Abstract: This disclosure describes systems, methods, and devices related to sensor data pipelining. A device may identify a first request of one or more requests received from a wireless universal serial bus (USB) host, wherein the first request is to collect data from a USB sensor. The device cause to send the first request to the USB sensor. The device identify a first response from the USB sensor, wherein the first response comprises data collected by the USB sensor based on the first request. The device determine that no additional requests are received from the wireless USB host. The device cause to send a second autonomous request to the USB sensor to collect data. The device identify a second response received from the USB sensor, wherein the second response is associated with the autonomous second request. The device cause to buffer or send the second response to the wireless USB host based on a second request being received from the wireless USB host.

Abstract: For example, an MA USB host of an MA USB PAL may be configured to process a request message from a USBDI of a USB host for a real time data transfer to be delivered between the USB host and a USB device EP; based on the request message, transmit at least one real time transfer request to an MA USB device of the MA USB PAL, a header of the real time transfer request including a request ID field to identify the real time data transfer, and a delivery time field to indicate a delivery time to complete delivery of the real time data transfer; and, based on a determination that the real time data transfer is not to be completed by the delivery time, send a response to the USBDI, the response including an error indication to indicate failure of the real time data transfer.

Abstract: A network profile grouping method for a communication device is described. In a network profile grouping method, wireless characteristics of a plurality of wireless access points (APs) are determined. Two or more APs of the plurality of APs are matched together based on the determined wireless characteristics. A group profile identification (ID) is assigned to the matched two or more APs to group the matched two or more APs together.

Abstract: A method for operating a media agnostic universal serial bus (MAUSB) device includes a compute device having a link connection manager, a USB manager, and a state manager. The compute device establishes a link with a MAUSB device and a session with the MAUSB device. Subsequently to receipt of a sleep command for the compute device, the compute device transitions to a sleep state and terminates the link with the MAUSB device while keeping intact the session with the MAUSB device. The compute device transitions back to an active state in response to receipt of a wake command for the compute device. The compute device sends a wake request to the MAUSB device. If the MAUSB device responds to the wake request with an acceptance, then the compute device reestablishes the previous session with the MAUSB device. If instead an error is received, the compute device terminates the session.

Abstract: In a communication device and communication method, channel quality information for first and the second communication protocols is calculated. Further, allocation information can be generated for the first and the second communication protocols based on the corresponding channel quality information. Sequence numbers of corresponding data frames to be transmitted by the communication device can be generated. Further, the data frames and corresponding sequence numbers can be allocated to the first and the second communication protocols based on the allocation information.

Abstract: This disclosure describes systems, methods, and computer-readable media related to cross indication of queue size in a reverse direction protocol. In some embodiments, a reverse direction (RD) grantor may transmit a frame to an RD responder. The RD responder may identify data to be transmitted to the RD grantor based on the received frame. The RD responder may generate a frame that may comprise a plurality of sub-frames. The RD responder may set a sub-field in each of the sub-frames indicating whether there is data to transmit. The RD responder may also set a second sub-field that may indicate a priority or traffic stream associated with the data to be transmitted. The RD responder may transmit the frame (and associated sub-frames) to the RD grantor.

Abstract: Technologies for improving enumeration of universal serial bus (USB) devices over a media agnostic USB (MAUSB) connection are disclosed. In the illustrative embodiment, an MAUSB device may send USB configuration data to a host compute device. The host compute device may then perform a virtual enumeration of the USB devices based on the USB configuration data without necessarily communicating with the USB devices. The MAUSB device may perform an enumeration of the USB devices on behalf of the host compute devices without necessarily communicating with the host compute device. The USB devices may not be aware or have any indication that the USB device is not communicating with the host compute device during the enumeration process. Such an approach may improve the latency of USB enumeration over an MAUSB connection.

Abstract: This disclosure describes systems, methods, and computer-readable media related to cross indication of queue size in a reverse direction protocol. In some embodiments, a reverse direction (RD) grantor may transmit a frame to an RD responder. The RD responder may identify data to be transmitted to the RD grantor based on the received frame. The RD responder may generate a frame that may comprise a plurality of sub-frames. The RD responder may set a sub-field in each of the sub-frames indicating whether there is data to transmit. The RD responder may also set a second sub-field that may indicate a priority or traffic stream associated with the data to be transmitted. The RD responder may transmit the frame (and associated sub-frames) to the RD grantor.

Abstract: Embodiments of methods for scanning in a directive multi-gigabit network are generally described herein. An apparatus of a station may include processing circuitry configured to decode a sector sweep beacon received from an access point, encode for transmission a sector sweep feedback message to include a beam refinement protocol (BRP) request, and encode for transmission BRP responses to BRP signaling received from the access point. The processing circuitry may be further configured to decode a link margin feedback signal received from the access point to determine an access point link margin, measure signal information associated with the link margin feedback signal to determine a received link margin measurement, and encode signaling for association with the access point based on the access point link quality and the receive link quality.

Abstract: Techniques (e.g., apparatus, method, machine-readable medium, chipset, etc.) to effect scenario analysis. Included is a determining of a power-affecting operational setting based on at least one operating condition of a device, the at least one operating condition of the device to be an operating condition of the device while the device is communicatively coupled to another device; and a setting of a first operational setting of the device based on the determined power-affecting operational setting.

Abstract: This disclosure describes systems, methods, and devices related to a time division duplex (TDD) antenna sector switch. A device may determine one or more antenna sector configurations based on TDD beamforming, wherein the one or more antenna sector configurations are associated with first antenna sectors used to communicate with a first station device (STA). The device may initiate a TDD sector switch with the first STA to switch from the one or more first antenna sectors to one or more second antenna sectors. The device may cause to send, to the first STA, an action frame comprising TDD sector setting parameters associated with the TDD sector switch. The device may identify a response frame received from the first STA, wherein the response frame comprises the TDD sector setting parameters. The device may perform the TDD sector switch by switching from the one or more first antenna sectors to the one or more second antenna sectors.

