公开(公告)号：US20220334878A1

公开(公告)日：2022-10-20

申请号：US17854664

申请日：2022-06-30

申请人： Francesc Guim Bernat ,  Marcos E. Carranza ,  Akhilesh Thyagaturu

发明人： Francesc Guim Bernat ,  Marcos E. Carranza ,  Akhilesh Thyagaturu

IPC分类号： G06F9/50

摘要： System and techniques for generating a virtual shared resource pool are described herein. The system may include means for reserving, by a controller of a first computing device, a resource on a second computing device. Means for instantiating, by the controller of the first computing device, a local service including a virtual function for the resource. The system may also include means for executing a process on the first computing device using the resource from the second computing device via the virtual function.

公开(公告)号：US20230135938A1

公开(公告)日：2023-05-04

申请号：US18090813

申请日：2022-12-29

申请人： Marcos E. Carranza ,  Francesc Guim Bernat ,  Kshitij Arun Doshi ,  Karthik Kumar ,  Srikathyayani Srikanteswara ,  Mateo Guzman

发明人： Marcos E. Carranza ,  Francesc Guim Bernat ,  Kshitij Arun Doshi ,  Karthik Kumar ,  Srikathyayani Srikanteswara ,  Mateo Guzman

IPC分类号： H04L67/63 ,  H04L67/1087

摘要： Various approaches for service mech switching, including the use of infrastructure processing units (IPUs) and similar networked processing units, are disclosed. For example, a packet that includes a service request for a service may be received at a networking infrastructure device. The service may include an application that spans multiple nodes in a network. An outbound interface of the networking infrastructure device may be selected through which to route the packet. The selection of the outbound interface may be based on a service component of the service request in the packet and network metrics that correspond to the service. The packet may then be transmitted using the outbound interface.

公开(公告)号：US20220114251A1

公开(公告)日：2022-04-14

申请号：US17561134

申请日：2021-12-23

申请人： Francesc Guim Bernat ,  Kshitij Arun Doshi ,  Adrian Hoban ,  Thijs Metsch ,  Dario Nicolas Oliver ,  Marcos E. Carranza ,  Mats Gustav Agerstam ,  Bin Li ,  Patrick Koeberl ,  Susanne M. Balle ,  John J. Browne ,  Cesar Martinez-Spessot ,  Ned M. Smith

发明人： Francesc Guim Bernat ,  Kshitij Arun Doshi ,  Adrian Hoban ,  Thijs Metsch ,  Dario Nicolas Oliver ,  Marcos E. Carranza ,  Mats Gustav Agerstam ,  Bin Li ,  Patrick Koeberl ,  Susanne M. Balle ,  John J. Browne ,  Cesar Martinez-Spessot ,  Ned M. Smith

IPC分类号： G06F21/51 ,  G06F21/57 ,  H04L43/0823 ,  H04L41/5009

摘要： Various systems and methods for implementing reputation management and intent-based security mechanisms are described herein. A system for implementing intent-driven security mechanisms, configured to: determine, based on a risk tolerance intent related to execution of an application on a compute node, whether execution of a software-implemented operator requires a trust evaluation; and in response to determining that the software-implemented operator requires the trust evaluation: obtain a reputation score of the software-implemented operator; determine a minimum reputation score from the risk tolerance intent; compare the reputation score of the software-implemented operator to the minimum reputation score; and reject or permit execution of the software-implemented operator based on the comparison

公开(公告)号：US20240348606A1

公开(公告)日：2024-10-17

申请号：US18754752

申请日：2024-06-26

申请人： Stephen T. Palermo ,  Valerie J. Parker ,  Patrick L. Connor ,  Francesc Guim Bernat ,  John Joseph Browne ,  Rajesh Poornachandran ,  Marcos E. Carranza

发明人： Stephen T. Palermo ,  Valerie J. Parker ,  Patrick L. Connor ,  Francesc Guim Bernat ,  John Joseph Browne ,  Rajesh Poornachandran ,  Marcos E. Carranza

IPC分类号： H04L9/40

CPC分类号： H04L63/0876

摘要： Various approaches for the verification of 5G networks, including the use of fingerprint-based IQ measurements for authentication and integrity monitoring, are discussed. In an example, a method of using fingerprints for authentication of network use includes: capturing in-phase and quadrature (IQ) data from a network connection between a user equipment (UE) and a 5G network; performing authentication of the network connection between the UE and the 5G network, by using a symbol of the IQ data as a random factor for the authentication; and monitoring the IQ data on an ongoing basis to verify the network connection between the UE and the 5G network. The method may also include creating a baseline IQ measurement from the IQ data when performing the authentication between the UE and the 5G network, and monitoring the IQ data by using a comparison of an ongoing IQ measurement to the baseline IQ measurement.

