A modular optical device having a set of optoelectronic modules that enables the device to operate, e.g., as a WDM or multichannel transceiver. In an example embodiment, the set of optoelectronic modules includes a laser module, a modulator module, and an optical-to-electrical converter module, all mounted on the same circuit board and optically and electrically connected for the intended application. Each of the optoelectronic modules comprises a respective stack of integrated circuits, at least one of which is a photonic integrated circuit (PIC). Some of the PICs may be configurable for different applications, with the configuration setup being carried out using electrical control signals and/or optical connections of the PICs. The modular structure of the device enables the manufacturer to provide customized solutions to different customers according to their respective specifications while using the same device architecture and/or to interchangeably use parts obtained from different suppliers to engineer those solutions.
G02B 6/12 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
G02B 6/126 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind using polarisation effects
An apparatus may implement an ad hoc service switch to establish an ad hoc link between ad hoc devices, such that the apparatus is a transparent node in an ad hoc link between the ad hoc devices. The apparatus may implement rule-based control of at least one ad hoc device, based on processing a data packet received from an ad hoc device via the ad hoc link. Rule-based control may include performing at least one operation of selectively forwarding the data packet, selectively inhibiting the data packet from being forwarded, modifying the data packet, and generating and transmitting a new data packet. The apparatus may establish the ad hoc link via an initial ad hoc link between the apparatus and the first device, a network communication link between the apparatus and an external apparatus, and an ad hoc link between the external apparatus and the second device.
H04W 40/22 - Communication route or path selection, e.g. power-based or shortest path routing using selective relaying for reaching a BTS [Base Transceiver Station] or an access point
3.
METHOD AND APPARATUSES FOR PROVIDING TRANSFER BLOCK INDICATION IN UPLINK GRANT-FREE TRANSMISSIONS
A system, apparatus, method, and/or non-transitory computer readable medium for providing transfer block indications in uplink (UL) grant-free transmissions may include a memory having computer readable instructions stored thereon, and at least one processor configured to execute the computer readable instructions to transmit a first transport block (TB) to a base station (BS) (120, 122) during a first transmission time interval (ΤΤI) using a grant-free UL transmission (210, 250), receive a UL grant (220, 260) from the BS in a physical downlink control channel (PDCCH) region during a time window, determine a target of the UL grant, the target including at least one of the first TB, a second TB, or a previously transmitted TB, based on the UL grant, and transmitting the target of the UL grant to the BS.
A first network function in a communication system receives a policy that defines a rule to be enforced for users of the communication system in response to a set of conditions being satisfied. The first network function evaluates a first subset of the set of conditions and provides, in response to the first subset of the set of conditions being satisfied, information to configure a second network function to evaluate a partial policy decision that indicates that the rule is to be enforced in response to a second subset of the set of conditions being satisfied. The second network function evaluates the second subset of the set of conditions and provides information to configure an enforcement point to enforce the rule in response to the second subset of the set of conditions being satisfied.
Techniques are provided for protecting the privacy of user equipment during paging operations in a communication system. A method includes determining (600) at a mobility management element of a communication system that a paging operation is to be initiated for given user equipment. The method further includes restricting (602) the paging operation between the mobility management element and the given user equipment to use of a temporary identifier for the given user equipment. By not using a permanent identifier of the given user equipment during paging operations, the given user equipment is effectively non-trackable by malicious base stations and active/passive listeners.
User equipment (UE) and a network node may establish data radio bearers (DRBs) for wireless communication of user plane data. For each DRB, the UE and network node may signal static or dynamic integrity protection for the user plane data during set-up of the DRB. When the DRB has static integrity protection, integrity protection is applied to the user plane data for a duration of the DRB. When the DRB has dynamic integrity protection, the UE and network node establish one or more trigger conditions for dynamic integrity protection of the DRB. The integrity protection may be enabled upon detection of one or more trigger conditions and disabled when the one or more trigger conditions subside after a predetermined period of time.
An apparatus, including: an optical sensor fiber having a first end optically couplable to receive light from a light source, wherein the optical sensor fiber is a multimode optical fiber configured to carry light in different spatial propagating modes, wherein the optical sensor fiber is constructed such that environmental fluctuations couple light energy between some of the spatial propagating modes: a spatial propagating mode demultiplexer optically coupled to a second end the optical sensor fiber and configured to separate a plurality of light signals received from different ones of the spatial propagating modes; and an optical receiver configured to process the separated light signals and to estimate a longitudinal position of one of the environmental fluctuations along the optical sensor fiber based a measured delay between arrival times of the separated light signals.
G01D 5/353 - Mechanical means for transferring the output of a sensing memberMeans for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for convertingTransducers not specially adapted for a specific variable using optical means, i.e. using infrared, visible or ultraviolet light with attenuation or whole or partial obturation of beams of light the beams of light being detected by photocells influencing the transmission properties of an optical fibre
8.
OPTICAL DATA MODULATORS WITH FEEDBACK WAVELENGTH CONTROL
An apparatus includes an optical data modulator, an electrical timer located to control an operating wavelength of the optical data modulator, a photo- sensitive diode or photo- sensitive transistor, and an electronic feedback controller. The photo-sensitive diode or photo-sensitive transistor is connected to receive light from an optical output of the optical data modulator and is configured to output an electrical signal representative of a measured intensity of said received light. The electronic feedback controller is connected to receive the electrical signal from the optical intensity detector and to operate said electrical tuner based on an alternating current component of said measured intensity.
In one example embodiment, a first network element includes a memory storing computer-readable instructions and at least one processor configured to execute the computer-readable instructions to cause the first network element to, obtain user equipment (UE)-side parameter values from a user domain of the UE, convert a first data stream received from a second network element into multiple second data streams over multiple data communication paths between the UE and the first network element and allocate the multiple second data streams to at least one of the multiple data communication paths based on the UE-side parameter values.
The present disclosure generally discloses improvements in computer performance for supporting troubleshooting in a remote management service (RMS) based on an RMS troubleshooting capability. The RMS troubleshooting capability may be configured to enable troubleshooting within the context of an RMS configured to support remote management of a managed device(s) by a managing device(s). The RMS troubleshooting capability may be configured to support troubleshooting for an RMS by isolating traffic of managed devices for which troubleshooting is not being performed (e.g., which traffic is directed to managing devices of the RMS) from traffic of managed devices for which troubleshooting is being performed (e.g., which traffic is directed to troubleshooting devices of the RMS). The RMS troubleshooting capability may be configured to support troubleshooting for an RMS by directing traffic of a managed device to a troubleshooting server, rather than to a managing device (e.g., a device management server), under various conditions.
The present disclosure generally discloses improvements in computer performance for supporting automatic recovery for a remote management service (RMS) based on an RMS automatic recovery capability. The RMS automatic recovery capability may be configured to support automatic recovery for an RMS by supporting automatic recovery for a managed device that is experiencing a device authentication failure. The RMS automatic recovery capability may be configured to support automatic recovery for an RMS based on configuration of a load balancer of the RMS to recognize an authentication failure of a managed device and to trigger the managed device to enter a bootstrap process based on recognition of the authentication failure of the managed device. The RMS automatic recovery capability may be configured to support automatic recovery for an RMS based on configuration of a managed device to initiate a bootstrap process based on an indication from a load balancer of the RMS.
The present disclosure generally discloses improvements in computer performance for supporting a multipath transport throughput capability that is configured to improve throughout of a multipath transport connection of a multipath transport protocol. The multipath transport throughput capability is configured to improve the throughput of the multipath transport connection by improving delivery of acknowledgment packets acknowledging successful delivery of data packets sent from a data transmitting side to a data receiving side. The multipath transport throughput capability may be configured to improve the delivery of acknowledgment packets from the data receiving side to the data transmitting side by, for a data packet that is successfully received at the data receiving side from the data transmitting side, sending multiple acknowledgment packets from the data receiving side to the data transmitting side where the multiple acknowledgment packets associated with the received data packet may be sent over multiple transport connections of the multipath transport connection.