Abstract: A method for operating a media agnostic universal serial bus (MAUSB) device includes a compute device having a link connection manager, a USB manager, and a state manager. The compute device establishes a link with a MAUSB device and a session with the MAUSB device. Subsequently to receipt of a sleep command for the compute device, the compute device transitions to a sleep state and terminates the link with the MAUSB device while keeping intact the session with the MAUSB device. The compute device transitions back to an active state in response to receipt of a wake command for the compute device. The compute device sends a wake request to the MAUSB device. If the MAUSB device responds to the wake request with an acceptance, then the compute device reestablishes the previous session with the MAUSB device. If instead an error is received, the compute device terminates the session.

Abstract: An apparatus comprises a memory and processing circuitry that are configured to implement a first network control protocol (NCP) MAC layer configured to handle MAC layer communications of the first NCP, and sniffer edge circuitry. The sniffer edge circuitry is configured to communicate with the first NCP MAC layer and a second NCP MAC layer and to capture events related to second NCP (WiGig) communications. These captured events are communicated over a dedicated sniffer network, and packet contents communicated between the second NCP MAC layer and the second NCP stack are secure from the sniffer edge circuitry. The apparatus receives a distributed common time reference and uses this to timestamp the captured events.

Abstract: Some demonstrative embodiments include apparatuses, devices, systems and methods of power management in a wireless network. For example, a first wireless station may be configured to transmit a frame to a second wireless station during a first beacon interval, the frame including an indication that the first wireless station is to switch to a low power mode; switch to the low power mode; operate at an active mode during an awake window in a second beacon interval subsequent to the first beacon interval; and upon receipt of an announcement traffic indication message (ATIM) from the second wireless station during the awake window, transmit an acknowledgement to the second wireless station, and stay at the active mode to communicate data with the second wireless station.

Abstract: Embodiments of methods for scanning in a directive multi-gigabit network are generally described herein. An apparatus of a station may include processing circuitry configured to decode a sector sweep beacon received from an access point, encode for transmission a sector sweep feedback message to include a beam refinement protocol (BRP) request, and encode for transmission BRP responses to BRP signaling received from the access point. The processing circuitry may be further configured to decode a link margin feedback signal received from the access point to determine an access point link margin, measure signal information associated with the link margin feedback signal to determine a received link margin measurement, and encode signaling for association with the access point based on the access point link quality and the receive link quality.

Abstract: This disclosure describes systems, methods, and devices related to sensor data pipelining. A device may identify a first request of one or more requests received from a wireless universal serial bus (USB) host, wherein the first request is to collect data from a USB sensor. The device cause to send the first request to the USB sensor. The device identify a first response from the USB sensor, wherein the first response comprises data collected by the USB sensor based on the first request. The device determine that no additional requests are received from the wireless USB host. The device cause to send a second autonomous request to the USB sensor to collect data. The device identify a second response received from the USB sensor, wherein the second response is associated with the autonomous second request. The device cause to buffer or send the second response to the wireless USB host based on a second request being received from the wireless USB host.

Abstract: Disclosed herein are connection management techniques for wireless docking. According to various such techniques, a wireless docking station may be arranged to implement an auto-connect mode setting that defines whether mobile clients are permitted to automatically connect to the wireless docking station, and may be arranged to implement a persistent pairing setting that defines whether authentication certificates may be reused. In some embodiments, the wireless docking station may be configured to advertise the auto-connect mode setting and the persistent pairing setting in auto-connect capability information elements (IEs) that it includes in probe requests and/or probe responses. The embodiments are not limited in this context.

Abstract: This disclosure describes systems, methods, and devices related to a time division duplex (TDD) antenna sector switch. A device may determine one or more antenna sector configurations based on TDD beamforming, wherein the one or more antenna sector configurations are associated with first antenna sectors used to communicate with a first station device (STA). The device may initiate a TDD sector switch with the first STA to switch from the one or more first antenna sectors to one or more second antenna sectors. The device may cause to send, to the first STA, an action frame comprising TDD sector setting parameters associated with the TDD sector switch. The device may identify a response frame received from the first STA, wherein the response frame comprises the TDD sector setting parameters. The device may perform the TDD sector switch by switching from the one or more first antenna sectors to the one or more second antenna sectors.

Abstract: This disclosure describes systems, methods, and computer-readable media related to cross indication of queue size in a reverse direction protocol. In some embodiments, a reverse direction (RD) grantor may transmit a frame to an RD responder. The RD responder may identify data to be transmitted to the RD grantor based on the received frame. The RD responder may generate a frame that may comprise a plurality of sub-frames. The RD responder may set a sub-field in each of the sub-frames indicating whether there is data to transmit. The RD responder may also set a second sub-field that may indicate a priority or traffic stream associated with the data to be transmitted. The RD responder may transmit the frame (and associated sub-frames) to the RD grantor.

Abstract: Some demonstrative embodiments include apparatuses, devices, systems and methods of a Fast Basic Service Set (BSS) Transition (FT). For example, a wireless station (STA) may be configured to process at least one frame from at least one advertiser Access Point (AP) over a first frequency band while the STA is associated with a current AP over the first frequency band, the frame including a Multiband Mobility Domain Element (MMDE) corresponding to a target AP; and to transmit to the advertiser AP an FT authentication request frame over the first frequency band to request an FT from the current AP on the first frequency band to the target AP on the second frequency band, the FT request frame including the MMDE corresponding to the target AP.