Abstract: An integrated HOFS meander line polarizer radome including: a substrate including layers having a dielectric constant (dk) greater than 2.0 and less than 5.0; a Higher Order Floquet-mode Structure (HOFS) may include HOFS lines disposed in a first subset of the layers; and meander lines, to provide a phase shift and match, disposed in a second subset of the layers, where at least one layer of the first subset is disposed between the second subset of the layers.

Abstract: A method for communicating with a legacy terminal supporting a legacy air interface and a new terminal supporting a next generation air interface including: assigning a same carrier to the legacy terminal and the new terminal; receiving a terminal identifier and an optional payload for transmission at a MAC/RLC layer; determining if the terminal identifier is associated with the legacy terminal or the new terminal; composing, based on the determining, a burst header; formatting, a burst including the burst header and the optional payload; and transmitting the burst. In the method, the burst header is set to one of the one or more valid burst headers when the burst is associated with the legacy terminal, and the burst header is set to one of the one or more undefined burst headers when the burst is associated with the new terminal.

Abstract: A system and method for communicating with an Internet of Things (IoT) User Terminal (UT) population. The method includes storing UT parameters for each UT of the UT population with a security and repository server (SRS), where the UT parameters include a UT identifier, a UT IP address, and an application server IP address; communicating from the UT population using a one-shot transmission via an over-the-air (OTA) link; receiving the one-shot transmission from a sender UT of a UT population; and sending an IP packet including a portion of the one-shot transmission to an application server. In the method, the one-shot transmission includes an unscheduled transmission between the GW and UT, the one-shot transmission includes a sender UT identifier, and the UT identifier for each UT of the UT population is unique.

Abstract: A system and method for aggregating representational state transfer (REST) API response fields, the method including receiving, via a satellite link, a schema including field definitions, where each of the field definitions includes an endpoint and a field. The method also includes retrieving, for each of the field definitions, the respective field from a result of invoking the respective endpoint; and aggregating a package including each retrieved field. The schema and the package may conform to a JavaScript Object Notation (JSON) schema format.

Abstract: A cellular system and method to provide voice and data services to a user terminal are disclosed. The cellular system includes a cellular base station; a satellite backhaul including a first satellite link and a second satellite link; and a traffic classifier to classify traffic from the cellular base station as voice traffic for transportation via the first satellite link and as data traffic for transportation via the second satellite link.

Abstract: Systems and methods are disclosed, and one includes receiving an encoded data stream, generating a first upsampled encoded block, based on a first upsampling rate upsampling of a first content from the data stream, communicating the first upsampled encoded block to a beam hopping satellite, on an uplink, during an uplink first time interval having a synchronization with a first beam of the beam hopping satellite, as a feed for the first beam. The systems may further include generating, starting at a time within the uplink first time interval, a second upsampled encoded block, based on a second upsampling rate upsampling of a second content from the data stream, and communicating the second upsampled encoded block via the uplink to the beam hopping satellite, during an uplink second time interval having a synchronization with a second beam of the beam hopping satellite, as a feed for the second beam.

Abstract: A transmitter, including a signal processor programmed to generate, based on input serial data, for each of an integer number of subcarriers mutually orthogonal to each other, a respective first parallel data stream. The signal processor is further programmed to modulate each of the integer number of subcarriers respectively with the respective parallel stream to generate the integer number of data-modulated subcarriers. The signal processor is further programmed to modulate a single carrier occupying a same bandwidth as the integer number of subcarriers with a unique word and one or more pilot symbols to generate a second signal. The signal processor combines the first signal and second signal to generate a third signal. The signal processor generates an output signal by applying a transmit filter to the third signal.

Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for adjusting communication channel bandwidth. In some implementations, a method includes determining to change a bandwidth of a wireless communication channel on which a transmitter and receiver communicate. In response, and while the transmitter and the receiver maintain data communication on the wireless communication channel, a target value and rate of change is determined for each of one or more communication parameters of the wireless communication channel. The rate of change is a rate at which the communication parameter can be changed over time while continuing to transfer data on the wireless communication channel. Data is provided to the transmitter. The data can cause, for each communication parameter, the transmitter to gradually adjust the communication parameter using the rate of change until the communication parameter reaches the target value.

Abstract: Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for training and using machine learning models to classify network traffic as IoT traffic or non-IoT traffic and managing the traffic based on the classification. In some implementations, machine learning parameters of a local machine learning model trained by the edge device is received each of at least a subset of a set of edge devices. The machine learning parameters received from an edge device are parameters of the local machine learning model trained by the edge device based on local network traffic processed by the edge device and to classify the network traffic as Internet of Things (IoT) traffic or non-IoT traffic. A global machine learning model is generated, using the machine learning parameters, to classify network traffic processed by edge devices as IoT traffic or non-IoT traffic.

Abstract: A system comprises a gateway computer further comprising a processor and a memory. The memory stores instructions executable by the processor to determine one or more service functions (SF) based on a received data packet, and to determine a list of routing identifiers based on the determined service functions and a destination of the data packet. Each routing identifier identifies at least one of a router computer and a service function. The memory stores instructions to update the data packet to include the list of routing identifiers, and to transmit the updated data packet based on the list of routing identifiers.

