A wireless communication node (300) and method therein for generating multicarrier signals by means of backscattering in a wireless communication system (100) are disclosed. The wireless communication node (300) comprises a plurality A of antennas (310) configured to receive a radio frequency. The wireless communication node (300) further comprises a plurality A of switches (320), each switch has a number M of states. The wireless communication node (300) further comprises a number of impedance matrices (330), each impedance matrix comprising a number M of impedances (Z1, Z2 . . . ), each antenna is coupled to one of the impedance matrices (330) by one of the plurality A switches (320). The wireless communication node (300) further comprises a symbol mapper, a serial to parallel converter and one or more modulators (340) configured to generate a number A of baseband subcarrier signals based on data symbols (342) to be transmitted. The wireless communication node (300) further comprises one or more switch controller (350) configured to control the states of the plurality A of switches (320) based on the generated baseband subcarrier signals such that each antenna impedance is selected among the number M of impedances (330), and thereby the received RF signal at each antenna is modulated by its specific frequency baseband subcarrier signal. A group of RF subcarrier signals is generated by reflecting the modulated RF signal from each antenna, and thereby the multicarrier signals are generated from the plurality A of antennas (310).

Architectures, methods and apparatus for providing data services (including enhanced ultra-high data rate services and IoT data services) which leverage existing managed network (e.g., cable network) infrastructure, while also providing support and in some cases utilizing the 3GPP requisite NSA functionality. Also disclosed are the ability to control nodes within the network via embedded control channels, some of which “repurpose” requisite 3GPP NSA infrastructure such as LTE anchor channels. In one variant, the premises devices include RF-enabled receivers (enhanced consumer premises equipment, or CPEe) configured to receive (and transmit) OFDM waveforms via a coaxial cable drop to the premises. In another aspect of the disclosure, methods and apparatus for use of one or more required NSA LTE channels for transmission of IoT user data (and control/management data) to one or more premises devices are provided.

Aspects of the present application provide methods and devices for time domain implementation of a single carrier waveform such as single carrier quadrature amplitude modulation (QAM) DFT-s-OFDM and single carrier Offset QAM (OQAM). A time domain implementation allows flexible symbol lengths, lower implementation complexity as a large IDFT operation is not required in the time domain and support for variable cyclic prefix (CP) length. An OQAM implementation utilizes a pre-processing step to convert a K complex QAM symbol sequence into a 2K OQAM symbol sequence and generates a sequence for transmission in the time domain as opposed to the frequency domain.

A multi-carrier cellular wireless network (400) employs base stations (404) that transmit two different groups of pilot subcarriers: (1) cell-specific pilot subcarriers, which are used by a receiver to extract information unique to each individual cell (402), and (2) common pilots subcarriers, which are designed to possess a set of characteristics common to all the base stations (404) of the system. The design criteria and transmission formats of the cell-specific and common pilot subcarriers are specified to enable a receiver to perform different system functions. The methods and processes can be extended to other systems, such as those with multiple antennas in an individual sector and those where some subcarriers bear common network/system information.

Methods, systems, and devices for wireless communications are described. In one example, a transmitting device may identify first and second portions of data to include in a data transmission. The transmitting device may encode the second portion by a configuration of a first subset of resource elements. The transmitting device may transmit, via the data transmission, first signals representative of the first portion over the first subset and one or more second signals over a second subset of resource elements. A receiving device may receive the data transmission and may identify that the one or more second signals include content other than data of the data transmission. The receiving device may decode the first signals in order to identify the first portion and the configuration in order to identify the second portion. The receiving device may refrain from decoding the one or more second signals based on the identifying.

Methods, systems, and devices for wireless communications are described. A transmitting device may identify a first signal in a time domain, the first signal including multiple sequences spanning a bandwidth for multiple symbol periods. The transmitting device may segment the first signal into signal segments, where each signal segment corresponds to a respective symbol period of the multiple symbol periods. The transmitting device may apply a first transform operation to each signal segment of the signal segments and apply a bandwidth restriction in the frequency domain to the transformed signal segments. Then, the transmitting device may apply a second transform operation to each transformed signal segment to return the bandwidth-restricted segments to the time domain. The transmitting device may generate a second signal in the time domain based on the bandwidth-restricted segments. The transmitting device may then transmit the second signal to a receiving device.

Apparatus and methods for guaranteeing a quality of experience (QoE) associated with data provision services in an enhanced data delivery network. In one embodiment, a network architecture having service delivery over at least portions of extant infrastructure (e.g., a hybrid fiber coax infrastructure) is disclosed, which includes standards-compliant ultra-low latency and high data rate services (e.g., 5G NR services) via a common service provider. In one exemplary implementation, “over-the-top” voice data services may enable exchange of voice traffic with client devices in the aforementioned network. A distribution node may use a detection rule to identify received packets as voice traffic, and cause a dedicated bearer to attach to the default bearer, thereby enabling delivery of high-quality voice traffic by at least prioritizing the identified packets thereafter and sustaining the delivery even in a congested network environment, and improving the quality of service (QoS) and QoE for the user(s).

Apparatus and methods for unified high-bandwidth, low-latency data services. In one embodiment, a network architecture having service delivery over at least portions of extant infrastructure (e.g., a hybrid fiber coaxial infrastructure) is disclosed, which includes standards-compliant ultra-low latency and high data rate services (e.g., 5G NR services) via a common service provider. In one variant, parallel MIMO data streams supported by 3GPP 5G NR are shifted in frequency before being injected into the single coaxial cable feeder, so that frequency diversity (instead of spatial diversity) is leveraged to achieve the maximum total carrier bandwidth that 3GPP 5G NR chipsets. Intermediate Frequencies (IF) are transmitted over the media in one implementation, (i.e., instead of higher frequencies), and block-conversion to RF carrier frequency is employed subsequently in the enhanced consumer premises equipment (CPEe) for 3GPP band-compliant interoperability with the 3GPP 5G NR chipset in the CPEe.

A wireless communication node (300) and method therein for generating multicarrier signals by means of backscattering in a wireless communication system (100) are disclosed. The wireless communication node (300) comprises a plurality A of antennas (310) configured to receive a radio frequency. The wireless communication node (300) further comprises a plurality A of switches (320), each switch has a number M of states. The wireless communication node (300) further comprises a number of impedance matrices (330), each impedance matrix comprising a number M of impedances (Z1, Z2 . . . ), each antenna is coupled to one of the impedance matrices (330) by one of the plurality A switches (320). The wireless communication node (300) further comprises a symbol mapper, a serial to parallel converter and one or more modulators (340) configured to generate a number A of baseband subcarrier signals based on data symbols (342) to be transmitted. The wireless communication node (300) further comprises one or more switch controller (350) configured to control the states of the plurality A of switches (320) based on the generated baseband subcarrier signals such that each antenna impedance is selected among the number M of impedances (330), and thereby the received RF signal at each antenna is modulated by its specific frequency baseband subcarrier signal. A group of RF subcarrier signals is generated by reflecting the modulated RF signal from each antenna, and thereby the multicarrier signals are generated from the plurality A of antennas (310).

A multi-carrier cellular wireless network (400) employs base stations (404) that transmit two different groups of pilot subcarriers: (1) cell-specific pilot subcarriers, which are used by a receiver to extract information unique to each individual cell (402), and (2) common pilots subcarriers, which are designed to possess a set of characteristics common to all the base stations (404) of the system. The design criteria and transmission formats of the cell-specific and common pilot subcarriers are specified to enable a receiver to perform different system functions. The methods and processes can be extended to other systems, such as those with multiple antennas in an individual sector and those where some subcarriers bear common network/system information.