Abstract: A system includes a transceiver configured to receive frequency dependent channel estimates or beamforming feedback in a multi-carrier, multi-antenna communication system, and a multi-layer perceptron feed forward neural network component, coupled with the transceiver, configured to estimate parameters of multipath reflections using representations of the channel estimates or beamforming feedback, and to generate transmission correction factors for the transceiver.

Abstract: A method can include, by operation of first communication circuits, determining a quality of a plurality of communication frequencies according to wireless communications of a first protocol type; recording a quality of the communication frequencies; selecting communication frequencies for use by second communication circuits based on the quality of the communication frequencies; and wirelessly transmitting and receiving data with the second communication circuits according to a second protocol different than the first protocol; wherein the first and second communication circuits are collocated on the same device. Related devices and systems are also disclosed.

Abstract: Techniques for low-power USB Type-C receivers with high noise rejection are described herein. In an example embodiment, a USB-enabled device comprises a receiver circuit coupled to a Configuration Channel (CC) line of a USB Type-C subsystem. The receiver circuit is configured to reject the incoming signal even when the incoming signal includes noise with a magnitude of more than 300 mVpp, and to operate in the presence of a VBUS charging current that is compliant with a USB-PD specification.

Abstract: A system and method are provided for extending range of devices in a legacy wireless network. Generally, the method involves providing in a transmitter of the system a frame having a first field including a number of preamble segments and a second field including a number of data segments. The transmitter in the system is then operated to transmit at least one of the preamble segments with at least a first transmit power, and to transmit the segments of the second field at a second transmit power, wherein the first transmit power is greater than the second transmit power. Other embodiments are also described.

Abstract: Example systems and methods transfer data between a first device and a second device. Embodiments generate, using an output circuit, an analog signal based on a data signal for an application associated with the first device and the second device. Embodiments transmit the data signal over an interface between a processor of the first device and a processor of the second device by capacitively coupling the analog signal through a capacitor formed by at least one sensor electrode, of a touchscreen, of the first device and a conductor of the second device.

Abstract: Devices, systems and methods generate a packet including a first preamble and a narrow band packet. Embodiments assign a first frequency band to the first preamble and assign a second frequency band to the narrow band packet. The second frequency band is a first sub-band of the first frequency band. Embodiments transmit the packet by transmitting the first preamble across the first frequency band and transmitting the narrow band packet across the second frequency band. The narrow band packet includes a second preamble and narrow band packet data.

Abstract: An AC-DC converter with synchronous rectifier (SR) architecture and method for operating the same are described. Generally, a secondary side integrated circuit (IC) controller of the AC-DC converter includes a SR-SNS pin, a VBUS_IN pin, a first voltage-to-current converter, a sample-and-hold (S/H) circuit, a second voltage-to-current converter, and a signal generation circuit. The first voltage-to-current converter is coupled to remove a component of the output bus voltage sensed on the VBUS_IN pin from the voltage sensed on the SR-SNS pin. The S/H circuit is coupled to sample the voltage sensed on the SR-SNS pin and to provide a sampled voltage. The second voltage-to-current converter is coupled to convert the sampled voltage to a feed-forward current. The signal generation circuit is coupled to receive the feed-forward current and to generate feed-forward signals used to control operation of a primary side of the AC-DC converter.

Abstract: An AC-DC converter with synchronous rectifier (SR) architecture and method for operating the same are described. Generally, a secondary side IC controller of the AC-DC converter includes a SR-SNS pin coupled to a peak-detector block, a zero-crossing block, and a calibration block. The calibration block is configured to: measure a loop turn-around delay (Tloop), a time (Tpkpk) between two successive peak voltages detected on the SR-SNS pin, and a time (Tzpk) from when the voltage sensed on the SR-SNS pin crosses zero voltage to when a peak voltage is detected on the SR-SNS pin; and set timing for a signal to turn on a power switch in a primary side of the AC-DC converter based at least on Tloop, Tpkpk, and Tzpk.

Abstract: An AC-DC converter with secondary side control and synchronous rectifier (SR) architecture and method for operating the same are provided for reducing the cost, complexity and size of the converter while improving efficiency. In an example embodiment, an integrated circuit (IC) controller for the secondary side of the AC-DC converter comprises a zero-crossing detector (ZCD) block and a negative-sensing (NSN) block coupled to a terminal. The terminal is configured to receive an input signal from a drain node of a SR circuit on the secondary side of the AC-DC converter. The ZCD block is configured to determine when a voltage of the input signal reaches 0V. The NSN block is configured to determine a negative voltage of the input signal. An internal rectifier, coupled between the terminal and local ground, is configured to ensure that substantially no current flows through the terminal during operation of the ZCD block and the NSN block.

Abstract: An AC-DC converter with synchronous rectifier (SR) architecture and method for operating the same are described. Generally, a secondary side integrated circuit (IC controller of the AC-DC converter includes a peak-detector block coupled to detect peak voltages sensed on a SR-SNS pin. The peak-detector block comprises a peak comparator, a sample-and-hold (S/H) circuit, and a DC offset circuit. The peak comparator is coupled to receive a sinusoidal input from the SR-SNS pin. The S/H circuit is coupled to sample the sinusoidal input and to provide a peak sampled voltage. The DC offset voltage circuit is coupled between the output of the S/H circuit and a reference voltage input of the peak comparator to subtract a DC offset voltage from the peak sampled voltage.

