A system includes a plurality of remote units; a centralized unit communicatively coupled to the plurality of remote units via a fronthaul network; and an entity that performs deep packet inspection. The centralized unit transmits sets of data to the plurality of remote units across the fronthaul network in packets, each of the sets of data mapped to at least one of the plurality of remote units and each of the packets including a respective indicator indicating each remote unit the associated packet is intended for, wherein each indicator comprises a plurality of bit positions where each bit position is mapped to a different one of the plurality of remote units. The entity performs the deep packet inspection on the packets to determine each remote unit the packets are intended for and communicate each packet to each remote unit the packet is intended for over the fronthaul network.

Methods and apparatus for controlling transmission of a base station, such as a Femto cell, based on the determined quality of a backhaul connection to a network are disclosed. In particular, a quality of a backhaul connection of a base station to a node in a communication network is determined. Based on this quality determination, transmission from the base station is either limited or stopped when the determined quality fails to meet a predefined condition. The degradation in quality of the backhaul connection, for example, affects the ability of the base station to offer sufficient service to access terminals. By limiting or stopping wireless transmission of the base station when the backhaul quality is degraded, access terminals either currently accessing the base station or attempting to connect to the base station can then more efficaciously hand off to another base station or access point.

In an example method, a first wireless access device establishes, based on disconnection from a second wireless access device, a connection to the second wireless access device by using stored first configuration information. The first wireless access device receives a first notification message from a server through the connection established to the second wireless access device. The first wireless access device re-establishes a connection to the second wireless access device based on the first notification message by using second configuration information. The first wireless access device can receive the notification message from the server through the connection established to the second wireless access device by using the first configuration information.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a wireless node may establish a connection with a base station. The wireless node may provide, to the base station, an indication that the wireless node has backhauling capability. The wireless node may receive a backhauling configuration from the base station over the connection after providing the indication that the wireless node has backhauling capability. Numerous other aspects are described.

A method of sharing of network resources between at least two access gateways, each of the at least two access gateways providing network connectivity to user equipment, includes assessing whether a first access gateway can to share a portion of available network resources, assessing whether a second access gateway requires additional network resources to provide network connectivity to user equipment, and establishing a wireless connection between the first access gateway and the second access gateway. The first access gateway provides the portion of available network resource as additional network resources for the second access gateway. The method also includes collecting information regarding operation of the two access gateways, processing information for identifying assessment rules regarding availability of network resources, exploiting the assessment rules for determining availability of network resources, and providing available network resources from the first access gateway to the second access gateway according to the availability of network resources.

A method of sharing of network resources between at least two access gateways, each of the at least two access gateways providing network connectivity to user equipment, includes assessing whether a first access gateway can to share a portion of available network resources, assessing whether a second access gateway requires additional network resources to provide network connectivity to user equipment, and establishing a wireless connection between the first access gateway and the second access gateway. The first access gateway provides the portion of available network resource as additional network resources for the second access gateway. The method also includes collecting information regarding operation of the two access gateways, processing information for identifying assessment rules regarding availability of network resources, exploiting the assessment rules for determining availability of network resources, and providing available network resources from the first access gateway to the second access gateway according to the availability of network resources.

Techniques that provide link establishment between a radio equipment controller (REC) and a radio equipment (RE) in a fronthaul network are described herein. In one embodiment, a method includes performing, Common Public Radio Interface (CPRI) Layer 1 (L1) link auto-negotiation operations to establish a CPRI link between the REC and RE. A proxy slave may achieve a hyper frame number (HFN) synchronization with the REC at a link bit rate for a first CPRI bit stream and communicate the first CPRI bit stream and the link bit rate to a proxy master. The proxy master may communicate a second CPRI bit stream to the proxy slave to transmit to the REC. The L1 link auto-negotiation operations are completed and CPRI link is established between the REC and the RE when the REC achieves a HFN synchronization for the second CPRI bit stream.

A pre-5.sup.th-Generation (5G) or 5G communication system for supporting higher data rates Beyond 4.sup.th-Generation (4G) communication system such as Long Term Evolution (LTE) is provided. The device of a radio unit (RU) of a base station in a wireless communication system includes at least one transceiver and at least one processor coupled to the at least one transceiver, wherein the at least one processor is configured to receive a first control message including a section extension field from a digital unit (DU) via a fronthaul interface, identify additional information based on the section extension field, and acquire a beamforming weight based on the additional information, wherein the first control message is configured to schedule a terminal in a control plane.

In modern networks, RRU and BBU equipment of an access point site typically handles traffic from a single sector. An RRU-BBU pair process that traffic (often limited to a single spectrum from a single sector) according to implemented capabilities and other equipment located further upstream perform functions that rely on information from multiple sectors. An integrated device (e.g., white box) can integrate the functionality of multiple RRU (or NR in 5G) and the functionality of multiple BBU (or DU/CU splits in 5G), which can reduce implementation footprint, costs, and can provide related services more efficiently without going upstream.

Techniques and apparatus for managing a message relaying system are described. One technique includes an access point (AP) detecting a first signal and a second signal from a computing device. A validation of the first signal is performed based on parameters of the first signal and the second signal. After the validation, information associated with the first signal is transmitted to a computing system. In another technique, the computing system may designate one of multiple APs reporting information regarding first signals as a primary reporting AP and designate the remaining APs as secondary reporting APs. The computing system may instruct the secondary reporting APs to refrain from reporting information regarding first signals to the computing system.