Aspects of the subject disclosure may include, for example, obtaining channel cross correlation data relating to multiple user equipment (UEs) being served in a cell, wherein the channel cross correlation data comprises a correlation coefficient associated with a first UE of the multiple UEs and a second UE of the multiple UEs, identifying that the first UE is experiencing decreasing throughput, responsive to the identifying that the first UE is experiencing decreasing throughput, determining whether the correlation coefficient associated with the first UE and the second UE satisfies a correlation threshold, and, based on a first determination that the correlation coefficient does not satisfy the correlation threshold, adjusting a downlink (DL) transmit power allocation for transmissions directed to the first UE. Other embodiments are disclosed.

The present disclosure describes systems and methods for selecting modulation and coding schemes (MCS) per-sub-band, and in some examples, per-stream. In some examples, channel condition metrics regarding wireless communication conditions from a communication node of a wireless access system may be received. Based at least on the received channel condition metrics, a modulation and coding scheme may be selected. In some examples, the selected modulation and coding scheme may be transmitted to various modulators/demodulators, encoders/decoders, and/or other communication nodes within the wireless access system.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a transmission-adjusting wireless node may transmit a first communication via a sidelink channel. The transmission-adjusting wireless node may receive, from a feedback-reporting wireless node, transmission-specific information relating to at least one of a channel quality of the sidelink channel or a power level for the transmission-adjusting wireless node. The transmission-specific information may be based at least in part on the first communication. The transmission-adjusting wireless node may adjust, based at least in part on the transmission-specific information, a transmission property of the transmission-adjusting wireless node to obtain an adjusted transmission property. The transmission-adjusting wireless node may transmit a second communication via the sidelink channel using the adjusted transmission property. Numerous other aspects are provided.

Systems, methods, apparatuses, and computer program products for altitude-aware energy saving. The method may include receiving, from a network element, information including a coupling loss change or a reduced transmit power command. The method may also include controlling an uplink transmission based on the received information.

A global prediction manager for generating predictions using data from data zones includes storage for storing a model repository comprising a global model set and a prediction manager. The prediction manager obtains a local model set from a data zone of the data zones indicating that the global model set is unacceptable; makes a determination that the local model set is acceptable; in response to the determination: distributes the local model set to at least one second data zone of the data zones; obtains compressed telemetry data, that was compressed using the local model set, from the data zone and the at least one second data zone; and generates a global prediction regarding a future operating condition of the data zones using: the compressed local telemetry data and the local model set.

Facilitating real-time power optimization in advanced networks (e.g., 5G, 6G, and beyond) is provided herein. Operations of a method can include determining, by a system comprising a memory and a processor, a power distribution setting for a user equipment that includes multiple radios based on a historical radio power usage, a historical performance result, a current location, and an application currently executing on the user equipment. The method also can include implementing, by the system, the power distribution setting across the multiple radios of the user equipment. The first radio of the multiple radios can be a first radio type and a second radio of the multiple radios can be a second radio type, different from the first radio type.

A method can include an integrated circuit device, determining if first communication circuits are operating in a first mode that wirelessly receives data at a first rate or a second mode that wirelessly receives data at a second rate that is lower than the first rate. If the first communication circuits are operating in the second mode, transmitting signals with the second communication circuits at a first power level, and if operating in the first mode, transmitting signals with the second communication circuits at a second power level that is lower than the first power level. In the first mode, X symbols per data bit are received and in the second mode, Y symbols per data bit are received, where X<Y. Corresponding devices and methods are also disclosed.

A data transmission method, applied to a terminal that uses a dual connection mode of non-standalone networking for data transmission, includes: monitoring a network signal quality in the dual connection mode of non-standalone networking, and monitoring a real-time data packet transmission rate of a data packet transmitted and received by the terminal; and adjusting, based on the network signal quality and the real-time data packet transmission rate, the dual connection mode of non-standalone networking, which includes turning off the dual connection mode of non-standalone networking or maintaining the dual connection mode of non-standalone networking. Automatic and dynamic switching between EN-DC dual connection and single 4G network connection can be realized, without manually switching networks by users, such that effective transmission and reception of terminal data packets is ensured, and increase in power consumption caused by always relying on the EN-DC dual connection is avoid.

Systems and methods for power conservation via frame aggregation in a wireless network. A station may enter low-power sleep mode for a prescribed duration and subsequently transmit or receive either a burst transmission or an aggregate frame comprising a prescribed amount of data. The prescribed duration and amount of data may be analytically characterized in terms of the arrival rate of data, latency, power consumption, and various additional parameters in the wireless network. The systems and methods can be applied to conserve power in data-intensive high-rate wireless mesh networks, finding application in cellular backhaul, mm wave small cell networks, oil and gas exploration, and wide area monitoring.

The devices, systems, and techniques described herein provide for efficient communications between devices to reduce power consumption while maintaining performance. In some aspects, a terminal may adjust a transmission power limit for transmitting signals to a base station to reduce power consumption at the terminal. In some examples, the terminal may adjust the transmission power limit based on a temperature of the terminal and a number of resource blocks allocated to the terminal (e.g., such that the temperature remains below a threshold). In some other examples, the terminal may adjust the transmission power limit based on a block error rate (BLER) (e.g., such that the BLER remains below a threshold while minimizing the transmission power limit). In some other examples, the terminal may adjust the transmission power limit based on an importance of one or more transmissions (e.g., to avoid wasting power on less important transmissions).