A DATA PROCESSING APPARATUS CONFIGURED TO RECOVER A NETWORK CONNECTION, A METHOD, A SYSTEM AND A NON-TRANSITORY COMPUTER READABLE MEDIUM CONFIGURED TO PERFORM SAME
In at least some example embodiments, a data processing apparatus is configured to recover a network connection within an application framework that hides sockets by separating acquisition and processing into different threads of the same process, and, thus, when the processing thread is unable to retrieve a frame from the acquisition thread, the data processing device may terminate the acquisition thread with impunity since all important application state may safely remain within the processing thread.
The present disclosure generally discloses improvements in computer performance for delivery of content via a wireless communication network. The present disclosure generally discloses improvements in computer performance for delivery of content to wireless end devices via a wireless communication network using unicast services and multicast-broadcast services of the wireless communication network based on a service switching capability configured to support dynamic and opportunistic switching between the unicast services and multicast-broadcast services of the wireless communication network. The service switching capability may be configured to support dynamic and opportunistic switching between use of unicast service and use of multicast-broadcast service for a content item on a serving cell based on a number of wireless end devices on the serving cell that are receiving or requesting the content item.
An optoelectronic circuit (100) having a substantially planar double- sided substrate (106), each side of which has a respective plurality of electrically conducting tracks and a respective plurality of planar optical waveguides. The substrate also has at least one via (170) crossing the substrate (106) in a manner that can be used to establish an optical path across the substrate (106), e.g., between optical waveguides located on different sides thereof. In an example embodiment, the electrically conducting tracks and planar optical waveguides are configured to operatively connect various optoelectronic devices (144) and auxiliary electrical circuits >(148) attached to the two sides of the substrate (106) using hybrid- integration technologies. In some embodiments, two or more of such double-sided substrates (106) can be stacked and optically and electrically interconnected to create an integrated three-dimensional assembly.
G02B 6/12 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
G02B 6/43 - Arrangements comprising a plurality of opto-electronic elements and associated optical interconnections
16.
SYSTEM AND METHOD FOR SESSION ESTABLISHMENT BY UNAUTHENTICATED USER EQUIPMENT
An authentication server establishes a network connection to user equipment (UE) in a non-3GPP compliant access network. The authentication server obtains an identity for the UE and determines that the UE is unauthenticated and requesting establishment through a non-3 GPP compliant access network. The authentication server negotiates a connection mode with the unauthenticated UE and negotiates connection parameters for the connection mode with the unauthenticated UE. The authentication server may then establish a network connection through the non-3 GPP compliant access network to the UE.
A mobility management entity (MME) is configured to perform cell redirection or Circuit- Switched fallback with security protocols. The MME receives an initial connection message from user equipment (UE) in an idle mode with a service request for a voice call. The MME and UE first perform an authentication procedure with the UE prior to processing of the service request by the MME. The MME generate a cell redirection command with integrity protection using an integrity key established during the authentication procedure. The MME transmits the cell redirection command with integrity protection in the payload of a signaling message to the UE. The MME may also transmit the UE its policy of security protected cell redirection in an initial attach message to the network or with a tracking area update message.
A neutral host network is configured to provide services supported by any one or more of multiple Participating Service Providers (PSPs) to user equipment in an unlicensed frequency band. The neutral host network includes a neutral host gateway configured for communication with at least one external network, a mobility management entity (MME), and a local authentication, authorization, and accounting (AAA) server configured to determine that a session involving the user equipment is to be detached from the neutral host network. The local AAA server is also configured to transmit, to the neutral host gateway, a first message to initiate session detach of the session involving the user equipment. The neutral host gateway can be configured to transmit a second message to the MME in response to receiving the first message. The MME is configured to perform session detach for the session in response to receiving the second message.
An image acquisition device compresses a media signal representative of a scene based on a sensing matrix that is a determined by a sensing matrix template and a set of template parameters. The image acquisition device provides the compressed media signal to a receiver and selectively provides a specification of a subset of the set of template parameters to the receiver. The receiver extracts one or more scene descriptors representative of one or more portions of the scene from the compressed media signal using the sensing matrix template without knowledge of the template parameters that are not included in the subset. The template parameters that are not included in the subset are not received by the receiver.
The present disclosure generally discloses improvements in computer performance in service providing architectures, including deployment of services in service providing architectures using edge resource sharing. The improvements to computer performance in deployment of services in service providing architectures using edge resource sharing may be based on edge resource sharing capabilities which may be configured to support deployment of services in service providing architectures using edge resource sharing. The edge resource sharing capabilities may be configured to enable an infrastructure provider device of an infrastructure provider to facilitate sharing of edge device resources of edge devices of an edge resource owner for supporting services of a service provider that offers services to customers.
An encoder determines a compression ratio for compressive sensing and a quantization level used to quantize a media signal based on a target indicator. The encoder accesses compressive sensing measurements performed using the compression ratio and quantizes the compressive sensing measurements based on the quantization level. A decoder receives a compressed signal generated from the signal acquired by the signal acquisition device using the compression ratio and the quantization level. The decoder also receives information indicating the compression ratio or the quantization level. T he decoder decompresses the compressed signal based on the compression ratio and the quantization level.
H03M 7/30 - CompressionExpansionSuppression of unnecessary data, e.g. redundancy reduction
H04N 19/132 - Sampling, masking or truncation of coding units, e.g. adaptive resampling, frame skipping, frame interpolation or high-frequency transform coefficient masking
H04N 19/172 - Methods or arrangements for coding, decoding, compressing or decompressing digital video signals using adaptive coding characterised by the coding unit, i.e. the structural portion or semantic portion of the video signal being the object or the subject of the adaptive coding the unit being an image region, e.g. an object the region being a picture, frame or field
H04N 19/146 - Data rate or code amount at the encoder output
H04N 19/154 - Measured or subjectively estimated visual quality after decoding, e.g. measurement of distortion
Various embodiments relate to a network monitor and method thereof for receiving a plurality of alarms during a baseline period from a plurality of network elements, establishing a baseline for at least one of the plurality of the network elements by determining a number of the plurality of alarms during the baseline period that occur during each of a plurality of sub-intervals within the baseline period, calculating a mean arrival rate for each of the plurality of alarms during the baseline period, generating a probability density function for an arrival rate for each of the plurality of alarms during the baseline period, calculating a probabilistic score for each of a plurality of alarms during a test period based on the probability density function for the arrival rate of each of the plurality of alarms during the baseline period, determining if the score for each of the plurality of alarms during the test period is greater than or equal to a probabilistic threshold, summing the number of the scores for each of the plurality of alarms during the test period that is greater than or equal to probabilistic threshold, generating a list by sorting the plurality of network elements in descending order based on the sum of the number of the scores for each of the plurality of alarms that generated a probabilistic score greater than or equal to probabilistic threshold or based on a sum of the probabilistic scores that are greater than or equal to probabilistic threshold, reporting first network elements of the generated list and reporting alarms for the first network elements of the generated list having probabilistic scores higher than the probabilistic threshold.
An apparatus includes first and second light sources, an optical interferometer, one or more light detectors, and an electronic processor. The second light source is configured to output light of a different wavelength than the first source. The optical interferometer has optical reference and sample arms. The optical sample arm has a first optical path to transmit light received from the first and second light sources to an area of a target and has a second optical path to transmit light collected from the area of the target to one or more interference regions. The optical reference arm is configured to transmit light received from the first light source to the one or more interference regions. Each light detector is configured to produce electrical signals indicative of measured intensities of interfered light in a corresponding one of the one or more interference regions. The electronic processor is configured to determine, from the electrical signals, information indicative of a depth dependence of stimulated Raman optical emission in the area of the target.
Systems and methods for charging in networks where radio resources are shared between Machine Type Communication (MTC) traffic and legacy traffic. A base station of a wireless access network determines a scheduling of radio resources on the air interface between MTC traffic and legacy traffic, and provides signaling to an MTC device and a legacy device indicating the scheduling of the radio resources. The base station collects resource sharing information regarding the sharing of the radio resources between the MTC traffic and the legacy traffic, and transmits a message to a network element of a core network that includes the resource sharing information. The network element may then forward the resource sharing information to a charging system so that the sharing of the radio resources is taken into account when charging the MTC device and/or the legacy device for usage of the air interface.
