Aspects of the subject disclosure may include, for example, obtaining data pertaining to a plurality of user equipment and a plurality of network resources, analyzing the data to identify that a first user equipment included in the plurality of user equipment is a reduced capability device, based on the analyzing, allocating first network resources included in the plurality of network resources to the first user equipment, resulting in a first allocation, and based on the analyzing, allocating second network resources included in the plurality of network resources to a second user equipment included in the plurality of user equipment, resulting in a second allocation. Other embodiments are disclosed.

A template generation system includes a computing device configured to, in response to receiving a request for a resource from a user device, identify a set of network identifiers based on the request and select a subset of identifiers of the set of network identifiers based on filtering criteria and the request. The computing device is further configured to, for each identifier of the subset of identifiers, in response to a record being associated with the corresponding identifier, clean the record and generate a new record defining the resource by mapping the requested resource to the corresponding identifier. The computing device is also configured to populate a template based on a set of rules identifying the subset of identifiers and the new record and transmit the template to a deployment system.

Provided are systems and methods for segmenting and grouping a plurality of network nodes into one or more clusters. Content may be delivered from a transmitting user node to a receiving user node based on which cluster the receiving user node resides. The grouping of the clusters may be dynamically updated in real-time based on user activity data. Such user activity data may be collected from both a transmitting user node (e.g., server) and a receiving user node (e.g., user device) to map the delivery of a relevant communication. Advantageously, a transmitting user may deliver content to other relevant users and a receiving user may receive content from other relevant users.

Systems and methods are described for onboarding a new device to a blockchain secured network. A trusted device that is already enrolled on the blockchain can receive information from a new device. The new device can send an onboarding request to a server through a non-blockchain secured Application Programming Interface (“API”). The trusted device can send an onboarding request for the new device through a blockchain secured API. The server can receive the requests and match them. The server can authenticate the two devices and send a request to a blockchain consensus to add the new device to the blockchain with the trusted device as a referral. The blockchain consensus can add the new device to the blockchain and notify the server. The server can notify the new device, and the new device can begin communicating through the blockchain secured API or directly with other devices on the blockchain.

Various embodiments of the present disclosure are directed to a group-based communication apparatus that is configured to enable end-users (e.g., non-admin users) to initiate, by way of client devices, generation of a shareable resource associated with a group-based communication resource identifier to efficiently authorize communication between client devices associated with different organization identifiers in group-based communication interfaces associated with a shared group-based communication resource identifier.

Embodiments of the invention are directed to systems, methods, and computer program products for dynamic linking of resource data structures across distributed networks. The system is structured for enhancing data security by evaluating and determining iterations of data transformations associated with resource data structures across networks and establishing deletion and usage modification mechanisms for stored unauthorized downstream iterations. The system is structured to link a first front end resource data structure and a downstream transformation comprising a first entity resource data structure. The system is structured to construct a real-time interactive technology resource interface such that the technology resource interface is structured to present graphical interface objects associated with the link between the first front end resource data structure and the first entity resource data structure.

Systems and methods for efficient database management of non-transitory readable media, including a memory configured to store information associated with service instance requests across a plurality of distributed network resources and a processor configured to receive a service instance request, determine the first native domain object associated with the service instance request, allocate the plurality of network resources to a plurality of distributed worker instances dependent upon a first native domain object, assign the first service instance request to a first worker instance that includes a microservice instance that define service instance blocks to execute the request, and a service instance block manager configured to manage the first service instance request in conjunction with subsequent service instance requests associated with the plurality of worker instances, track running and completed requests, and allocate resources for similar requests across the distributed network nodes.

A template generation system includes a computing device configured to, in response to receiving a request for a resource from a user device, identify a set of network identifiers based on the request and select a subset of identifiers of the set of network identifiers based on filtering criteria and the request. The computing device is further configured to, for each identifier of the subset of identifiers, in response to a record being associated with the corresponding identifier, clean the record and generate a new record defining the resource by mapping the requested resource to the corresponding identifier. The computing device is also configured to populate a template based on a set of rules identifying the subset of identifiers and the new record and transmit the template to a deployment system.

Apparatus and methods for optimizing bandwidth utilization and services in a data network infrastructure. In one embodiment, the data network is a managed Hybrid Fiber Coaxial (HFC) cable network, and the network infrastructure is configured to enable dynamic allocate of frequency bands to individual consumer premises device (e.g., DOCSIS-compliant cable modems). In one variant, the improved network infrastructure enables creation of virtual Service Groups (vSGs), and allocation of individual ones of the CM to such vSGs, to some degree irrespective of topological or “hardwired” location within the network. The allocations can be dynamic, and based on factors such as load balancing, evacuation of portions of the physical network topology (such as to support infrastructure upgrades or replacement), or for yet other reasons such as relating to subscriber tier or service level agreement (SLA).

Some embodiments of the invention provide a novel method of performing network slice-based operations on a data message at a hardware forwarding element (HFE) in a network. For a received data message flow, the method has the HFE identify a network slice associated with the received data message flow. This network slice in some embodiments is associated with a set of operations to be performed on the data message by several network elements, including one or more machines executing on one or more computers in the network. Once the network slice is identified, the method has the HFE process the data message flow based on a rule that applies to data messages associated with the identified slice.