Abstract: Embodiments described herein provide a method for fragmenting and reassembling data frames on a medium access control (MAC) layer in a wireless local area network. A datagram is received from an application running on a first network device, for transmission over a wireless communication link in the wireless local area network. A negotiation request is initiated with a second network device for determining whether both the first network device and the second network device have enhanced directional multi-gigabit capability (EDMG) for data segmentation and reassembly. When both devices have EDMG capability and the size of the datagram exceeds the maximum size defined by the wireless local area network transmission protocol, the datagram is segmented into a plurality of transmission data units on the MAC layer.

Abstract: An audio processing circuit is described. The audio processing circuit includes at least one input configured to receive a primary audio signal and a feature generation signal. A feature model estimation circuit is configured to model and output a feature model signal of the primary audio signal. A feature generation circuit is coupled to the feature model estimation circuit and is to receive the feature model signal and the feature generation signal and, in response to the feature model signal, modify the feature generation signal; and output a modified representation of the feature generation signal that is more similar to the primary audio signal.

Abstract: Embodiments of a method and a device are disclosed. A method for performing operations in a communications network is disclosed. The method involves, determining, at a first network node in a communications network, that a DSP of a receiver of a network node in the communications network can operate at a reduced functionality level, and communicating the determination from the first network node to a second network node in the communications network in a protocol data unit (PDU), wherein the DSP of a receiver of a network node that can operate at a reduced functionality level is a DSP of a receiver of one of the first network node and the second network node.

Abstract: A method and apparatus are provided. The apparatus comprises an input for receiving a plurality of data streams carrying misaligned common content. The apparatus further comprises a plurality of buffers configured to delay one or more of the data streams to align the common content, each buffer for storing data blocks of a respective one of the plurality of data streams. The apparatus comprises an output for selecting a data block from the plurality of buffers to form a next data block in an output packet stream comprising the common content. Each data block is stored in a respective buffer along with quality information corresponding to said data block and selecting a data block from the plurality of buffers is carried out in dependence on the quality information.

Abstract: A semiconductor switch device for switching an RF signal and a method of making the same. The device includes a first semiconductor region having a first conductivity type. The device also includes a source region and a drain region located in the first semiconductor region. The source region and the drain region have a second conductivity type. The second conductivity type is different to the first conductivity type. The device further includes a gate separating the source region from the drain region. The device also includes at least one sinker region having the second conductivity type. Each sinker region is connectable to an external potential for drawing minority carriers away from the source and drain regions to reduce a leakage current at junctions between the source and drain regions and the first semiconductor region.

Abstract: Methods of securing a cryptographic device against implementation attacks are described. A disclosed method comprises the steps of: generating secret values (324) using a pseudorandom generator (510); providing a key (330), an input (324) having a number of chunks and the secret values to an encryption module (340); indexing the chunks and the secret values (324); processing the input chunk wise by encrypting the secret values (324) indexed by the chunks using the key (330) and the encryption module (340); generating for each chunk a pseudorandom output (330?) of the encryption module (340), providing the pseudorandom output as the key (330?) when processing the next chunk; and performing a final transformation on the last pseudorandom output (330?) from the previous step by using it as a key to encrypt a fixed plaintext.

Abstract: A signal processor and method of signal processing to reduce delays in channel estimation is described. In the method, the following operations are performed: receiving a signal at a signal processor (200); estimating a first channel from the received signal with a one-dimensional, 1D, frequency filter (304) in a frequency domain to generate an interim output; decoding said interim output (406) to generate decoded interim output; estimating (414,418) at least a second channel from the decoded interim output with a two-dimensional, 2D, filter (100) to produce a final output (420).

Abstract: An apparatus comprising an authentication processor configured to, based on received firmware and predetermined cryptographic authentication information, provide for cryptographic based authentication of the received firmware to control execution of the received firmware by any one of a plurality of processors. Each processor of the plurality of processors is uniquely addressable by a boot sequencer.

Abstract: A circuit comprising: an input terminal configured to receive an input-signal; an output terminal configured to provide an output-signal; a reference circuit comprising: a first output terminal configured to provide a first-reference-signal; a second output terminal configured to provide a second-reference-signal; and a third output terminal configured to provide a third-reference-signal. A comparator-block configured to compare a comparator-input-voltage-signal representative of signalling received at the input terminal with: (i) the first-reference-signal, (ii) the second-reference-signal and (iii) the third-reference-signal in order to generate a comparison-signal. A control-block configured to set the output-signal as one of at least two voltage levels based on the comparison-signal; and an input-control-circuit configured to apply a feedback-control-signal to the input-terminal based on the comparison-signal.

Abstract: An embodiment of a Doherty amplifier module includes a substrate, an RF signal splitter, a carrier amplifier die, and a peaking amplifier die. The RF signal splitter divides an input RF signal into first and second input RF signals, and conveys the first and second input RF signals to first and second splitter output terminals. The carrier amplifier die includes one or more first power transistors configured to amplify, along a carrier signal path, the first input RF signal to produce an amplified first RF signal. The peaking amplifier die includes one or more second power transistors configured to amplify, along a peaking signal path, the second input RF signal to produce an amplified second RF signal. The carrier and peaking amplifier die are coupled to the substrate so that the RF signal paths through the carrier and peaking amplifier die extend in substantially different (e.g., orthogonal) directions.