The present disclosure provides systems and methods that are configured for feature extraction or object recognition using compressive measurements that represent a compressed image of a scene. In various aspects, a compressive sensing matrix is constructed and used to acquire the compressive measurements, such that in the extraction phase, the compressive measurements can be processed to detect feature points and determine their feature vectors in the scene without using a pixel representation of the scene. The determined feature vectors are used to detect objects based on comparison with one or more predetermined feature vectors.
An electrical system comprising a circuit of reconfigurable electrical devices and a controller including a processor. The processor has a configuration examiner and a state modifier. The configuration examiner is configured to determine a configuration for the circuit of reconfigurable electrical devices based upon a connection input. The state modifier is configured to modify, based on the configuration, the circuit by changing a resistance state of the reconfigurable electrical devices. A controller for reconfigurable electrical devices and a method of controlling reconfigurable electrical devices of a circuit are also described.
H03K 19/177 - Logic circuits, i.e. having at least two inputs acting on one outputInverting circuits using specified components using elementary logic circuits as components arranged in matrix form
H03K 19/094 - Logic circuits, i.e. having at least two inputs acting on one outputInverting circuits using specified components using semiconductor devices using field-effect transistors
27.
RECONFIGURABLE INTEGRATED CIRCUIT AND OPERATING PRINCIPLE
An electrical device comprising a reconfigurable integrated circuit that includes paired top electrodes and bottom electrodes separated from each other by an active layer.
H01L 27/105 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including integrated passive circuit elements with at least one potential-jump barrier or surface barrier the substrate being a semiconductor body including a plurality of individual components in a repetitive configuration including field-effect components
H01L 27/24 - Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including solid state components for rectifying, amplifying, or switching without a potential-jump barrier or surface barrier
An application layer monitoring module is configured to monitor application layer packets for a call supported by a voice application and to detect an interruption in the call based on the application layer packets. A signaling layer monitoring module is configured to monitor signaling layer events associated with the voice application concurrently with monitoring of the application layer packets for the call. A correlation module is configured to correlate the interruption with the signaling layer events in response to the application layer monitoring module detecting the interruption. The correlation module is also configured to generate a key performance indicator (KPI) message including information indicating the interruption and at least one signaling layer event that is correlated with the interruption.
We disclose various embodiments that enable a mobile terminal to authenticate a base station before the mobile terminal proceeds to attach to the corresponding network and/or camp on the corresponding cell, e.g., during the initial network selection and attachment or during an idle mode. In an example embodiment, the authentication processing includes the mobile terminal generating and sending to a candidate base station a system query with a nonce. The candidate base station is deemed to be authentic only if the acknowledgement generated and transmitted in response to the system query includes a copy of the nonce properly signed by a digital signature generated using one or more security keys. In some embodiments, the system query may also include a request for GPS coordinates and/or selected system information signed using a digital signature, which the mobile terminal may beneficially use to further strengthen the protection against a spoofing attack.
The method includes generating a preamble sequence at a transmitter, where the transmitter is capable of generating a first type of preamble sequence and a second type of preamble sequence. The transmitter transmits a request message to a receiver to request network resources, where the request message including the preamble sequence. The transmitter receives a feedback message from the receiver. The transmitter controls the network data traffic based on the feedback message. The method further includes receiving, a receiver, a signal from the transmitter, the signal including the preamble sequence. The receiver detects the preamble sequence within the signal, where the receiver is capable of detecting a first type of preamble sequence and a second type of preamble sequence. The receiver identifies a request message within the signal based on the detected preamble sequence, and controls the network data traffic based on the identified request message.
A plurality of lighting elements is configured to selectively illuminate a scene during a plurality of time intervals. The plurality of lighting elements forms a different illumination pattern in each of the plurality of time intervals. One or more sensors are configured to measure a plurality of intensities of light received from the scene during the plurality of time intervals. A processor is configured to generate an image of the scene based on the plurality of intensities. In some cases, the plurality of lighting elements are switched on or off to produce different illumination patterns during a plurality of time intervals that too short to be perceptible to the human eye.
An apparatus includes an optical data modulator, an electrical tuner located to control an operating wavelength of the optical data modulator, a photo-sensitive diode or photo-sensitive transistor, and an electronic feedback controller. The photo-sensitive diode or photo-sensitive transistor is connected to receive light from an optical output of the optical data modulator and is configured to output an electrical signal representative of a measured intensity of said received light. The electronic feedback controller is connected to receive the electrical signal from the optical intensity detector and to operate said electrical tuner based on an alternating current component of said measured intensity.
H04B 10/00 - Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
The present disclosure generally discloses a scheduling control capability for controlling scheduling of transmissions where adaptive bitrate streaming is used for delivery of content (e.g., video content or other types of content which may be streamed using adaptive bitrate streaming) from source devices to end devices. The scheduling control capability may be configured to control scheduling of transmissions of adaptive bitrate streaming flows based on priority levels assigned to the adaptive bitrate streaming flows. The scheduling control capability may be configured to dynamically control the priority levels assigned to the adaptive bitrate streaming flows. The scheduling control capability may be configured to dynamically control the priority levels assigned to the adaptive bitrate streaming flows, for use in controlling the scheduling of transmissions of the adaptive bitrate streaming flows, in manner for improving user quality-of-experience, in a manner for improving spectral efficiency, or the like, as well as various combinations thereof.
Dynamic control of the length of time that an RRC connection exists is implemented based on the known and anticipated data needs of the UE. More specifically, the lifetime of the RRC connection may be a) initially set, b) extended, or c) shortened, even to the point of substantially immediately releasing it, based on the expected data transmission needs of the UE. This dynamic control is implemented by elements of the core network which are aware of the known and anticipated data needs of the UE. The UE needs are a function of the applications running on the UE. In one LTE-based embodiment, the RRC release timer is responsive to the Policy and Charging Rules Function (PCRF), which can access information about the applications that are running at the UE. In another embodiment, the RRC release timer is responsive to the Policy and Charging Enforcement Function (PCEF).
The present disclosure generally discloses packet processing offload support capabilities for supporting packet processing offload. The packet processing offload support capabilities may be configured to support general and flexible packet processing offload at an end host by leveraging a processing device (e.g., a smart network interface card (sNIC) or other suitable processing device) added to the end host to support offloading of various packet processing functions from the hypervisor of the end host to the processing device added to the end host. The packet processing offload support capabilities may be configured to support packet processing offload by including, within the end host, a visualization switch and a packet processing offload agent which may be configured to cooperate to transparently offload at least a portion of the packet processing functions of the end host from the hypervisor of the end host to an sNIC of the end host while keeping the existing management plane and control plane interfaces of the data center unmodified.
The present disclosure generally discloses multicast communication support capabilities configured to support multicast communications of a multicast group using a multicast tree. The multicast communication support capabilities may include a unicast branching based multicast capability. The unicast branching based multicast capability may be configured to support determination and establishment of, as well as communication via, a multicast tree that is composed of unicast branches. The unicast branching based multicast capability may be configured to preserve the multicast information of multicast transmissions transported via the multicast tree even though the multicast transmissions are transported via unicast branches of the multicast tree. The unicast branching based multicast capability may be configured to preserve the multicast information of multicast transmissions transported via unicast branches of the multicast tree based on encoding of the multicast information within the packets of the multicast transmission being transported via the unicast branches of the multicast tree.
A server receives signals indicating an alert condition for a location that is defined by a set of location attributes and Identifies one or more base stations that serve one or more cells that overlap with the location, which encompasses less than ail of the cells. The server transmits a message to the one or more base stations identifying the alert condition and including the set of location attributes. A user equipment receives the message identifying the alert condition and including the set of location attributes that define the location of the alert condition. The user equipment compares a location of the user equipment to the set of location attributes and generates an alert in response to the location of the user equipment being within the location of the alert condition.
