Abstract: A quadrature clock generator that takes advantage of the inherently low delay of a shunt-series inductively peaked clock buffer to generate quadrature clocks with the high jitter performance using just one additional stage in Q path compared to I path. The generator includes a delay cell that uses shunt-series peaking and uses a resistive DAC in series with the shunt inductor to provide a large delay range with good jitter characteristics. The resistive DAC can be placed near a real or a virtual ground to minimize capacitive loading on the signal path. This delay cell can provide greater than 2× delay tuning range and is suitable for clocks at high frequencies. This delay cell can also be used as a ring oscillator with large frequency tuning range. A low voltage differential signaling termination switch control that uses feed forward mechanism to control termination impedance of device in a receiver.

Abstract: An apparatus enables a high-bandwidth 4-way data serializing (4:1 serializer) digital-to-analog converter. The apparatus uses active inductor-based bandwidth extension technique for two-stage driver enabling design of quarter-rate 4-way data serializing transmitter. The 4:1 serializer output bandwidth is extended by gate-resistor-peaked n-type transistor load working as an active inductor. A current steering switch with current source is used as the final driver. The 4:1 serializer includes a pulse width tuning technique with tunable ground voltage on the ground terminal of a pulse generator to tune an effective threshold voltage of the pulse generator. A Bessel-like LC filter is coupled to an output of the 4:1 serializer. The filter includes shunt peaking paths that provide zeros, which natively cancel large parasitic capacitance at a shunt peaking node. As such, active and passive devices including driver circuitry, ESD diodes, and any other sensing circuitry are flexibly added on any LC filter nodes.

Abstract: A quadrature clock generator that takes advantage of the inherently low delay of a shunt-series inductively peaked clock buffer to generate quadrature clocks with the high jitter performance using just one additional stage in Q path compared to I path. The generator includes a delay cell that uses shunt-series peaking and uses a resistive DAC in series with the shunt inductor to provide a large delay range with good jitter characteristics. The resistive DAC can be placed near a real or a virtual ground to minimize capacitive loading on the signal path. This delay cell can provide greater than 2× delay tuning range and is suitable for clocks at high frequencies. This delay cell can also be used as a ring oscillator with large frequency tuning range. A low voltage differential signaling termination switch control that uses feed forward mechanism to control termination impedance of device in a receiver.

Abstract: A clock buffer that uses low-to-medium quality factor (e.g., QF of 2 to 5) inductors in shunt-series and in series-shunt configuration in high-speed clock distribution stages. Shunt-series and series-shunt inductors extend amplifier bandwidth. Applying shunt-series and series-shunt inductors to high-speed clock distribution filters jitter, attenuates supply noise, and improves fanout. An asymmetric multiplexer with inductors in shunt or in shunt-series configurations. Another asymmetric multiplexer with capacitively coupled tri-stateable inverter-based buffer stages. These two multiplexer techniques along with the ability to ‘hide’ a load of a non-preferred path at a virtual ground node of the shunt inductor, the multiplexer improves the jitter and power consumption of the preferred path significantly. A de-multiplexer (DeMux) is also shown using inductors. A combination of a shunt-multiplexer and an inductor-based DeMux is also discussed.

Abstract: An apparatus enables a high-bandwidth 4-way data serializing (4:1 serializer) digital-to-analog converter. The apparatus uses active inductor-based bandwidth extension technique for two-stage driver enabling design of quarter-rate 4-way data serializing transmitter. The 4:1 serializer output bandwidth is extended by gate-resistor-peaked n-type transistor load working as an active inductor. A current steering switch with current source is used as the final driver. The 4:1 serializer includes a pulse width tuning technique with tunable ground voltage on the ground terminal of a pulse generator to tune an effective threshold voltage of the pulse generator. A Bessel-like LC filter is coupled to an output of the 4:1 serializer. The filter includes shunt peaking paths that provide zeros, which natively cancel large parasitic capacitance at a shunt peaking node. As such, active and passive devices including driver circuitry, ESD diodes, and any other sensing circuitry are flexibly added on any LC filter nodes.

Abstract: A method for providing safe-driving support of a vehicle includes obtaining occupant data and vehicle data received at a vehicle hub. The occupant data is related to an identity and health status of an occupant and the vehicle data is related to a status of the vehicle. The method also includes obtaining action data based on an application of the occupant data and vehicle data to a machine learning safe-driving model. The machine learning safe-driving model is associated with a user profile of the occupant that is identified from among a plurality of user profiles based on the occupant data. A server maintains a plurality of user profiles, each having a respective machine learning safe-driving model. The action data relates to an action to be performed by the vehicle while the occupant is located in the vehicle.

Abstract: A method for securing Bluetooth communications. The method includes receiving, by a target wireless device, a security level indication from a source wireless device using one or more receiver antennas of the target wireless device. The method also includes determining, by the target wireless device, a jammer signal power level based on the security level indication and generating, by the target wireless device, the jammer signal based on the jammer signal power level. The method also includes transmitting, by the target wireless device, the jammer signal using one or more transmitter antennas of the target wireless device and receiving at least a portion of a communication from the source wireless device using the one or more receiver antennas of the target wireless device.

Abstract: A method for providing safe-driving support of a vehicle includes obtaining occupant data and vehicle data received at a vehicle hub. The occupant data is related to an identity and health status of an occupant and the vehicle data is related to a status of the vehicle. The method also includes obtaining action data based on an application of the occupant data and vehicle data to a machine learning safe-driving model. The machine learning safe-driving model is associated with a user profile of the occupant that is identified from among a plurality of user profiles based on the occupant data. A server maintains a plurality of user profiles, each having a respective machine learning safe-driving model. The action data relates to an action to be performed by the vehicle while the occupant is located in the vehicle.

Abstract: A method for Bluetooth packet acquisition is described. The method includes performing preamble detection on a received signal using a first set of cross-correlation results. The method also includes delaying packet detection by a delay window when a preamble is detected. The method further includes detecting the Bluetooth packet based on a maximum cross-correlation result of the received signal within a packet search window of a second set of cross-correlation results.

Abstract: A method is described. The method includes receiving an event monitoring model generated by a machine learning engine. The event monitoring model is configured to classify network device behavior based on observed events. The method also includes monitoring events in a network based on the event monitoring model. Machine learning features are extracted from network traffic generated by one or more network devices. The method further includes determining a network device classification of the monitored events based on the event monitoring model. The method additionally includes sending the observed events and the network device classification to the machine learning engine to update the event monitoring model.

Abstract: The present invention relates generally to wireless networking, and more particularly to methods and apparatuses for increasing throughput of wireless devices and systems in a wireless network. The invention includes transmitting one or more signaling frames from one wireless device in the wireless network to other wireless devices (STAs) in the wireless network. The one or more signaling frames contain information concerning channel allocation for the transmission and requirement for the acknowledgement frames between the transmitting wireless device and the receiving wireless devices. This invention allows wireless devices not allocated the transmission medium to sleep during a transmission burst and different wireless devices allocated the transmission medium to be scheduled in different data transmission bursts.