Abstract: Computer-implemented systems and methods for diagnosing and correcting connectivity problems in a network are provided. The method includes obtaining, at a network node disposed at an edge of the network, measurements of one or more attributes of network traffic exchanged between a content server and a client device via the network. The network traffic is associated with streaming video content transmitted from the content server to the client device over the network. The method also includes analyzing the one or more attributes of the network traffic to estimate Quality of Experience (QoE) performance metrics related to the streaming video content at the client device, and adjusting one or more network operating parameters of the network responsive to QoE performance metrics falling below a predetermined threshold.

Abstract: A system and method for scheduling a variable stayout distance when beam hopping, the method including providing an illumination area of a satellite and candidate beam centers disposed in the illumination area; measuring a respective scan angle from an antenna boresight to a respective beam center of the candidate beam centers; and determining a reuse factor k for each of the candidate beam centers, based on a proportion of the respective scan angle to a maximum scan angle. Each candidate beam center may be processed sequentially. Prior to adding each candidate beam center to a current beam center set, checking whether a candidate beam center meets the stayout distance criteria from all beam centers already in the beam center set.

Abstract: A method of and system for designing a satellite network includes selecting an optimal design for a backhaul network to be used as part of the satellite network, selecting a number of radio frequency (RF) gateways for the satellite network, selecting an optimal number of satellite network cores (SNCs) for the satellite network. The method may also include placing each SNC at a site that is geographically separate from locations of the RF gateways, selecting a number of data centers for the satellite network, connecting each SNC to one or more data centers in the satellite network, and connecting each data center to one or more of the RF gateways via the backhaul network.

Abstract: Systems and method are disclosed and among these is a method for fingerprint based detection of Internet of Things (IoT) devices and classification of IoT device type, and corresponding adaptive allocation of link resources, with monitoring of traffic for flow data, detecting IoT devices and classifying the IoT device types, via machine learning classifiers, real time assigning IoT device type based quality of service (QoS) for IoT device traffic, and corresponding IoT device type based, real time allocating of resources to the link. Optionally, machine classifiers can be centrally instantiated, distributed to what can be large populations of user IoT Internet access terminals, and retrained by same, centrally merged or combined, and then redistributed.

Abstract: Half tone offset may be utilized to mitigate signal distortion caused by DC bias within OFDM-based systems. In addition a cyclic prefix may be utilized within an OFDM-based system to mitigate inter-symbol-interference. Presented herein are techniques and methods to efficiently apply a cyclic prefix to an OFDM symbol with half tone offset for low power systems.

Abstract: Systems and methods are disclosed, and one includes determining a network resource state, based at least in part on a delay level of the network resource, determining a first priority user demand and a second priority user demand for the network resource, and upon the network resource state meeting a condition, adjusting an allocation of network resource bandwidth to the first priority user and an allocation of network resource bandwidth to the second priority user adjusting. The update of the allocation of network resource bandwidth to the first priority user is based at least in part on a combination of the first priority user demand, the second priority user demand, a first priority user guaranteed bandwidth, and a capacity of the network resource. The update of the allocation of network resource bandwidth to the second priority user is based at least in part on the adjusted allocation of network resource bandwidth to the first priority user.

Abstract: Embodiments disclosed herein relate generally to techniques for mitigating blockages associated with satellite systems. More specifically, techniques disclosed herein, describe solutions for minimizing service interruption during satellite handover. One or more blockages associated with one or more user terminals that connect to a satellite system may be determined by various means. Utilizing those blockages, handover times for the one or more user terminals may be determined such that service interrupts may be minimized.

Abstract: A communications apparatus to receive a composite signal including a desired signal and interferer signals, where the desired signal may include desired symbols and the interferer signals may include interferer symbols. The system may include N frameworks, each framework may include a detector to partition the desired symbols and the interferer symbols based on an interference severity into a dominant group and a non-dominant group, and to generate A Posteriori Probabilities (APP) of the desired symbols and the interferer symbols. The detector of each of the N frameworks generates the APP based on a feedback of a priori probabilities from each of the N frameworks.

Abstract: A method of and system for converting domain names to a vector space embedding may include receiving data relating to internet traffic over a network, organizing the data into one or more documents that make up a training dataset, each of the one or more documents including one or more Domain Name Server (DNS) queries, providing the training dataset to a deep neural network to generate at least one vector space embedding for one or more domain names, and providing the vector space embedding as an output.

Abstract: A method for isolating packet loss on a hierarchical packet network, the method including: connecting a first network element (NE) to a second NE via a varying path traversing multiple network segments; discovering, with the first NE, a set of segment-demarcation expect-to-echo nodes along the varying path; ascertaining, with the first NE, a request-to-echo configuration for each node in the set; emitting a sample size of requests-to-echo in a respective request-to-echo configuration for each node in the set at a sample rate; receiving results of the sample size of requests-to-echo to generate a packet-loss sample; and calculating a rate-of-loss for the packet-loss sample.