Abstract: Embodiments relate to an apparatus for monitoring a telecommunication network including one or more telecommunication channels. The apparatus includes a processor configured after executing computer code to design a convolutional neural network configured for determining an impairment type of a telecommunication channel as a function of a channel frequency response of the telecommunication channel, by selecting at least one of a number of convolutional layers, a number of filters for respective convolutional layers, and/or a size of filters for respective convolutional layers; and train the convolutional neural network based on training data specifying, for respective telecommunication channels, a channel frequency response and an associated impairment type.

Abstract: The present invention addresses a method, apparatus and computer program product for accessing a local area scoped network having non-access-stratum procedures, such as a MuLTEfire network, which implement identifying an available access point of the local area scoped network having non-access-stratum procedures, transmitting a message to the access point, indicating a request for retrieving network information, wherein the information are queried from the network before authorization and actually connecting to the network, selecting a service provider of the network based on received network information for binding the network identity to the selected service provider for accessing, and conveying a Non-Access Stratum service request to the network to cause authentication of the user equipment for connecting to the network.

Abstract: A technique may include sending, by a base station to at least one user device, a signal indicating a configuration of at least one guard period, wherein the at least one guard period is provided between subframe portions of a same link direction. According to an example implementation, the at least one guard period may include one or more of: at least one first guard period provided between subframe portions of a same link direction within a subframe, and at least one second guard period provided between subframe portions of a same link direction of different subframes.

Abstract: An optical system having a plurality of ring resonators that can be tuned by regulating their local temperatures in a manner that enables: initial spectral alignment of the optical resonances with the desired carrier wavelengths; fine-tuning of the ring resonators to spectrally align a selected feature of the optical resonances with the carrier wavelengths; and continuous tuning of the ring resonators to counter any detuning thereof during operation. The initial spectral alignment can be performed using intensity/frequency modulation of different carrier wavelengths with different respective frequencies and detection of said frequencies in the photocurrents generated by the individual ring resonators under reverse-bias conditions.

Abstract: An apparatus includes a laser, an optical power combiner, and an electronic controller. The laser has a plurality of modulatable optical reflectors and is operable to emit mutually coherent optical beams from the modulatable optical reflectors. The optical power combiner has a first optical inputs connected to receive light of one of the optical beams emitted from a first of the modulatable optical reflectors and has a second optical input connected to receive light of one of the optical beams emitted from a second of the modulatable optical reflectors. The electronic controller is connected to operate the first and second of the modulatable optical reflectors to modulate the optical beams emitted therefrom to carry respective first and second data streams. The optical power combiner is connected to interfere the light received from the first and second of the modulatable optical reflectors with a relative phase difference.

Abstract: Encoders and decoders for encoding and decoding data according to a coding scheme. The encoder converts N bits of input data into M voltage signals for transmission over M parallel wires to a decoder having one or two decoding stages that recover the N bits of data from the M voltage signals. The coding scheme is an N-bit, M-wire PAM-Q code in which each voltage signal wi has one of Q voltage levels l1-lQ, where l1<l2< . . . <lQ, and the different sets of M voltage signals for the different N-bit input values are permutations of a single set of M voltage signals. The decoder has a comparator stage. For the decoder having one other decoding stage, the other decoding stage is a computation stage or a logic stage that is before or after the comparator stage.

Abstract: Systems, methods, and software for controlling Quality of Service (QoS) selection in Mobile Edge Computing (MEC) services. In one embodiment, a MEC server is at a Radio Access Network (RAN), and implements edge applications that provide the MEC services. The MEC server queries a core network for a QoS policy for a mobile device that indicates QoS profile options for the mobile device, and receives the QoS policy from the core network. The MEC server monitors for a triggering event that triggers selection of a QoS profile, selects the QoS profile from the QoS profile options for a user plane connection established for a MEC service between the mobile device and an edge application in response to the triggering event, and provides a QoS profile identifier for the QoS profile to a base station in the RAN to enforce the QoS profile on the user plane connection.

Abstract: Embodiments of the present disclosure relate to a device, method and computer readable storage medium for wireless data transmission. In example embodiments, the device includes a first NCO configured to shift a frequency of a pre-distorted downlink baseband signal by a first offset to generate a first signal. The baseband signal is associated with a plurality of allocated carriers. The device also includes an RF processing unit including an LO configured to generate an LO signal at an LO frequency. The LO frequency is within a protection area of one of the plurality of allocated carriers or equal to a center frequency of the one of the plurality of allocated carriers. The device also includes a power amplifier configured to generate, based on a modulated baseband signal, an amplified signal for transmission. The device also includes a second NCO configured to shift a frequency of the amplified signal by a second offset to generate a second signal for generation of a pre-distortion coefficient.

Abstract: Various communication systems may benefit from improved wireless communications. For example, communication systems may benefit from a wireless broadband network that monitors and detects link latency. A method includes detecting latency information of data being transmitted on at least one link between a first base station and at least one second base station. In addition, the method includes forming at least one array comprising the latency information of the data. Further, the method includes modifying a system behavior relating to at least the first base station or the at least one second base station based on the at least one array.

