Abstract: According to an aspect of an example, an access point (AP) may comprise a transceiver configured to receive, at the AP from a backhaul modem, a downlink signal including a signaling aid and a backhaul frame. The AP may comprise a processing device configured to: identify, at the AP, a signaling aid in the downlink signal to detect a downlink backhaul frequency channel; and determine, based on the signaling aid, one or more operating frequencies for the AP, wherein the operating frequencies do not include the backhaul frequency channel.

Abstract: According to an aspect of an embodiment, an AP may comprise a processing device and a transceiver. The processing device may be configured to: determine interference between the AP and one or more incumbent devices; determine a distance between the AP and the one or more incumbent devices; and determine an AP location based on a location of a close proximity communication device. The transceiver may be configured to: send, from the AP for transmission to an AFC server, the AP location, and receive, at the AP from the AFC server, a transmission power mode permission.

Abstract: According to an aspect of an embodiment, an automatic frequency coordination (AFC) server may comprise an AFC database and a processing device. The AFC database may comprise incumbent device data for an incumbent device. The processing device may be configured to determine a mean square error (MSE) value for the incumbent device. The processing device may be configured to compute an interference to noise (I/N) ratio for the incumbent device based on the MSE value for the incumbent device. The processing device may be configured to compute one or more operating frequencies for an access point, wherein the one or more operating frequencies have the I/N ratio of less than a threshold at the incumbent device.

Abstract: A method for collecting frequency spectrum data for an automated frequency coordination (AFC) system includes determining an operation mode of a Wi-Fi access point. The method also includes in response to a determination that the operation mode is associated with 6 GHz transmissions, determining a power mode of the Wi-Fi access point. The method also includes in response to a determination that the Wi-Fi access point is in a standard power mode, scanning one or more 6 GHz bands to begin collecting 6 GHz frequency spectrum data.

Abstract: A method for communicating multicast traffic includes snooping data received from a plurality of devices. The plurality of devices is in wireless communication with the access point. The method includes determining a multicast group membership status of each of the devices based on a result from snooping.

Abstract: Systems and methods are provided for powering Multimedia over Coax Alliance (MoCA) devices. An electronic device that is configured for use in a multimedia over coax alliance (MoCA) network may include a communication circuit operable to communicate multimedia over coax alliance (MoCA) based signals over coax cabling in the MoCA network, and one or more power circuits operable to support supplying and/or drawing power over the coax cabling in the MoCA network, to enable powering the electronic device and/or one or more other electronic devices in the MoCA network. The power circuits may include one or more of: a power regulator circuit that draws power from the coax cabling and/or regulates use of the power, a power source circuit that supplies power into the coax cabling, and a power management circuit that manages power related operations in the electronic device and/or in the MoCA network.

Abstract: Systems and methods are provided for powering Multimedia over Coax Alliance (MoCA) devices. An electronic device that is configured for use in a multimedia over coax alliance (MoCA) network may comprise a communication circuit operable to communicate multimedia over coax alliance (MoCA) based signals over coax cabling in the MoCA network, and one or more power circuits operable to support supplying and/or drawing power over the coax cabling in the MoCA network, to enable powering the electronic device and/or one or more other electronic devices in the MoCA network. The power circuits may comprise one or more of: a power regulator circuit that draws power from the coax cabling and/or regulates use of the power, a power source circuit that supplies power into the coax cabling, and a power management circuit that manages power related operations in the electronic device and/or in the MoCA network.

Abstract: Methods and systems for power optimization of a global navigation satellite system may comprise receiving LEO RF satellite signals utilizing a LEO satellite signal receiver path (LEO Rx) in a wireless communication device (WCD). Circuitry in the LEO Rx may be configured in a powered down state based on a sleep schedule. A location of the wireless communication device may be determined utilizing LEO signals received by the LEO Rx. The sleep schedule may be based on a desired accuracy of the determined location, the relative strengths of signals received from a plurality of LEO satellites, a relevance factor generated by a position engine and communicated to the sort module, or a desired power level of the WCD. The relative strengths of received signals may be compared utilizing a sort module in a LEO demodulator in the LEO satellite signal receiver path.

Abstract: Systems and methods are provided for remote secure automated system recovery, debug, and logging. In particular, remote management circuits may be configured to support remote automated management of systems by remote entities, specifically to enable managing the systems during system crashes and/or when the systems may not be operating normally. Security measures may be utilized to ensure secure management. In particular, communication may be performed over encrypted links, with encryption and decryption being performed by the remote management circuits.

Abstract: Methods and systems for power optimization of a global navigation satellite system may comprise receiving LEO RF satellite signals utilizing a LEO satellite signal receiver path (LEO Rx) in a wireless communication device (WCD). Circuitry in the LEO Rx may be configured in a powered down state based on a sleep schedule. A location of the wireless communication device may be determined utilizing LEO signals received by the LEO Rx. The sleep schedule may be based on a desired accuracy of the determined location, the relative strengths of signals received from a plurality of LEO satellites, a relevance factor generated by a position engine and communicated to the sort module, or a desired power level of the WCD. The relative strengths of received signals may be compared utilizing a sort module in a LEO demodulator in the LEO satellite signal receiver path.

Abstract: Methods and systems for power optimization of a global navigation satellite system may comprise receiving LEO RF satellite signals utilizing a LEO satellite signal receiver path (LEO Rx) in a wireless communication device (WCD). Circuitry in the LEO Rx may be configured in a powered down state based on a sleep schedule. A location of the wireless communication device may be determined utilizing LEO signals received by the LEO Rx. The sleep schedule may be based on a desired accuracy of the determined location, the relative strengths of signals received from a plurality of LEO satellites, a relevance factor generated by a position engine and communicated to the sort module, or a desired power level of the WCD. The relative strengths of received signals may be compared utilizing a sort module in a LEO demodulator in the LEO satellite signal receiver path.

Abstract: The invention relates to method for controlling the orientation (Oinfo) of information (INFO) shown for a user (21) on a display (20), in which the information (INFO) has a target orientation (Oitgt) In method: the orientation (Odisplay) of the display (20) is defined relative to the information (INFO) shown on the display (20); and if the orientation (Oinfo) of the information (INFO) shown on the display (20) differs from the target orientation (Oitgt), then a change of orientation (?O) is implemented, as result of which change the orientation (Oinfo) of the information (INFO) shown on the display (20) is made to correspond to the target orientation (Oitgt).The orientation (Odisplay) of the display (20) is defined, in a set manner at intervals, by using a camera means (11) connected operationally to the display (20).

Abstract: A method and apparatus for protecting electronic devices from cloning employs an electronic signature generated from an identification code for the electronic device (e.g., an electronic serial number (ESN), an international mobile equipment identifier (IMEI), or the like) and a unique, unchangeable identification for a hardware component of the electronic device code (e.g., a flash hardware serial number, or the like). The electronic signature is encrypted and stored to the non-volatile memory of the electronic device for verifying the authenticity of the electronic device's identification code to prevent use of the device for cloning a second electronic device.