公开(公告)号：US20230013452A1

公开(公告)日：2023-01-19

申请号：US17953539

申请日：2022-09-27

申请人： S M Iftekharul Alam ,  Marcos E. Carranza ,  Francesc Guim Bernat ,  Mateo Guzman ,  Satish Chandra Jha ,  Cesar Martinez-Spessot ,  Arvind Merwaday ,  Rajesh Poornachandran ,  Vesh Raj Sharma Banjade ,  Kathiravetpillai Sivanesan ,  Ned M. Smith ,  Liuyang Lily Yang ,  Mario Jose Divan Koller

发明人： S M Iftekharul Alam ,  Marcos E. Carranza ,  Francesc Guim Bernat ,  Mateo Guzman ,  Satish Chandra Jha ,  Cesar Martinez-Spessot ,  Arvind Merwaday ,  Rajesh Poornachandran ,  Vesh Raj Sharma Banjade ,  Kathiravetpillai Sivanesan ,  Ned M. Smith ,  Liuyang Lily Yang ,  Mario Jose Divan Koller

IPC分类号： G05B19/4155

摘要： System and techniques for an environmental control loop are described herein. A device for an environmental control loop can include a memory including instructions and processing circuitry that when in operation, can be configured by the instructions to receive environmental sensor data from a first component in a set of heterogeneous components installed in an environment with a controller. The environmental sensor data can indicate a service level value sensed by the first component. The controller can also measure a violation of a service level objective based on comparing the environmental sensor data to a threshold. The controller can also transmit an adjustment to an operating parameter of a second component of the set of heterogeneous components. The adjustment can be operative to attenuate the violation of the service level objective when implemented by the second component.

公开(公告)号：US20210116261A1

公开(公告)日：2021-04-22

申请号：US17247844

申请日：2020-12-26

申请人： Francesc Guim Bernat ,  Marcos E. Carranza ,  Satish Chandra Jha ,  Sindhu Pandian ,  Lakshmi Talluru ,  Cesar Martinez-Spessot ,  Mateo Guzman ,  Dario Nicolas Oliver ,  Ignacio J. Alvarez ,  David Gonzalez Aguirre ,  Javier Felip Leon ,  S M Iftekharul Alam

发明人： Francesc Guim Bernat ,  Marcos E. Carranza ,  Satish Chandra Jha ,  Sindhu Pandian ,  Lakshmi Talluru ,  Cesar Martinez-Spessot ,  Mateo Guzman ,  Dario Nicolas Oliver ,  Ignacio J. Alvarez ,  David Gonzalez Aguirre ,  Javier Felip Leon ,  S M Iftekharul Alam

IPC分类号： G01C21/36 ,  G08G1/09 ,  G05D1/02

摘要： Disclosed herein are systems and methods for vehicle-occupancy-based and user-preference-based smart routing, and autonomous volumetric-occupancy measurement. In an embodiment, a system is configured to receive from a user device associated with a user, a routing-options request for routing options between two locations, and to responsively identify one or more routing options between the two locations based at least in part on occupancy data for a vehicle that would be utilized for at least a portion of at least one of the identified routing options. The occupancy data is based on an output of an automated occupancy-measurement system onboard the vehicle. The system is also configured to provide the one or more identified routing options to the user device. In some embodiments, the occupancy data is obtained using volumetric-occupancy measurement. Some embodiments relate to volumetric-occupancy measurement conducted by autonomous mesh nodes.