Systems, methods, and software for implementing a software upgrade in a virtualized Offline Charging System (OFCS) that includes a pool of Virtualized Charging Collection Functions (vCCF). In one embodiment, a software upgrade is identified for the virtualized OFCS, and installed with an upgrade process. The upgrade process includes developing a skeletal vCCF, installing the software upgrade in the skeletal vCCF, and communicating with a DNS server to modify the priority in a DNS resource record for the skeletal vCCF to equal at least one of the other vCCFs. The upgrade process includes designating an antiquated vCCF in the pool as the (next) skeletal vCCF, draining the accounting sessions from the skeletal vCCF, and communicating with the DNS server to set a priority in the DNS resource record for the skeletal vCCF so that the skeletal vCCF is selected last by the CTFs for accounting sessions.
Systems and methods are provided for ranking electronic information based on determined similarities. In one aspect a set of unique features are determined from a collection of electronic objects. A graph is constructed in which electronic object are represented as object nodes and determined features are represented as feature nodes. The object nodes are interconnected by a weighted edge to at least one feature node. Scores for the object nodes and the feature nodes are computed using a determined set of anchor nodes and a determined weighted adjacency matrix. The object nodes and the feature nodes of the graph are ranked and displayed based on the computed scores. In one aspect, the scores and the ranks for the object nodes and the feature nodes are dynamically updated and displayed based on user preferences.
We disclose a shaping encoder configured to use a variable-length shaping code to implement fixed-input fixed-output (FIFO) probabilistic signal shaping. In various embodiments, the variable-length shaping code can be a variable-input fixed-output code, a fixed-input variable- output code, or a variable-input variable-output code. The FIFO functionality of the shaping encoder is enabled by a control circuit that operates to: (i) check an output-overflow condition for each bit-word to be encoded using the variable-length shaping code and (ii) switch the shaping encoder from using the variable-length shaping code to using a suitable FIFO code if the output-overflow condition is satisfied. Some embodiments of the shaping encoder can incorporate a conventional FEC encoder in a manner that substantially preserves the shaping gain realized by the shaping encoder.
The present disclosure generally discloses a congestion control capability for use in communication systems (e.g., to provide congestion control over wireless links in wireless systems, over wireline links in wireline systems, and so forth). The congestion control capability may be configured to provide congestion control for a transport flow of a transport connection, sent from a transport flow sender to a transport flow receiver, based on flow control associated with the transport flow. The transport flow may traverse a flow queue of a link buffer of a link endpoint. The link endpoint may provide to the transport flow sender, via an off-band signaling channel, an indication of the saturation state of the flow queue of the transport flow. The transport flow sender may control transmission of packets of the transport flow based on the indication of the saturation state of the flow queue of the transport flow.
In one example embodiment, a method includes obtaining a duration of a first network element scanning period of a first network element for a plurality of first beacons, the plurality of first beacons associated with the different direct energy beams, scanning for the plurality of first beacons over a second network element scanning period of a second network element, the second network element scanning period including a number of first network element scanning periods, the first network element scanning period being part of the number of the first network element scanning periods, receiving at least one of the plurality of first beacons during the number of the first network element scanning periods, determining a preferred first beacon based on the received at least one of the plurality of first beacons and transmitting an indication of the preferred first beacon to a base station.
H04B 7/0408 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas using two or more beams, i.e. beam diversity
H04B 7/06 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
In one example embodiment, a method includes transmitting a plurality of first beacons over a first scanning period, the plurality of first beacons associated with different direct energy beams, the transmitting including, transmitting the plurality of first beacons over sub-periods of the first scanning period, respectively; obtaining an indication of a preferred first beacon, the preferred beacon being received by a network element during the transmitting of the plurality of beacons over the first scanning period; and communicating with the element during a scheduled portion of a first data communication period using the beam associated with the preferred first beacon, a length of the first scanning period and a length of the first data communication period forming a length of a time transmission interval.
H04B 7/0408 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas using two or more beams, i.e. beam diversity
H04B 7/06 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
44.
ROUTING PARENT AND CHILD DEVICE CALLS THROUGH A PARENT TELEPHONY APPLICATION SERVER
A first invite message including a parent device identifier assigned to a parent device is received. The first invite message refers to an incoming call or an outgoing call. The incoming call or the outgoing call are then routed between a parent telephony application server (TAS) allocated to the parent device and a child TAS allocated to a child device. In some cases, the child device is a mobile child device that is registered with an Internet Protocol (IP) multimedia subsystem (IMS) network using a unique identifier that is associated with a child device identifier assigned to the mobile child device. The parent TAS is able to store the child device identifier and the child TAS is able to store the parent device identifier.
Various embodiments relate to a system and method for performing programmable native analytics on a 5G mobile network, the system comprising a plurality of programmable native analytics agents configured to produce data digests by reducing, aggregating and binning source data, and a central analytics engine configured to collect the data digests from each of the plurality of programmable native analytics agents wherein the central analytics engine includes a plurality of enginelets which are configured to perform analytics on the data digests received by the central analytics engine.
A first gateway (P-GW, 355) receives, from a source user equipment, (315) an uplink packet addressed to a target user equipment (320) and identifies a pairing between the source user equipment (315) and the target user equipment (320). The first gateway (355) routes the received uplink packet to the target user equipment directly through a second P-GW (370) bypassing Internet.
In one example embodiment, a method includes transmitting a plurality of first beacons over a first scanning period, the plurality of first beacons associated with different direct energy beams, the transmitting including, transmitting the plurality of first beacons over sub-periods of the first scanning period, respectively; obtaining an indication of a preferred first beacon, the preferred beacon being received by a network element during the transmitting of the plurality of beacons over the first scanning period; and communicating with the element during a scheduled portion of a first data communication period using the beam associated with the preferred first beacon, a length of the first scanning period and a length of the first data communication period forming a length of a time transmission interval.
H04B 7/0408 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas using two or more beams, i.e. beam diversity
H04B 7/06 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
48.
SYSTEM AND METHOD FOR CORRELATION-AWARE CACHE-AIDED CODED MULTICAST (CA-CACM)
Requests are received from destination devices for files of a plurality of data files, each of the requested files including at least one file-packet. A conflict graph is built using popularity information and a joint probability distribution of the plurality of date files. The conflict graph is colored. A coded multicast is computed using the colored conflict graph. A corresponding unicast refinement is computed using the colored conflict graph and the joint probability distribution of the plurality of data files. The coded multicast and the corresponding unicast is concatenated. The requested files are transmitted to respective destination devices of the plurality of destination devices.
H04L 29/06 - Communication control; Communication processing characterised by a protocol
H04L 29/08 - Transmission control procedure, e.g. data link level control procedure
H04W 4/06 - Selective distribution of broadcast services, e.g. multimedia broadcast multicast service [MBMS]Services to user groupsOne-way selective calling services
49.
SYSTEMS AND METHODS FOR DECOUPLING CONTROL AND DATA CHANNELS IN WIRELESS NETWORKS
The downlink control and uplink data channels between wireless user equipment and a wireless cell site are decoupled, allowing the user equipment to send data payloads to a second cell site via a different uplink data channel that provides greater throughput and/or a higher quality-of-experience for a user of the user equipment.
An identifier of a mobile session is generated for a mobile device accessing a network operating in an unlicensed radio band (e.g., Neutral Host Network). Generation of at least one part of the identifier comprises generating a random binary value, converting the random binary value into a decimal value, and truncating the decimal value to a number of decimal digits consistent with an identifier recognizable by a network operating in a licensed radio band (e.g., 3GPP Evolved Packet Core).
A first identifier of a mobile session is generated for a mobile device accessing a network operating in an unlicensed radio band, wherein at least one part of the first mobile session identifier comprises a decimal format consistent with an identifier recognizable by a network operating in a licensed radio band. The first mobile session identifier is compared to one or more previously generated mobile session identifiers currently allocated in the unlicensed radio band network to prevent collision there between.
H04W 8/02 - Processing of mobility data, e.g. registration information at HLR [Home Location Register] or VLR [Visitor Location Register]Transfer of mobility data, e.g. between HLR, VLR or external networks
The efficiency of uplink data channels provided by a wireless cell is increased by using offset scheduling grants to control the transmission of data payloads from user equipment to the cell.
