Abstract: Apparatuses, systems, methods, and computer program products for flame detection are provided. An example of a flame detection apparatus includes an infrared sensor to generate infrared sensor data and a thermal camera to capture one or more thermal images and generate thermal image data. The flame detection includes detecting if a flame is present in an environment based on the infrared sensor data and the thermal image data, including determining if one or more false alarms are present. The flame detection may also be based one or more spectral features or thermal features.

Abstract: Provided is an apparatus that includes a first reservoir system including a first fluid reservoir configured to be in fluid communication with a nozzle supply system during operation of the nozzle supply system, a second reservoir system including a second fluid reservoir configured to be, at least part of the time during operation of the nozzle supply system, in fluid communication with the first reservoir system, a priming system configured to produce a fluid target material from a solid matter, and a fluid control system fluidly connected to the priming system, the first reservoir system, the second reservoir system, and the nozzle supply system. The fluid control system is configured to, during operation of the nozzle supply system: isolate at least one fluid reservoir and the nozzle supply system from the priming system, and maintain a fluid flow path between at least one fluid reservoir and the nozzle supply system.

Abstract: The present disclosure is directed systems and methods for control embedding data packets for ARP queries, the methods including the steps of receiving a data plane packet from a first user device, the data plane packet requesting a hardware address associated with a second user device; generating a northbound control plane packet for transmission to a control plane node, the northbound control plane packet for requesting from the control plane node the hardware address associated with the second user device; embedding the data plane packet in the northbound control plane packet; and forwarding the northbound control plane packet with the data plane packet to the control plane node for respective processing of the northbound control plane packet and the data plane packet.

Abstract: In one embodiment, an access policy enforcement service receives a user authentication request from an end-user device. The access policy enforcement service identifies a telemetry collection intent from the user authentication request. The access policy enforcement service determines a monitoring policy based on the telemetry collection intent identified from the user authentication request. The access policy enforcement service configures, according to the monitoring policy, one or more telemetry collection agents to collect telemetry for traffic associated with the end-user device.

Abstract: The present disclosure is directed systems and methods for control embedding data packets for ARP queries, the methods including the steps of receiving a data plane packet from a first user device, the data plane packet requesting a hardware address associated with a second user device; generating a northbound control plane packet for transmission to a control plane node, the northbound control plane packet for requesting from the control plane node the hardware address associated with the second user device; embedding the data plane packet in the northbound control plane packet; and forwarding the northbound control plane packet with the data plane packet to the control plane node for respective processing of the northbound control plane packet and the data plane packet.

Abstract: In a computer-implemented method for generating a recommendation for automatic transformation of times series data at ingestion, historical query data of a time series data monitoring system is analyzed, where the historical query data includes a plurality of queries and data associated with execution of the plurality of queries. Based on the analyzing, it is determined whether an execution cost of a query of the plurality of queries can be reduced by performing automatic transformation of at least a portion of times series data accessed responsive to the query at ingestion into the time series data monitoring system. In response to determining that the execution cost of the query can be reduced by performing automatic transformation at ingestion, a recommendation to perform the automatic transformation of the at least a portion of the times series data at ingestion is generated.

Abstract: Provided is an apparatus that includes a first reservoir system including a first fluid reservoir configured to be in fluid communication with a nozzle supply system during operation of the nozzle supply system, a second reservoir system including a second fluid reservoir configured to be, at least part of the time during operation of the nozzle supply system, in fluid communication with the first reservoir system, a priming system configured to produce a fluid target material from a solid matter, and a fluid control system fluidly connected to the priming system, the first reservoir system, the second reservoir system, and the nozzle supply system. The fluid control system is configured to, during operation of the nozzle supply system: isolate at least one fluid reservoir and the nozzle supply system from the priming system, and maintain a fluid flow path between at least one fluid reservoir and the nozzle supply system.

Abstract: In a computer-implemented method for automatic transformation of time series data at ingestion, time series data comprising data points is received at at least one ingestion node of a time series data monitoring system, wherein the data points have an input observability format. At the at least one ingestion node, the data points the data points are transformed from the input observability format to an output observability format according to configuration rules of the time series data monitoring system. The data points having the output observability format are forwarded from the at least one ingestion node to a persistent storage device.

Abstract: In a method for secure ingestion of metrics of time series data, an ingestion request for ingesting at least one metric of time series data is received, the ingestion request including an identifier. The ingestion request is validated against a security policy according to the identifier. The ingestion request is updated to exclude any metric indicated in the security policy as excluded according to the identifier. The at least one metric of time series data is ingested according to the ingestion request.

Abstract: In a method for secure access to metrics of time series data, an access request for accessing at least one metric of time series data is received, the access request including an identifier. The access request is validated against a security policy according to the identifier. The access request is updated to exclude any metric indicated in the security policy as excluded according to the identifier. Results of the access request are returned.

