over the phased array antenna panel. The phased array antenna panel has a plurality of antennas arranged in a plurality of antenna segments. Each lens corresponds to at least one of the antenna segments. Each lens is configured to increase a gain of its corresponding antenna segment. Each lens increases a total gain of the phased array antenna panel. Additionally, each lens can provide an angular offset to direct a radio frequency (RF) beam onto its corresponding antenna segment.

Abstract: A wireless receiver includes an antenna receiving a right-handed circularly polarized (RHCP) signal and a left-handed circularly polarized (LHCP) signal, a first amplifier and a second amplifier coupled to the antenna, an intermediate summer coupled to the first and second amplifiers and providing a first intermediate signal, an intermediate subtractor coupled to the first and second amplifiers and providing a second intermediate signal. The wireless receiver also includes a V-signal summer providing a V-component output based on a sum of the first intermediate signal and the second intermediate signal, and an H-signal subtractor providing an H-component output based on a difference between the first intermediate signal and the second intermediate signal. The wireless receiver is configured to provide the V-component output and the H-component output without using a phase shifter.

Abstract: A radio frequency (RF) front end chip in a phased array antenna panel for transmitting a modulated circularly-polarized signal is disclosed. The RF front end chip includes an oscillator providing an angular speed modulation signal to a quadrature generation block, the quadrature generation block providing an in-phase signal and a quadrature signal based on the angular speed modulation signal, a first amplifier receiving the in-phase signal and a data signal, and providing a modulated horizontally-polarized signal, and a second amplifier receiving the quadrature signal and the data signal, and providing a modulated vertically-polarized signal, where a modulated circularly-polarized signal is generated based on the modulated horizontally-polarized signal and the modulated vertically-polarized signal. The angular speed modulation signal controls an angular speed of the modulated circularly-polarized signal. The data signal is encoded by the angular speed modulation signal.

Abstract: A phased array antenna panel includes an array of antenna cells. Optionally, the phased array antenna panel includes a frame with multiple shielding fences housing the array of antenna cells. Each antenna cell includes a raised antenna patch with air dielectric. In one example, the raised antenna patch may include four projections having outwardly increasing widths, and four supporting legs, each of the four supporting legs situated between a pair of adjacent projections. A first differential feed port may be coupled to first and second supporting legs of the raised antenna patch through first and second transformers, and a second differential feed port may be coupled to third and fourth supporting legs of the raised antenna patch through third and fourth transformers. A return loss in a frequency range of between 27.5 GHz and 29.5 GHz of each antenna cell is less than about ?10 dB.