We disclose a transceiver module having two optical transceivers, each connectable to a different respective optical line, and a pluggable electrical connector that can be mated with a matching electrical connector in a connection slot of the host network device. The transceiver module also has an electrical interface circuit that can transfer data between the optical transceivers and the host network device in a manner that provides a route for transferring data between two optical transceivers without crossing the electrical connectors. This architecture advantageously enables the optical-line rates to not be limited by the electrical data rate of data transfer through the electrical connectors. In some embodiments, the transceiver module is configurable in a manner that can change the optical-line rates of the optical transceivers and/or the electrical data rate. The latter feature enables the transceiver module to be compatible with both older and newer network devices.
H04B 10/00 - Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
H04B 10/80 - Optical aspects relating to the use of optical transmission for specific applications, not provided for in groups , e.g. optical power feeding or optical transmission through water
H04Q 11/00 - Selecting arrangements for multiplex systems
H04J 14/02 - Wavelength-division multiplex systems
An apparatus comprising an optical filter located on a substrate. The optical filter including an optical splitter configured to receive an input light and an interferometer having two waveguide arms having different optical path-lengths from each other. The waveguide arms configured to receive the input light from the optical splitter. At least a portion of one of the two waveguide arms has a narrower core width than a wider core width of the other waveguide arm. The waveguide arm with the longest waveguide portion having the narrower core width has the longest total physical path-length of the two waveguide arms. At least one of the two waveguide arms having a set of discrete waveguide portions, the discrete waveguide portions of the set being connected by optical switches which are configured to tunably select from a plurality of different physical path-lengths through the discrete waveguide portions of the at least one waveguide arm.
G02B 6/12 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
A manner of managing UE (user equipment) access to a core network via an access network. The access network may be a trusted or un-trusted network according to 3GPP protocols, and the core network may be or include an EPC. When a UE attempts access, a gateway node determines whether the UE will be authorized and responds accordingly. At least when the UE access request is rejected, a response is sent containing a backoff timer value. The backoff timer value may be based on, for example, the cause of the rejection or the number of attempts made by that UE or both. When the UE receives the response, the UE sets a backoff timer accordingly and preferably does not reattempt access until the backoff timer has expired. In some instances, the UE may be permitted to reattempt access immediately; in others, the UE may be directed not to reattempt access at all.
A central node may include a processor configured to empirically compute an approximation of power coefficients based on estimates of the channel coefficients such that a same one of the approximation of the power coefficient is assigned to each of a plurality of access terminals (ATs), and transmit components of a signal vector to associated access points (APs), the signal vector being based on at least the approximation of the power coefficient.
H04B 7/06 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
H04B 7/0456 - Selection of precoding matrices or codebooks, e.g. using matrices for antenna weighting
H04W 72/02 - Selection of wireless resources by user or terminal
57.
AN APPARATUS CONFIGURED TO APPROXIMATE A POWER COEFFICIENT IN A CELL-FREE MASSIVE MIMO WIRELESS SYSTEM AND METHOD OF PERFORMING SAME
A central node may include a processor configured to empirically compute an approximation of power coefficients based on estimates of the channel coefficients such that a same one of the approximation of the power coefficient is assigned to each of a plurality of access terminals (ATs), and transmit components of a signal vector to associated access points (APs), the signal vector being based on at least the approximation of the power coefficient.
H04B 7/024 - Co-operative use of antennas at several sites, e.g. in co-ordinated multipoint or co-operative multiple-input multiple-output [MIMO] systems
H04B 7/06 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
58.
Video-based measurement of round-trip latency from user input event to corresponding video output
An apparatus in one embodiment comprises a client device configured to communicate with a remote system over a network. The client device comprises a processor, a memory, an input device and a display. The client device is configured to detect an input event generated at the input device, to store in the memory a local time associated with the input event, and to transmit information characterizing the input event to the remote system over the network. The client device is configured to receive from the remote system a video signal comprising an event index of the input event. An event index is extracted from the video signal, and a round-trip latency is computed between the input event and a corresponding video output of the client device based at least in part on a local time associated with the extracted event index and the stored local time associated with the input event.
H04N 21/60 - Network structure or processes for video distribution between server and client or between remote clientsControl signalling between clients, server and network componentsTransmission of management data between server and clientCommunication details between server and client
H04N 21/63 - Control signaling between client, server and network componentsNetwork processes for video distribution between server and clients, e.g. transmitting basic layer and enhancement layers over different transmission paths, setting up a peer-to-peer communication via Internet between remote STB'sCommunication protocolsAddressing
H04N 21/647 - Control signaling between network components and server or clientsNetwork processes for video distribution between server and clients, e.g. controlling the quality of the video stream, by dropping packets, protecting content from unauthorised alteration within the network, monitoring of network load or bridging between two different networks, e.g. between IP and wireless
H04N 21/24 - Monitoring of processes or resources, e.g. monitoring of server load, available bandwidth or upstream requests
H04N 21/422 - Input-only peripherals, e.g. global positioning system [GPS]
H04N 21/442 - Monitoring of processes or resources, e.g. detecting the failure of a recording device, monitoring the downstream bandwidth, the number of times a movie has been viewed or the storage space available from the internal hard disk
H04N 21/433 - Content storage operation, e.g. storage operation in response to a pause request or caching operations
H04N 21/437 - Interfacing the upstream path of the transmission network, e.g. for transmitting client requests to a VOD server
H04N 21/239 - Interfacing the upstream path of the transmission network, e.g. prioritizing client requests
H04N 21/235 - Processing of additional data, e.g. scrambling of additional data or processing content descriptors
59.
Processing handovers for mobile terminals capable of interference cancellation
We disclose various embodiments of methods and apparatus for processing handovers of mobile terminals between base stations of a wireless communication system. An example handover algorithm used for this purpose enables the handover threshold to be increased for some mobile terminals, on a terminal-by-terminal basis, thereby individually expanding the range of the serving cell for each of such terminals. In an example embodiment, the handover-threshold determination is carried out based on physical-resource-block usage of the target cell. The extent of the cell-range expansion depends on whether or not the reference signals of the serving and target cells interfere with each other. Embodiments of the disclosed handover algorithm can advantageously reduce the number of failed handovers by allowing some communication sessions to run to completion before a handover is triggered.
H04W 36/22 - Performing reselection for specific purposes for handling the traffic
H04W 52/36 - Transmission power control [TPC] using constraints in the total amount of available transmission power with a discrete range or set of values, e.g. step size, ramping or offsets
We disclose embodiments of a WDM transmitter having an in-band OTDR capability for at least a subset of the WDM channels thereof. In an example embodiment, an OTDR-enabled WDM channel of the WDM transmitter is implemented using an optical transceiver that comprises an optical transmitter and a coherent optical receiver. The optical transmitter is configured to generate a modulated optical signal by modulating a respective carrier wavelength, transmit the modulated optical signal through an optical link as a component of the corresponding WDM signal, and provide the respective carrier wavelength to the coherent optical receiver for being used therein as an optical local oscillator. The optical receiver is configured to estimate an impulse response of the optical link by coherently detecting and processing a return optical signal produced within the optical link due to distributed reflection and/or backscattering of the modulated optical signal.
H04B 10/08 - Equipment for monitoring, testing or fault measuring
H04B 10/079 - Arrangements for monitoring or testing transmission systemsArrangements for fault measurement of transmission systems using an in-service signal using measurements of the data signal
H04J 14/02 - Wavelength-division multiplex systems
H04B 10/071 - Arrangements for monitoring or testing transmission systemsArrangements for fault measurement of transmission systems using a reflected signal, e.g. using optical time domain reflectometers [OTDR]
H04B 10/25 - Arrangements specific to fibre transmission
DETERMINATION OF OFFSET BASED ON RESOURCE UTILIZATION OF TARGET CELL FOR ADJUSTING HANDOVER THRESHOLD FOR MOBILE TERMINAL CAPABLE OF INTERFERENCE CANCELLATION
We disclose various embodiments of methods and apparatus for processing handovers of mobile terminals between base stations of a wireless communication system.. An example handover algorithm used for this purpose enables the handover threshold to be increased for some mobile terminals, on a terminal-by-terminal basis, thereby individually expanding the range of the serving cell for each of such terminals, in an example embodiment, the handover-threshold determination is carried out based on physical- resource-block usage of the target cell. The extent of the cell-range expansion depends on whether or not the reference signals of the serving and target cells interfere with each other. Embodiments of the disclosed handover algorithm, can advantageously reduce the number of failed handovers by allowing some communication sessions to run to completion before a handover is triggered.