Abstract: Communicating information stored at a secondary controller to a primary controller in a secondary-controlled flyback converter is described. In one embodiment, a method includes storing, by a secondary-side controller of a power converter, calibration information associated with a primary-side controller of the power converter. The power converter is a secondary-controlled alternating current to direct current (AC-DC) flyback converter comprising a galvanic isolation barrier. The method further includes sending, by the secondary-side controller, the calibration information to the primary-side controller across the galvanic isolation barrier in response to power-up of the power converter.

Abstract: Devices, systems and methods use a first communication interface to connect with a local device via a first protocol and use a second communication interface to connect with a server via a second protocol. Embodiments relay secure communications between the local device and the server for authentication of the at least one local device by the server and responsive to authentication of the local device by the server, transmit information for storage in a secure memory of the authenticated local device.

Abstract: In an example embodiment, a Universal Serial Bus (USB) Type-C cable comprises a USB Type-C connector and an IC controller coupled thereto. The IC controller comprises a terminal coupled to a VCONN line of the USB Type-C cable, a transistor coupled between the terminal and an internal power supply of the IC controller, a resistive element coupled between the terminal and a control terminal of the transistor, and control logic. The IC controller is to: power on the transistor from a voltage, received at the terminal, falling across the resistive element power on the internal power supply in response to the voltage being passed through the transistor; power up the IC controller in response to powering on the internal power supply; and operate the control logic to fully power on the transistor, and thus enter an active mode of the IC controller.

Abstract: Communicating information stored at a secondary controller to a primary controller in a secondary-controlled flyback converter is described. In one embodiment, a method includes storing, by a secondary-side controller of a power converter, calibration information associated with a primary-side controller of the power converter. The power converter is a secondary-controlled alternating current to direct current (AC-DC) flyback converter comprising a galvanic isolation barrier. The method further includes sending, by the secondary-side controller, the calibration information to the primary-side controller across the galvanic isolation barrier in response to power-up of the power converter.

Abstract: A touch detection system in accordance with one embodiment of the invention can include a circuit for converting a capacitance to a digital value. The touch detection system can include first and second communication interface circuits for enabling a first and second communication protocols, respectively. Furthermore, the touch detection system can include a detector circuit coupled to the first communication interface circuit and the second communication interface circuit. The detector circuit can be for automatically detecting a factor that indicates automatically enabling the first communication interface circuit and automatically disabling the second communication interface circuit. The detector circuit can be for detecting a coupling of a pin of the first communication interface circuit that is not used by the second communication interface circuit.

Abstract: Communicating fault indications between primary and secondary controller in a secondary-controlled flyback converter is described. In one embodiment, an apparatus includes a primary-side field effect transistor (FET) coupled to a flyback transformer coupled to the primary-side FET, and a primary-side controller coupled to the flyback transformer. The primary-side controller is configured to receive a signal from a secondary-side controller across a galvanic isolation barrier, apply a pulse signal to the primary-side FET in response to the signal to turn-on and turn-off the primary-side FET, communicate information to the secondary-side controller across the flyback transformer by varying a first pulse width of the pulse signal to a second pulse width and applying the pulse signal with the second pulse width to the primary-side FET.

Abstract: A processing device scans a capacitive sense array to determine a characteristic of a noise signal. A processing device further detects a location of a touch proximate to the capacitive sense array by a passive touch object using a first mode of capacitance touch detection. The first mode of capacitive touch detection uses a capacitive coupling of the noise signal to the capacitive sense array through the passive touch object to detect the touch.

Abstract: A method, apparatus, and system for provisioning a device onto a network using a non-secure communication channel between the device and a provisioner is described. The provisioner receives a timestamp-based on-time password (TOTP), and a universal resource identifier (URI) from the device and provides the TOTP and an out-of-band (OOB) UUID to a remote server over a secure communication channel identified by the URI. The device is then provisioned onto a network based on comparisons of the UUID and the TOTP.

Abstract: An electronic device includes a first switch configured to connect a VCONN supply terminal of a Universal Serial Bus Type-C (USB-C) controller to a first configuration channel (CC) terminal of the USB-C controller in response to a USB-C connector being in a first orientation. A first current may flow through the first switch. The electronic device also includes an overcurrent component coupled to the first switch. The overcurrent component includes a second switch associated with the first switch. The second switch has a second current associated with the first current. The overcurrent component is configured to determine whether the first current is greater than a threshold current based on the first current and the second current. The overcurrent component is also configured to close the first switch in response to determining that the first current is greater than the threshold current.

Abstract: Devices, systems and methods track geographical locations of a wireless device and time associated with the wireless device. Embodiments access channel map data including a predicted channel condition value for each of multiple communication channels within each of a plurality of geographical locations during a plurality of time periods of day. Embodiments use the channel map data to select one of the multiple communication channels for communication in a second geographical location, based on a first geographical location of the wireless device and a time of day associated with the wireless device.