Abstract: An apparatus is provided comprising a first integrated circuit. The first integrated circuit comprises a first element comprising one of a transmit or receive element, an oscillator for providing a first local oscillator signal, a local oscillator output configured to output the first local oscillator signal when activated, a local oscillator input configured to receive a master local oscillator signal when activated; and first switching circuitry for selectively coupling the first element to one of the oscillator and the local oscillator input.

Abstract: Embodiments are directed to apparatuses and methods involving communication between a first circuit and a second circuit over a wired-data bus. An example apparatus includes an integrated circuit (IC) chip within one of the first and second circuits and a logic circuit. The IC has a first data-communication port and a second data-communication for connection to respective first and second conductors of the wired-data bus. The logic circuit communicates a code multi-bit word out of a set of code multi-bit words over the wired-data bus by using signal transitions communicated on the first and second conductors. The code multi-bit word conveys clocked data bits indicated by the signal transitions, and information unique relative to other ones of the set of code multi-bit words by a known sequential pattern of the signal transitions defined relative to timing associated with the clocked data bits.

Abstract: A bi-directional level translator with fast rise and fall times and low current leakage is suitable for use with devices connected using a SPMI bus. The level translator passes signals between first and second voltage domains that operate at different voltage levels. The level translator has a first terminal that receives a first signal A from the first voltage domain and outputs a second signal B to the second voltage domain. A second terminal receives the second signal B and outputs the first signal A. A first switch is located between the first voltage source and the first terminal and a second switch is located between the second voltage source and the second terminal. The first and second switches are operable to reduce current leakage of the level translator.

Abstract: Embodiments of methods and systems for operating a communications device are described. In one embodiment, a method for operating a communications device that communicates via inductive coupling involves adjusting a phase configuration of the communications device in response to at least one system or environmental parameter, modulating a carrier signal with the adjusted phase configuration using active load modulation (ALM), and transmitting the modulated carrier signal from the communications device for inductive coupling. In some embodiments, the at least one system or environmental parameter is selected from one or more of the following: a distance information, a geometric information, a system code, a technology code, a transmitter current and/or a transmitter power, a detuning condition, a quality factor and a resonant frequency of a resonant system.

Abstract: A method for mapping an input message to a message authentication code (MAC) by a white-box implementation of a keyed cryptographic operation in a cryptographic system that includes using a white-box implementation of the block cipher in a MAC.

Abstract: Embodiments of a method and a device are disclosed. In an embodiment, a method for operating a Controller Area Network (CAN) transceiver involves detecting phase information related to a CAN data frame that is transmitted by the CAN transceiver and in response to the phase information, switching between different transmitter configurations of the CAN transceiver within a bit interval for use in transmitting subsequent bits of the CAN data frame.

Abstract: Systems for providing isolation of a bias signal relative to a radio frequency (RF) signal in an integrated circuit, and related circuits, modules, and methods, are disclosed herein. In one example embodiment, a system includes an inductor, a bypass capacitor, and a transmission line segment, which includes first and second ends and extends between the first and second ends. The first end is at least indirectly coupled to the bypass capacitor, the second end is at least indirectly coupled to a first additional end of the inductor, and a second additional end of the inductor is configured to be coupled at least indirectly to a device through which the RF signal is being communicated. The transmission line segment is configured to impart a non-negligible phase shift to a signal communicated between the first and second ends, or is configured to have a non-negligible effective inductance.

Abstract: A system includes first and second modules, each having a sensor and a processing circuit. First and second fault detection circuits are coupled with respective first and second modules. Each of the first and second fault detection circuits determines from a processed signal output from a corresponding module whether the module is faulted, prevents output of the processed signal when the module is faulted, and enables output of the processed signal when the module is not faulted. A signal processing unit combines the processed signals from the first and second modules to produce a first output signal when neither of the first and second modules is faulted, and the signal processing unit produces a second output signal by utilizing only the processed signal from a non-faulted one of the first and second modules when the other of the first and second modules is faulted.

Abstract: In a wireless communication system, ranging is performed between an initiator and one of a plurality of responders. Before the ranging operation is performed, the initiator preselects the responder, wherein the preselection is based on a comparison of a measured metric associated with signals carrying packets received from the responders by the initiator. The initiator utilizes only a portion of the preamble in each of the packets to measure the metric. The signals are transmitted in the wireless communication system utilizing ultra-wideband frequencies.

Abstract: In a method for communicating in a wireless communication network a trigger frame is generated to trigger simultaneous uplink transmissions by multiple communication devices. The trigger frame includes a padding portion having a length determined based on respective time duration requirements of the multiple communication devices, the respective time duration requirements for preparing uplink transmission by the corresponding second communication devices. The trigger frame is transmitted to the multiple communication devices. The simultaneous uplink transmissions, triggered by the trigger frame, are received from the multiple communication devices.