Detecting physical random access channel (RACH) preambles is accomplished by computing a correlation power profile based on received RACH preambles, where the correlation power profile values may be sorted. A weight factor is computed for each of the correlation power profile values based on a normalized RACH detection threshold. Outlier peaks of the correlation power profile values are selected based on the weight factor. The outlier peaks to the first set of RACH signatures are mapped in order to identify a user equipment (UE) that is associated with one of the received RACH preambles. Network traffic is then controlled for network communications associated with the identified UE.
Systems, methods, and software that perform, offline charging. One embodiment comprises a Charging Data Function (CDF) of an Offline Charging System (OFCS). The CDF receives accounting requests for a session from a Charging Trigger Function (CTF), and generates an incomplete Charging Data Record (CDR) for the session based on the accounting requests. The CDF identifies request identifiers (ID) assigned to the accounting requests used to generate the first incomplete CDR, and inserts the request IDs in the incomplete CDR. The CDF determines whether one or more of the accounting requests used to generate the incomplete CDR were indicated as a re -transmitted accounting request by the CTF, and inserts content information for the re-transmitted accounting request(s) in the incomplete CDR.
Systems, methods, and software that perform offline charging. One embodiment comprises a Charging Data Function (CDF) of an Offline Charging System (OFCS). The CDF receives accounting requests for a session from a Charging Trigger Function (CTF), and generates an incomplete Charging Data Record (CDR) for the session based on the accounting requests. The CDF identifies request identifiers (ID) assigned to the accounting requests used to generate the first incomplete CDR, and inserts the request IDs in the incomplete CDR. The CDF determines whether one or more of the accounting requests used to generate the incomplete CDR were indicated as a re-transmitted accounting request by the CTF, and inserts content information for the re-transmitted accounting request(s) in the incomplete CDR.
H04M 15/00 - Arrangements for metering, time-control or time-indication
H04L 29/12 - Arrangements, apparatus, circuits or systems, not covered by a single one of groups characterised by the data terminal
H04W 8/02 - Processing of mobility data, e.g. registration information at HLR [Home Location Register] or VLR [Visitor Location Register]Transfer of mobility data, e.g. between HLR, VLR or external networks
65.
SYSTEM AND METHOD OF CONTROLLING NETWORK TRAFFIC USING PREAMBLE DETECTION AND AUTOMATED OPTIMIZATION OF RANDOM ACCESS CHANNEL PARAMETERS
Detecting physical random access channel (RACH) preambles is accomplished by computing a correlation power profile based on received RACH preambles, where the correlation power profile values may be sorted. A weight factor is computed for each of the correlation power profile values based on a normalized RACH detection threshold. Outlier peaks of the correlation power profile values are selected based on the weight factor. The outlier peaks to the first set of RACH signatures are mapped in order to identify a user equipment (UE) that is associated with one of the received RACH preambles. Network traffic is then controlled for network communications associated with the identified UE.
We disclose a magnetic device having a pair of coplanar thin-film magnetic electrodes arranged on a substrate with a relatively small edge-to-edge separation. In an example embodiment, the magnetic electrodes have a substantially identical footprint that can be approximated by an ellipse, with the short axes of the ellipses being collinear and the edge-to-edge separation between the ellipses being smaller than the size of the short axis. In some embodiments, the magnetic electrodes may have relatively small tapers that extend toward each other from the ellipse edges in the constriction area between the electrodes. Some embodiments may also include an active element inserted into the gap between the tapers and electrical leads connected to the magnetic electrodes for passing electrical current through the active element. When subjected to an appropriate external magnetic field, the magnetic electrodes can advantageously be magnetized to controllably enter parallel and antiparallel magnetization states.
A coherent optical receiver that is capable of obtaining separate estimates of the I/Q phase imbalances caused by the front-end circuits of the receiver and transmitter. In an example embodiment, the receiver's I/Q imbalance is estimated using equalization coefficients of a first digital equalizer located upstream from the carrier-recovery module in the train of digital-signal processing implemented at the receiver, whereas the transmitter's I/Q imbalance is estimated using equalization coefficients of a second digital equalizer located downstream from the carrier-recovery module. The receiver DSP can then use the first estimate to carry out signal processing that reduces adverse effects of the receiver's I/Q imbalance on data recovery at the receiver. The receiver can also provide the estimate of the transmitter's I/Q phase imbalance to the transmitter, which can then perform digital signal pre-distortion directed at compensating that I/Q imbalance at the transmitter.
A distributed CATV system, that transports out-of-band signals between the cable headend and the set-top boxes is described. A video engine in the headend of the distributed CATV system converts downstream video channel RF (radio frequency) signals and downstream out-of-band RF signals respectively into video downstream packets and out-of-band downstream packets for a set of distribution nodes to transmit to the set-top boxes via CATV cables. The video engine also receives upstream packets from the distribution nodes that contain data based on upstream out-of-band RF signals transmitted by the set-top boxes via CATV cables.
The present disclosure generally discloses dynamic monitoring and management capabilities for use in wireless communication systems. The dynamic monitoring and management capabilities may be configured to support dynamic monitoring and management within various types of contexts and associated environments. The dynamic monitoring and management capabilities may include feedback collection capabilities, service qualify evaluation capabilities, parameter tuning capabilities, or the like, as well as various combinations thereof.
A novel method of operating a Distributed Cable Modem Termination System is provided. Each branch CMTS node in a distributed CMTS supports a complete CMTS system and with full-spectrum ports. One or more MAC domains are defined at each branch CMTS node. A MAC domain defined at a branch CMTS node includes only service flows of the CMs mat are connected to the branch CMTS node. Identifiers of service flows coming from a branch CMTS node are always unique, i.e., two different service flows of the branch CMTS would always have different SIDs, even if they belong to different MAC domains. On the other hand, service flows belonging to different branch CMTS nodes are free to reuse the same identifiers.
An apparatus includes a plurality of VCSELs, a master laser, one or more electrical drivers, and an optical combiner. The master laser is configured to transmit laser light to the VCSELs to optically lock wavelengths of the VCSELs. The one or more electrical drivers are connected to directly electrically modulate the VCSELs in a manner responsive to one or more digital data stream. The optical combiner is configured to combine light received from, at least, a pair of the VCSELs into an optical carrier with a substantially phase digital data modulation.
A method to extend the downstream and upstream data carrying capability of an HFC CATV system. At the neighborhood level, the CATV cable (the primary channel) is divided into different segments connected by electrically active junctions. At the junctions, each segment is also connected to a secondary data channel, such as an optical fiber or ultrahigh RF frequency (1 GHz+) secondary channel, which can carry supplemental downstream narrowcast channels and upstream channels between a plurality of such CATV cable segments. At the junctions, some CATV primary channel RF signals such as broadcast channels are passed without interference, while certain primary channel downstream narrowcast RF channels and upstream narrowcast RF channels are precisely suppressed using adaptive cancelling methods. Such adaptive cancellation methods are superior to prior art lowpass, highpass, and bandpass filtering methods because they allow for more efficient use of limited CATV primary channel RF spectrum.
An apparatus comprising an optical filter located on a substrate. The optical filter including an optical splitter configured to receive an input light and an interferometer having two waveguide arms having different optical path-lengths from each other. The waveguide arms configured to receive the input light from the optical splitter. At least a portion of one of the two waveguide arms has a narrower core width than a wider core width of the other waveguide arm. The waveguide arm with the longest waveguide portion having the narrower core width has the longest total physical path-length of the two waveguide arms. At least one of the two waveguide arms having a set of discrete waveguide portions, the discrete waveguide portions of the set being connected by optical switches which are configured to tunably select from a plurality of different physical path-lengths through the discrete waveguide portions of the at least one waveguide arm.