公开(公告)号：US20210109731A1

公开(公告)日：2021-04-15

申请号：US17131561

申请日：2020-12-22

申请人： Dario Nicolas Oliver ,  Marcos E. Carranza ,  Cesar Martinez-Spessot ,  Francesc Guim Bernat ,  Mateo Guzman ,  Sindhu Pandian ,  Ignacio Javier Alvarez Martinez ,  Mats Gustav Agerstam

发明人： Dario Nicolas Oliver ,  Marcos E. Carranza ,  Cesar Martinez-Spessot ,  Francesc Guim Bernat ,  Mateo Guzman ,  Sindhu Pandian ,  Ignacio Javier Alvarez Martinez ,  Mats Gustav Agerstam

IPC分类号： G06F8/61 ,  H04W12/033 ,  G06F21/71 ,  H04L29/08 ,  H04B1/38

摘要： System and techniques for hands-free deployment of geographically linked applications are described herein. A radio transceiver of a vehicle may detect a beacon. Here, the beacon includes an indication that an application linked to a geographical area covered by the beacon is available. The vehicle may establish a secure communications link with an application server corresponding to the beacon and receive, through the secure communications link, an application. Then, the vehicle may execute the application in a protected execution environment without intervention by a user of the vehicle.

公开(公告)号：US20230319141A1

公开(公告)日：2023-10-05

申请号：US18205664

申请日：2023-06-05

申请人： Kshitij Arun Doshi ,  Francesc Guim Bernat ,  Sunil Cheruvu ,  Ned M. Smith ,  Marcos E. Carranza

发明人： Kshitij Arun Doshi ,  Francesc Guim Bernat ,  Sunil Cheruvu ,  Ned M. Smith ,  Marcos E. Carranza

IPC分类号： H04L67/12 ,  H04L12/18

CPC分类号： H04L67/12 ,  H04L12/1881 ,  H04L12/185

摘要： Various systems and methods for providing consensus-based named function execution are described herein. A system is configured to access an interest packet received from a user device, the interest packet including a function name of a function and a data payload; broadcast the interest packet to a plurality of compute nodes, wherein the plurality of compute nodes are configured to execute a respective instance of the function; receive a plurality of responses from the plurality of compute nodes, the plurality of responses including respective results of the execution of the respective instances of the function; analyze the plurality of responses using a consensus protocol to identify a consensus result; and transmit the consensus result to the user device.

公开(公告)号：US20220124005A1

公开(公告)日：2022-04-21

申请号：US17561254

申请日：2021-12-23

申请人： Kshitij Arun Doshi ,  John J. Browne ,  Marcos E. Carranza ,  Francesc Guim Bernat ,  Mats Gustav Agerstam ,  Adrian Hoban ,  Thijs Metsch

发明人： Kshitij Arun Doshi ,  John J. Browne ,  Marcos E. Carranza ,  Francesc Guim Bernat ,  Mats Gustav Agerstam ,  Adrian Hoban ,  Thijs Metsch

IPC分类号： H04L41/5003 ,  H04L41/5019 ,  G06F9/50

摘要： Various systems and methods for reactive intent-driven end-to-end (E2E) orchestration are described herein. An orchestrator system, includes a processor; and memory to store instructions, which when executed by the processor, cause the system to: receive, at the orchestrator system, an intent-based service level agreement (SLA) for execution of a series of tasks on a plurality of compute nodes; calculate, based on the intent-based SLA, intermediate latency thresholds corresponding to each task of the series of tasks; calculate slack estimates based on the latency thresholds and real-time telemetry of the plurality of compute nodes or real-time telemetry of connections between the plurality of compute nodes; monitor execution of the series of tasks on the plurality of compute nodes; and perform a corrective action in response to determining that the execution of the series of tasks is predicted to exceed one of the intermediate latency thresholds

公开(公告)号：US20220114032A1

公开(公告)日：2022-04-14

申请号：US17559833

申请日：2021-12-22

申请人： Francesc Guim Bernat ,  Karthik Kumar ,  Alexander Bachmutsky ,  Marcos E. Carranza ,  Rita H. Wouhaybi

发明人： Francesc Guim Bernat ,  Karthik Kumar ,  Alexander Bachmutsky ,  Marcos E. Carranza ,  Rita H. Wouhaybi

IPC分类号： G06F9/50 ,  G06F9/48

摘要： System and techniques for infrastructure managed workload distribution are described herein. An infrastructure processing unit (IPU) receives a workload that includes a workload definition. The workload definition includes stages of the workload and a performance expectation. The IPU provides the workload, for execution, to a processing unit of a compute node to which the IPU belongs. The IPU monitors execution of the workload to determine that a stage of the workload is performing outside of the performance expectation from the workload definition. In response, the IPU modifies the execution of the workload.