Abstract: Approaches are disclosed for virtualizing a network management protocol (NMP). A network element offloads processes for communicating in the NMP to a virtualization engine (e.g., a backend virtualization proxy for the network element). The network element transmits a message containing a NMP request to the virtualization engine using service function chaining (SFC) by inserting service plane protocol data (e.g., a network service header (NSH)) into the message (e.g., an impregnated request). The virtualization engine expropriates, from the network element, processes for communicating in the NMP and can, thereby, reduce the computational resources used by the network element for communicating in the NMP. The virtualization engine generates a NMP response to the NMP request. The virtualization engine transmits a different message containing the NMP response to the network element using SFC by inserting service plane protocol data into the message (e.g., an impregnated response).

Abstract: End-to-end, in situ packet enrichment for network analytics includes receiving, at a network device is a part of an end-to-end path in a network, a template that specifies unique information elements to be added to a header of a packet traversing the network device when different combinations of network features are applied to the packet at the network device. When the network device applies one or more of the network features to the packet, the network device inserts one a particular information element of the unique information elements into the header of the packet based on the template and the one or more network features applied to the packet. The particular information element inserted into the header is resolvable to a list of the one or more network features applied to the packet at the network device.

Abstract: A computing system operates according to a method including: processing representations of housing structures with open locations for physically locating computing resources, a physical layout of the open locations, and characteristics of the structures and the resources to generate designated locations for optimally placing or allocating the computing resources in the open locations. The designated locations are generated based on analyzing multiple possible allocation or placement combinations of the computing resources into the open locations as an optimization function.

Abstract: A computing system operates according to a method including: processing representations of housing structures with open locations for physically locating computing resources, a physical layout of the open locations, and characteristics of the structures and the resources to generate designated locations for optimally placing or allocating the computing resources in the open locations. The designated locations are generated based on analyzing multiple possible allocation or placement combinations of the computing resources into the open locations as an optimization function.

Abstract: End-to-end, in situ packet enrichment for network analytics includes receiving, at a network device is a part of an end-to-end path in a network, a template that specifies unique information elements to be added to a header of a packet traversing the network device when different combinations of network features are applied to the packet at the network device. When the network device applies one or more of the network features to the packet, the network device inserts one a particular information element of the unique information elements into the header of the packet based on the template and the one or more network features applied to the packet. The particular information element inserted into the header is resolvable to a list of the one or more network features applied to the packet at the network device.

Abstract: Approaches are disclosed for virtualizing a network management protocol (NMP). A network element offloads processes for communicating in the NMP to a virtualization engine (e.g., a backend virtualization proxy for the network element). The network element transmits a message containing a NMP request to the virtualization engine using service function chaining (SFC) by inserting service plane protocol data (e.g., a network service header (NSH)) into the message (e.g., an impregnated request). The virtualization engine expropriates, from the network element, processes for communicating in the NMP and can, thereby, reduce the computational resources used by the network element for communicating in the NMP. The virtualization engine generates a NMP response to the NMP request. The virtualization engine transmits a different message containing the NMP response to the network element using SFC by inserting service plane protocol data into the message (e.g., an impregnated response).

Abstract: Apparatuses, methods, and non-transitory computer readable medium for testing business intelligence data over a communication network include receiving a data mapping file, applicable to a source data repository and a target data repository, and generating data mapping file based on the same. Test cases are generated, based on the data mapping file, and SQL scripts, for execution of the test cases, and executing the SQL scripts on the source data repository and the target data. An online analytical processing (OLAP) cube report for the target data repository is received and the OLAP cube report and a report, which is to be tested, are compared to generate a comparison report. The comparison report is indicative of the fields of the OLAP cube report and the report, which is to be tested, which generated at least one error.

Abstract: Apparatuses, methods, and non-transitory computer readable medium for testing business intelligence data over a communication network include receiving a data mapping file, applicable to a source data repository and a target data repository, and generating data mapping file based on the same. Test cases are generated, based on the data mapping file, and SQL scripts, for execution of the test cases, and executing the SQL scripts on the source data repository and the target data. An online analytical processing (OLAP) cube report for the target data repository is received and the OLAP cube report and a report, which is to be tested, are compared to generate a comparison report. The comparison report is indicative of the fields of the OLAP cube report and the report, which is to be tested, which generated at least one error.

Abstract: A storage system that accomplishes both robustness and scalability. The storage system includes replicated region servers configured to handle computation involving blocks of data in a region. The storage system further includes storage nodes configured to store the blocks of data in the region, where each of the replicated region servers is associated with a particular storage node of the storage nodes. Each storage node is configured to validate that all of the replicated region servers are unanimous in updating the blocks of data in the region prior to updating the blocks of data in the region. In this manner, the storage system provides end-to-end correctness guarantees for read operations, strict ordering guarantees for write operations, and strong durability and availability guarantees despite a wide range of server failures (including memory corruptions, disk corruptions, etc.) and scales these guarantees to thousands of machines and tens of thousands of disks.