G02F 1/295 - Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulatingNon-linear optics for the control of the position or the direction of light beams, i.e. deflection in an optical waveguide structure
G02F 1/313 - Digital deflection devices in an optical waveguide structure
G02B 6/122 - Basic optical elements, e.g. light-guiding paths
G02B 6/13 - Integrated optical circuits characterised by the manufacturing method
G02B 6/12 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings of the optical waveguide type of the integrated circuit kind
A node in a wireless communication system includes a transceiver to receive one or more configuration parameters to configure the node for communication in an unlicensed frequency band. The node also includes a processor to implement a state machine that transitions, based on the one or more configuration parameters, between an enable state in which the node supports wireless connectivity in the unlicensed frequency band, a disable state in which the node does not support wireless connectivity in the unlicensed frequency band, and a flywheel state in which the node supports wireless connectivity in the unlicensed frequency band for a predetermined time interval before transitioning to the disable state.
Systems, methods, and software for controlling transmissions of User Equipment (UE) on an unlicensed spectrum. In one embodiment, a base station communicates with the UE through radio communications on a licensed spectrum of a carrier. The base station transmits a query to a policy control element requesting spectrum selection criteria for the UE over a direct interface. The base station receives a response from the policy control element that includes the spectrum selection criteria for the UE, and processes the spectrum selection criteria to allocate resources for transmissions involving the UE on the licensed spectrum and on the unlicensed spectrum. The base station then provides a control message including the allocated resources towards the UE to enable the UE to perform the transmissions on the unlicensed spectrum, the licensed spectrum., or a combination of the two.
A node increments values of performance measurement (PM) counters to indicate characteristics of at least one unlicensed frequency band used for wireless communication during a first time interval. The node provides the values of the PM counters to a controller that is configured to aggregate the values of the PM counters for the node with values of PM counters for other nodes. A controller receives values of PM counters from a plurality of nodes to indicate characteristics of wireless communication by each of the plurality of nodes using the at least one unlicensed frequency band over the first time interval. The controller aggregates the values of the PM counters for the plurality of nodes and modifies a configuration of at least one of the plurality of nodes based on the aggregated values.
A central node of a MIMO system may transmit, to one or more communication terminals of the MIMO system, a long-duration downlink pilot signal carrying a pilot sequence having a first duration. The first duration may be equal to or greater than a quantity of antennas of the central node. The central node may receive retransmitted long-duration downlink pilot signals from the communication terminals. The central node may further transmit, to one or more communication terminals, a short-duration downlink pilot signal carrying a pilot sequence having a second duration. The second duration may be less than or equal to the quantity of antennas. The central node may receive a retransmitted short-duration downlink pilot signal from the one or more communication terminals. An uplink and downlink between the central node and one or more communication terminals may be estimated based on the received signals.
A node increments values of performance measurement (PM) counters to indicate characteristics of at least one unlicensed frequency band used for wireless communication during a first time interval. The node provides the values of the PM counters to a controller that is configured to aggregate the values of the PM counters for the node with values of PM counters for other nodes. A controller receives values of PM counters from a plurality of nodes to indicate characteristics of wireless communication by each of the plurality of nodes using the at least one unlicensed frequency band over the first time interval. The controller aggregates the values of the PM counters for the plurality of nodes and modifies a configuration of at least one of the plurality of nodes based on the aggregated values.
A node in a wireless communication system includes a transceiver to receive one or more configuration parameters to configure the node for communication in an unlicensed frequency band. The node also includes a processor to implement a state machine that transitions, based on the one or more configuration parameters, between an enable state in which the node supports wireless connectivity in the unlicensed frequency band, a disable state in which the node does not support wireless connectivity in the unlicensed frequency band, and a flywheel state in which the node supports wireless connectivity in the unlicensed frequency band for a predetermined time interval before transitioning to the disable state.
Systems, methods, and software for controlling transmissions of User Equipment (UE) on an unlicensed spectrum. In one embodiment, a base station communicates with the UE through radio communications on a licensed spectrum of a carrier. The base station transmits a query to a policy control element requesting spectrum selection criteria for the UE over a direct interface. The base station receives a response from the policy control element that includes the spectrum selection criteria for the UE, and processes the spectrum selection criteria to allocate resources for transmissions involving the UE on the licensed spectrum and on the unlicensed spectrum. The base station then provides a control message including the allocated resources towards the UE to enable the UE to perform the transmissions on the unlicensed spectrum, the licensed spectrum, or a combination of the two.
A central node of a MIMO system may transmit, to one or more communication terminals of the MIMO system, a long-duration downlink pilot signal carrying a pilot sequence having a first duration. The first duration may be equal to or greater than a quantity of antennas of the central node. The central node may receive retransmitted long-duration downlink pilot signals from the communication terminals. The central node may further transmit, to one or more communication terminals, a short- duration downlink pilot signal carrying a pilot sequence having a second duration. The second duration may be less than or equal to the quantity of antennas. The central node may receive a retransmitted short- duration downlink pilot signal from the one or more communication terminals. An uplink and downlink between the central node and one or more communication terminals may be estimated based on the received signals.
An embodiment of the disclosed MIMO transceiver uses a single master clock to generate (i) the sampling-clock signals for the analog-to-digital and digital-to-analog converters and (ii) the multiple electrical local-oscillator signals that are used in various channels of the transceiver's analog down- and up-converters to translate signals between the corresponding intermediate- frequency and RF bands. The MIMO transceiver may employ a plurality of interconnected frequency dividers configured to variously divide the master- clock frequency to generate the sampling-clock signals and the multiple local -oscillator signals in a manner that causes these signals to have different respective frequencies. In embodiments designed for operating in the mm W band, the MIMO transceiver may also employ a frequency multiplier configured to multiply the master-clock frequency to generate an additional local-oscillator signal for translating signals between the mm W and RF bands.
H04B 1/405 - Circuits using the same oscillator for generating both the transmitter frequency and the receiver local oscillator frequency with multiple discrete channels
H04B 1/00 - Details of transmission systems, not covered by a single one of groups Details of transmission systems not characterised by the medium used for transmission
83.
MIMO transceiver suitable for a massive-MIMO system
An embodiment of the disclosed MIMO transceiver uses a single master clock to generate (i) the sampling-clock signals for the analog-to-digital and digital-to-analog converters and (ii) the multiple electrical local-oscillator signals that are used in various channels of the transceiver's analog down- and up-converters to translate signals between the corresponding intermediate-frequency and RF bands. The MIMO transceiver may employ a plurality of interconnected frequency dividers configured to variously divide the master-clock frequency to generate the sampling-clock signals and the multiple local-oscillator signals in a manner that causes these signals to have different respective frequencies. In embodiments designed for operating in the mmW band, the MIMO transceiver may also employ a frequency multiplier configured to multiply the master-clock frequency to generate an additional local-oscillator signal for translating signals between the mmW and RF bands.
H04B 7/04 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
H04J 1/05 - Frequency-transposition arrangements using digital techniques
H04B 7/06 - Diversity systemsMulti-antenna systems, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
The present disclosure generally discloses a hybrid wireless communication system configured to support wireless broadband connectivity for a geographic region including a set of wireless network access devices configured to support wireless communications by a set of communication gateways disposed at locations within the geographic region. The hybrid wireless communication system may be configured to operate across a set of multiple radio spectrum bands associated with a set of multiple carrier frequencies, respectively. The hybrid wireless communication system may be configured to jointly determine assignment of the locations (and, thus, the associated communication gateways) to the multiple carrier frequencies of the multiple radio spectrum bands and to configure the wireless network access devices to support the jointly determined assignment of the locations to the multiple carrier frequencies of the multiple radio spectrum bands.
Various exemplary embodiments relate to a method, network node, and non-transitory machine-readable storage medium including one or more of the following: enabling communication via a first and a second access network, wherein the first access network is a first type and the second access network is a second type; communicating with a first control application via at least one of the first access network and the second access network according to a signaling protocol that is used for the communication without regard for which of the first access network and the second access network are used for the communication, wherein the communication effects a change to service provided via at least one data bearer across at least one of the first access network and the second access network, and communicating via the at least one data bearer to exchange non-control application data with at least one other network device.
A processor accesses a plurality of time series of alarms of a plurality of alarm types that are produced by resources of a network function virtualization (NFV) system. The processor identifies clusters of the plurality of alarm types based on similarities between the plurality of time series and determine causal connections between alarm types in the clusters based on temporal proximity and ordering of the alarm types in the clusters. The processor then stores one or more causality templates representative of the causal connections in a memory.