Abstract: A digital circuit for implementing a channel-tracking functionality, in which an adaptive (e.g., FIR) filter is updated based on reinforcement learning. In an example embodiment, the adaptive filter may be updated using an LMS-type algorithm. The digital circuit may also include an electronic controller configured to change the convergence coefficient of the LMS algorithm using a selection policy learned by applying a reinforcement-learning technique and based on residual errors and channel estimates received over a sequence of iterations. In some embodiments, the electronic controller may include an artificial neural network. An example embodiment of the digital circuit is advantageously capable of providing improved performance after the learning phase, e.g., for communication channels exhibiting variable dynamicity patterns, such as those associated with aerial copper cables or some wireless channels.

Abstract: Embodiments of the present disclosure provide a communication method and apparatus. For example, at a first device, a resource for data transmission is randomly selected, and the resource is used to transmit data. In addition, the first device sends, to a second device, an indication that the first device will continue to use the resource for transmitting further data. A corresponding apparatus is further disclosed in the present disclosure.

Abstract: Embodiments of the present disclosure provide a method for multiple input multiple output (MIMO) communications. For example, scheduling information is received at a terminal device from a network device, the scheduling information at least indicates physical resource blocks shared by a demodulation reference signal (DMRS) of the terminal device and a further DMRS of at least one further terminal device, and different sub-carriers allocated to the DMRS and the further DMRS in each of physical resource blocks, and the number of physical resource blocks is indivisible by a total number of the terminal device and the at least one further terminal device. The DMRS is generated, and a length of the DMRS is determined based on the number of physical resource blocks and the number of at least one further terminal device. The DMRS is transmitted to the network device on the sub-carriers allocated to the DMRS in the physical resource blocks.

Abstract: A resonator for radio frequency, RF, signals, said resonator comprising a cavity having a longitudinal axis, a first wall, at least one side wall, and a lid arranged opposite the first wall, wherein said resonator further comprises a guiding device which is arranged at said at least one side wall and is configured to guide an axial movement of said lid along said longitudinal axis.

Abstract: The present invention provides apparatuses, methods, computer programs, computer program products and computer-readable media regarding real-time segmentation.

Abstract: Embodiments of the present disclosure relate to a communication method, a network device and a terminal device. There is provided a communication method implemented at a network device, comprising: determining power allocation information for multiuser superposition transmission, the power allocation information indicating power allocation for the multiuser superposition transmission between a near terminal device and far terminal devices on one or more spatial layers; and transmitting the power allocation information to the near terminal device dynamically. There is also provided a communication method implemented at a terminal device, as well as corresponding network device and terminal device.

Abstract: An optical receiver capable of substantially measuring the phase and amplitude of a received intensity- or amplitude-modulated optical signal by performing digital-signal processing. In an example embodiment, a DSP of the receiver operates to reduce the detrimental effects of relative phase noise between the optical reference oscillator and optical carrier based on an optical pilot present in the received optical signal. The DSP may employ a sequence of digital filters configured to select a signal component that represents a non-vestigial modulation sideband and then perform signal equalization thereon. The signal equalization may include but is not limited to dispersion compensation. In some embodiments, the optical receiver can be a direct-detection optical receiver. In an example embodiment, the optical reference oscillator and optical carrier are generated using two respective independently running lasers that may or may not be co-located.

Abstract: There is provided a method comprising determining a number of acknowledgment bits allocated to at least one transmit block, the at least one transmit block comprising a plurality of code blocks, allocating each of the plurality of code blocks to a respective code block group, based on the number of acknowledgment bits allocated to the at least one transmit block and the number of the plurality of code blocks, wherein each code block group is associated with one of the number of acknowledgment bits and causing transmission of the acknowledgment bit associated with each respective code block group based on a determined acknowledgement result for the respective code block group.

Abstract: A method of coordinating a communication network comprising a self-coordination network coordinator is provided, wherein the method comprises receiving dynamic context information at the self-coordination network coordinator and performing a coordination of at least one self-organising network function instance based on the received dynamic context information.

Abstract: A method of identifying IP-optical links in a network having a plurality of nodes, including: grouping network nodes into discovery groups; for each group filtering ports of the nodes in the discovery group; for each group producing class IDs for each filtered port using a machine learning model; for each group matching IP ports to optical ports from the filtered ports using the class IDs for each port to identify IP-optical links; and verifying identified IP-optical links.

Abstract: According to an aspect, there is provided a network node for performing video on demand equalization. Upon receiving downlink traffic to be transmitted to one or more terminal devices, the network node detects a VOD stream from the downlink traffic. The network node determines the number of VOD streams handled by the cell and a first traffic load and compares the number of the VOD streams and the first traffic load to a first and a second threshold. In response to the number of the VOD streams being above the first threshold or the first traffic load being above the second threshold, the network node selects a terminal device associated with one of the VOD streams, selects a target cell from available cells and schedules the terminal device to use the target cell for said one of the VOD streams.