A technique is described for selecting an encoder to encode video captured by a network-connected camera system based on characteristics of deployment of the network connected cameras system. The network-connected camera system may include one or more cameras and a base station connected to each other via a network, which can be a wireless network. A processing system, for example at the base station, receives data indicative of characteristics of deployment of the network-connected camera system, processes, the received data to select an encoder, and causes the one or more cameras to process captured video using the selected encoder. In some embodiments, encoder selections can be continually updated based on changes in the deployment of the network-connected camera system.

Determining a sequence for providing a notification regarding activity recorded by a camera is described. In one aspect, a priority sequence for can be determined based on a variety of characteristics of the available devices registered with the home security system of the camera.

Disclosed are methods and systems for the testing and optimization of one or more wireless devices, e.g., wireless cameras, such as in conjunction with corresponding systems. Wireless device test capabilities include any of: single device, wireless video rate/delay/interference test; multi-security camera system wireless DC power range tweet with and without noise/interference; security camera system image quality with and without movement in day and night mode; multi-camera wireless range vs. DC power tweet with and without interference; WLAN beacon/sniffer automation; wireless audio range testing; security camera uplink testing; and optical synchronized video/audio distribution (optical fiber).

Systems and methods are introduced for rate control of data transmissions in a wireless camera system. In an illustrative embodiment, a computing system selects primary data rates and corresponding fallback data rates to use for transmission of video data. The computing system selects the data rates that provides high-throughput without resulting in wasted energy from retransmissions. The selection may be based upon transmission conditions as well as the record of past data rates, the number of attempts for the data rates, and whether they were successful. These data may be stored as a state machine or for machine learning analysis. Finally, the video data may be aggregated prior to transmission to reduce overhead and improve efficiency.

The disclosure is related to adaptive transcoding of video streams from a camera. A camera system includes a camera and a base station connected to each other in a first communication network, which can be a wireless network. When a user requests to view a video from the camera, the base station obtains a video stream from the camera, transcodes the video stream, based on one or more input parameters, to generate a transcoded video stream, and transmits the transcoded video stream to a user device. The base station can transcode the video stream locally, e.g., within the base station, or in a cloud network based on transcoding location factors. Further, the camera system can also determine whether to stream the video to the user directly from the base station or from the cloud network based on streaming location factors.

A base station device can adaptively assemble the downlink control information using a plurality of information segments and then transmit the assembled downlink control information to a mobile device. The information segments can each represent different control functions and the base station device can select relevant and appropriate information segments to include in the downlink control information based on the features represented in the downlink data transmission and the mobile device. If the downlink data transmission does not have a certain feature, the base station device can leave the information segment relevant to the feature out of the downlink control information. Additionally, when new features are introduced, new information segments can be added without defining a new downlink control information format.

A device may receive channel data associated with a channel provided between a network and a user device, and may calculate, based on the channel data, key performance indicator data that includes a plurality of key performance indicators for the channel. The device may multiply the plurality of key performance indicators by factors to generate factored key performance indicator data that includes a plurality of factored key performance indicators. The device may apply weights to the plurality of factored key performance indicators of the factored key performance indicator data to generate factored weighted key performance indicator data that includes a plurality of factored weighted key performance indicators. The device may calculate a quality indicator for the channel based on the factored weighted key performance indicator data, and may perform one or more actions based on the quality indicator for the channel.

Techniques for improved wireless reliability are provided. It is determined that a client device is at least one of an augmented reality (AR) or a virtual reality (VR) device. A default set of retry parameters and a second set of retry parameters are determined, where the second set of retry parameters are more robust than the default set of retry parameters. Data is transmitted to the client device using the second set of retry parameters.

Embodiments of the present disclosure disclose devices, methods and apparatuses for uplink transmission. A terminal device measures at least two reference signals from a network device. Moreover, the terminal device transmits, to the network device, a mode indication of uplink transmission for multiple transmission and reception points (m-TRP) based on the measured at least two reference signals. The mode indication indicates information on a preferred one of frequency division multiplexing (FDM) transmission modes. The FDM transmission modes comprise at least a first FDM transmission mode and a second FDM transmission mode.

Pilots suitable for use in MIMO systems and capable of supporting various functions are described. The various types of pilot includea beacon pilot, a MIMO pilot, a steered reference or steered pilot, and a carrier pilot. The beacon pilot is transmitted from all transmit antennas and may be used for timing and frequency acquisition. The MIMO pilot is transmitted from all transmit antennas but is covered with different orthogonal codes assigned to the transmit antennas. The MIMO pilot may be used for channel estimation. The steered reference is transmitted on specific eigenmodes of a MIMO channel and is user terminal specific. The steered reference may be used for channel estimation. The carrier pilot may be transmitted on designated subbands/antennas and may be used for phase tracking of a carrier signal. Various pilot transmission schemes may be devised based on different combinations of these various types of pilot.