The present disclosure generally discloses a longest queue identification mechanism. The longest queue identification mechanism, for a set of queues of a buffer, may be configured to identify the longest queue of the set of queues and determine a length of the longest queue of the set of queues. The longest queue identification mechanism may be configured to identify the longest queue of the set of queues using only two variables including a longest queue identifier (LQID) variable for the identity of the longest queue and a longest queue length (LQL) variable for the length of the longest queue. It is noted that the identity of the longest queue of the set of queues may be an estimate of the identity of the longest queue and, similarly, that the length of the longest queue of the set of queues may be an estimate of the length of the longest queue.
Various exemplary embodiments relate to a network node in a distributed dynamic cloud, the node including: a memory; and a processor configured to: observe a local queue backlog at the beginning of a timeslot, for each of a plurality of commodities; compute a processing utility weight for a first commodity based upon the local queue backlog of the first commodity, the local queue backlog of a second commodity, and a processing cost; where the second commodity may be the succeeding commodity in a service chain; compute an optimal commodity using the processing utility weights; wherein the optimal commodity is the commodity with the highest utility weight; assign the number of processing resource units allocated to the timeslot to zero when the processing utility weight of die optimal commodity is less than or equal to zero; and execute processing resource allocation and processing flow rate assignment decisions based upon the optimal commodity.
A non-access stratum (NAS) control protocol includes procedures for control plane cellular internet of things (CP-CIoT) service requests and attach request. UE in idle mode may transmit an NAS service request message including user data to a mobility management entity (MME) over the control plane. The MME extracts the user data from the NAS service request message and determines a type of the user data. The MME may forward non-IP data to a Service Capability Exposure Function (SCEF) and forward IP data to a packet gateway.
A first smart card in a first wireless communication device receives a first profile that indicates a subscription to provide wireless connectivity to a user. The first profile is a copy of at least a portion of a second profile previously established by the user and stored on a second smart card in a second wireless communication device. The first wireless communication device then establishes a first wireless connection with a network using the subscription indicated by the first profile.
The present disclosure generally discloses an autonomous wireless transmission mechanism. The autonomous wireless transmission mechanism may be configured to support autonomous transmissions by wireless end devices to wireless access nodes in a connectionless manner. In general, an autonomous wireless transmission by a wireless end device may include transmission of a preamble in a preamble transmission zone and autonomous transmission of a payload over one or more resource units of one or more payload transmission zones without requiring establishment of a connection between the wireless end device and the wireless access node. The autonomous wireless transmission mechanism, by obviating the need for a wireless end device to establish a connection with a wireless access node in order to transmit data to the wireless access node, also obviates a need for the wireless end device to operate in a scheduled transmission mode.
In one example embodiment, a distributed platform includes at least one node for performing baseband processing of signals, the at least one node including a memory and a processor. The memory has computer-readable instructions stored therein. The processor is configured to the execute computer-readable instructions to enable independent operations of a plurality of radio protocol stacks and a plurality of backhaul protocol stacks for performing the base band processing functions of a plurality of base stations, each of the plurality of base stations being configured to serve one or more user devices. The processor is further configured to manage data packet flows between the plurality of radio protocol stacks and the plurality of backhaul protocol stacks.
The present disclosure generally discloses an addressing mechanism adapted for extending a customer local area network of a customer premises of a customer outside of the customer premises and into a private data network with improved scalability and performance. The extension of a local area network of a customer premises of a customer outside of the customer premises and into a private data network may be provided using a customer bridge associated with the customer local area network of the customer, a customer bridging domain hosted on a network gateway device for the customer, and a switching element hosted in the private data network for the customer for one or more customer components hosted within the private data network for the customer. The addressing mechanism may include one or more of address announcement functions, address resolution functions, address translation functions, or the like, as well as various combinations thereof.
A base station includes a plurality of system-on-a-chip (SOC) boards, which each include a plurality of SOC devices to support wireless communication on a plurality of carriers. One of the SOC devices is a transport SOC (TSOC) device that terminates a backhaul interface for receiving downlink radio bearer packets. Each of the SOC devices configures the TSOC device to route downlink radio bearer packets to a packet data convergence protocol (PDCP) module in the SOC device.
A controller in a wireless communication system includes a transceiver to receive channel activity reports from a first node and a plurality of second nodes that are connected to the first node. The first node supports wireless communication over one or more first channels of a licensed frequency band and second channels of an unlicensed frequency band. The second node supports wireless communication over the second channels of the unlicensed frequency band. The controller also includes a processor to allocate a subset of the second channels to the first node and the plurality of second nodes based on the channel activity reports.
This disclosure generally discloses an anchor mobility mechanism. The anchor mobility mechanism is configured to support migration of flows between mobility anchors within a wireless communication system. The anchor mobility mechanism may be configured to support migration of flows between mobility anchors within a wireless communication system in a highly seamless manner. The anchor mobility mechanism may be configured to support migration of a flow of a wireless device between mobility anchors within a wireless communication system using functions performed by a control element (CE) and one or more forwarding elements (FEs) within the data plane of the flow of the wireless device. The functions may include identifying a time at which to initiate migration of the flow, initiating migration of the flow based on identification of the time at which to initiate migration of the flow, or the like, as well as various combinations thereof.
We disclose an optical receiver for direct detection of an intensity-modulated optical signal, the digital signal processor of which employs a clock-recovery circuit capable of reliably recovering the internal clock of the received optical signal without relying on dispersion-compensation processing even if the signal's eye pattern is substantially closed. In an example embodiment, the clock-recovery circuit comprises a frequency-domain phase detector that operates to determine and track in time the sampling phase using only a subset of the digital spectral components corresponding to the received optical signal. The determined sampling phase is then used to synchronize the digital electrical samples of the received optical signal with the internal clock thereof by way of digital interpolation or through appropriate control of the sampling frequency and phase of the receiver's analog-to- digital converter. Some embodiments of the clock-recovery circuit can beneficially be used in a two-channel optical receiver.
Disclosed is a multi-phase power supply system (500), including a plurality of power controllers (510a-d), each power controller configured to control a DC-DC power converter (520a-d), a plurality of compensation loops configured to receive outputs from the DC-DC power converters and input feedback to the plurality of power controllers, wherein the plurality of power controllers are configured to operate the power converters phase shifted from one another to increase a reaction time to load disturbances on a power rail.
H02M 3/158 - Conversion of DC power input into DC power output without intermediate conversion into AC by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators including plural semiconductor devices as final control devices for a single load
We disclose an optical receiver for direct detection of an intensity-modulated optical signal, the digital signal processor of which employs a clock-recovery circuit capable of reliably recovering the internal clock of the received optical signal without relying on dispersion-compensation processing even if the signal's eye pattern is substantially closed. In an example embodiment, the clock-recovery circuit comprises a frequency-domain phase detector that operates to determine and track in time the sampling phase using only a subset of the digital spectral components corresponding to the received optical signal. The determined sampling phase is then used to synchronize the digital electrical samples of the received optical signal with the internal clock thereof by way of digital interpolation or through appropriate control of the sampling frequency and phase of the receiver's analog-to-digital converter. Some embodiments of the clock-recovery circuit can beneficially be used in a two-channel optical receiver.
H04L 7/033 - Speed or phase control by the received code signals, the signals containing no special synchronisation information using the transitions of the received signal to control the phase of the synchronising-signal- generating means, e.g. using a phase-locked loop
This disclosure generally discloses a path search mechanism for determining mutually compatible paths within a network includes nodes and links. The path search mechanism for determining mutually compatible paths may be configured to determine a set of mutually compatible paths for a set of demands where the demands may include requests for paths between pairs of nodes of the network. The path search mechanism for determining mutually compatible paths may be configured to determine a set of mutually compatible paths for a set of demands where compatibility may be based on edge disjointness, node disjointness, or the like, as well as various combinations thereof. The path search mechanism for determining mutually compatible paths may be configured to determine a set of mutually compatible paths for a set of demands subject to an objective.
