Responsive to receiving a probe request at an idle transceiver over a first channel from a Wi-Fi client and a determination that the Wi-Fi client is not currently associated with the access point for service, a second channel being used for client service is identified. A probe response frame is generated including a CSA (channel switch announcement) indicating the second channel and transmitted to the Wi-Fi client causing authentication over the second channel. The Wi-Fi client is then serviced over the at least one non-idle transceiver over the second channel.

Responsive to receiving a probe request at an idle transceiver over a first channel from a Wi-Fi client and a determination that the Wi-Fi client is not currently associated with the access point for service, a second channel being used for client service is identified. A probe response frame is generated including a CSA (channel switch announcement) indicating the second channel and transmitted to the Wi-Fi client causing authentication over the second channel. The Wi-Fi client is then serviced over the at least one non-idle transceiver over the second channel.

A wireless communication system includes a first communication device and a second communication device. The first communication device obtains a plurality of radio frequency (RF) signals corresponding to different communication protocols from a plurality of communication systems. A frequency of each of the plurality of RF signals is upconverted to a different frequency, and a phase noise is introduced in the plurality of RF signals. The plurality of RF signals corresponding to different communication protocols are multiplexed into a mmWave RF signal of a specified frequency and a defined pilot tone along with the mmWave RF signal is transmitted. The second communication device captures the mmWave RF signal having the defined pilot tone over-the-air. At least one RF signal is down converted to a source frequency and the phase noise is estimated in the one extracted RF signal based on the defined pilot tone which is reduced concurrently.

Mitigation of satellite interference is contemplated. The mitigation may include processing satellite transmissions to remove interferences based on an amount of signal overlap, such as to facilitate mitigating interferences resulting from satellite spacing and/or ground antenna dish size.

An unmanned mobile communication station is adapted for location in a marine environment and includes a platform adapted for flotation or is semi-submersible, a communication node for sending and receiving wireless signals, a power system for energizing said communication node, a data center, at least one sensor for detecting the geolocation of the platform; and a processor for receiving signals from said sensors and controlling communication to and from communication nodes wherein embodiments include both autonomous and remote controlled navigation and propulsion systems.

An unmanned mobile communication station is adapted for location in a marine environment and includes a platform adapted for flotation or is semi-submersible, a communication node for sending and receiving wireless signals, a power system for energizing said communication node, a data center, at least one sensor for detecting the geolocation of the platform; and a processor for receiving signals from said sensors and controlling communication to and from communication nodes wherein embodiments include both autonomous and remote controlled navigation and propulsion systems.

The present disclosure provides a Light Emitting Diode (LED) illuminating apparatus. The illuminating apparatus includes a first antenna, a second antenna, a signal amplifying unit, an LED lighting unit, and an LED driving power supply. The LED driving power supply is connected with the signal amplifying unit and the LED lighting unit to drive the LED lighting unit to emit light and to provide power to the signal amplifying unit. The first antenna and the second antenna are connected to the signal amplifying unit. The first antenna receives a base station signal, and transmits the base station signal to the signal amplifying unit. The signal amplifying unit amplifies the base station signal, and transmits the amplified base station signal to the second antenna. The second antenna transmits the amplified base station signal to a terminal. The second antenna further receives a terminal signal, and transmits the terminal signal to the signal amplifying unit. The signal amplifying unit further amplifies the terminal signal, and transmits the amplified terminal signal to the first antenna. The first antenna further transmits the amplified terminal signal to a base station.

A wireless communication system based on millimeter wave (mmWave) radio frequency (RF) repeaters includes a first communication device. The first communication device includes a digital signal processor configured to provide access to a first type of communication network to a plurality of communication systems that are communicatively coupled to the first communication device via a plurality of different type of wireless networks. A plurality of radio frequency (RF) signals corresponding to different communication protocols is obtained via the plurality of different type of wireless networks. The obtained plurality of RF signals corresponding to different communication protocols are merged into a mmWave RF signal of a specified frequency. The mmWave RF signal of the specified frequency is transmitted to a second communication device.

Embodiments of the present application provide a method and apparatus of communication between a terminal and a base station. The communication method between a terminal and a base station performed by the terminal includes: sending, by the terminal, a network access request frame with a first preamble to a relay device. The relay device may be configured to receive the network access request frame according to the first preamble, send the network access request frame with a second preamble to the base station, and receive a network access response frame returned by the base station. The length of the second preamble may be smaller than that of the first preamble. The communication method may further includes receiving, by the terminal, the network access response frame sent by the relay device.

The application relates to a communication method, apparatus, and system, a storage medium, and a terminal. The method includes: receiving first data from a first receiving device in multiple first devices of a first device type through a first network of a first network type, wherein the first data is received from a first client device by the first receiving device through a second network of a second network type, the first data is configured to control a first target device in multiple second devices of a second device type, and the first client device is beyond a communication range of the second devices; and sending the first data to a relay device in the second devices through a third network of a second network type, wherein the relay device is connected to the first target device through a fourth network of a third network type, and the first data is sent to the first target device by the relay device. The technical solution of the application allows a communication connection to be established between different types of Bluetooth network devices without updating an old type of network devices.