The present disclosure relates to systems, methods, and non-transitory computer-readable media that generate compressed metric data for digital metrics utilizing a graph-based compression dictionary and time slice compression. For instance, the disclosed systems can utilize a dynamically modifiable graph-based compression dictionary to generate compressed metric label identifiers for metric labels of digital metrics. The graph-based compression dictionary can include nodes and edges corresponding to metric label segments and metric label identifier values, respectively. The disclosed systems can traverse the graph-based compression dictionary using a metric label to determine the corresponding compressed metric label identifier. The disclosed systems can further generate delta compression values for the metric values of the digital metrics. For instance, the disclosed systems can compare metric values within a single time slice (e.g., a time stamp) to generate corresponding delta compression values. In some cases, the disclosed systems further compare the metric values across a time window.

A computer-implemented system for eliminating perpetual application programming interface (API) calls to minimize resource drain. The system may comprise: at least one non-transitory computer-readable medium configured to store instructions; and at least one processor configured to execute the instructions to perform operations. The operations may comprise: monitoring a dynamic list of one or more API calls, wherein the dynamic list is configured to vary in length; identifying a subset of the API calls that remain in the dynamic list through a number of the process cycles over a first threshold; querying one or more network databases to verify that the subset of the API calls have not been resolved; determining costs of dismissing the subset of the API calls; dismissing the API calls with costs less than a second threshold; and transmitting a notification API call to one or more user devices corresponding to the dismissed API calls.

A computer-implemented system for eliminating perpetual application programming interface (API) calls to minimize resource drain. The system may comprise: at least one non-transitory computer-readable medium configured to store instructions; and at least one processor configured to execute the instructions to perform operations. The operations may comprise: monitoring a dynamic list of one or more API calls, wherein the dynamic list is configured to vary in length; identifying a subset of the API calls that remain in the dynamic list through a number of the process cycles over a first threshold; querying one or more network databases to verify that the subset of the API calls have not been resolved; determining costs of dismissing the subset of the API calls; dismissing the API calls with costs less than a second threshold; and transmitting a notification API call to one or more user devices corresponding to the dismissed API calls.

A method for data reduction may comprise computing (i) a first sketch of a first segment and (ii) a second sketch of a second segment. The first sketch and the second sketch may each comprise a set of features that are representative of or unique to the corresponding first and second segments. The method also comprise processing the first sketch and the second sketch to generate a similarity metric indicative of whether the second segment is similar to the first segment. The method may further comprise (1) performing a differencing operation on the second segment relative to the first segment when the similarity metric is greater than or equal to a similarity threshold, or (2) storing the first segment and the second segment in a database without performing the differencing operation when the similarity metric is less than the similarity threshold.

The present invention relates to systems and methods for controlling real-time traffic surge at a server [102]. An Application Programming Interface (API) gateway [104] receives at least one service request from at least one application device [106] for availing at least one service from a server [102], and enables at least one part of the server [102] based on a count of the received requests determined by a load counter. A throttling parameter, including one of a static throttling parameter and a dynamic throttling parameter, is determined by a throttling parameter module [204] for the enabled at least one part of the server [102]. The API gateway [104] validates the at least one service request based on the count and the throttling parameter. Thereafter, the at least one part of the server [102] provides at least one service to the validated at least one application device [106].

A machine-learning tool evaluates an acquirer's current portfolio and then develops a model portfolio that mathematically redistributes the effect of the current portfolio by suggesting business categories that would better serve the acquirer from a risk/reward perspective. The machine-learning tool is trained with model portfolios and then generates a suggested portfolio that incorporates the acquirer's current partners and supplements them with additional business categories that would improve the risk/reward metric. The machine-learning tool may also select specific businesses from within the suggested business categories for the acquirer to use in achieving the suggested improvement.

The Cloud-based Video Streaming Service (CVSS) architecture is disclosed to transcode video streams in an on-demand manner. The architecture provides a platform for streaming service providers to utilize cloud resources in a cost-efficient manner and with respect to the Quality of Service (QoS) demands of video streams. In particular, the architecture includes a QoS-aware scheduling method to efficiently map video streams to cloud resources, and a cost-aware dynamic (i.e., elastic) resource provisioning policy that adapts the resource acquisition with respect to the video streaming QoS demands. Simulation results based on realistic cloud traces and with various workload conditions, demonstrate that the CVSS architecture can satisfy video streaming QoS demands and reduces the incurred cost of stream providers up to 70%.

A computer implemented method of reducing a size of a message intercepted on a communication channel of a vehicle, comprising using one or more processors of a vehicular device. The processor(s) is adapted for receiving one or more of a plurality of messages intercepted by one or more devices adapted to monitor messages transmitted via one or more segments of one or more communication channels of a vehicle, applying one or more trained machine learning models to identify one or more of a plurality of data patterns in one or more of the messages, adjusting one or more of the messages by replacing each of the identified data pattern(s) with a respective predefined lossless representation having a reduced size compared to the identified data pattern and transmitting the adjusted message(s) to a remote system via one or more upload communication channels.

A computer implemented method of reducing a size of a message intercepted on a communication channel of a vehicle, comprising using one or more processors of a vehicular device. The processor(s) is adapted for receiving one or more of a plurality of messages intercepted by one or more devices adapted to monitor messages transmitted via one or more segments of one or more communication channels of a vehicle, applying one or more trained machine learning models to identify one or more of a plurality of data patterns in one or more of the messages, adjusting one or more of the messages by replacing each of the identified data pattern(s) with a respective predefined lossless representation having a reduced size compared to the identified data pattern and transmitting the adjusted message(s) to a remote system via one or more upload communication channels.

A method of processing payment transactions includes receiving a connection request from a client device, determining whether a gateway is available for the client device, creating a connection between the client device and a gateway, the gateway being a previously existing gateway or a newly generated gateway, creating a message filter for the client device on a message bus, listening for messages on the message bus and transmitting the message to the client device by way of the gateway upon finding a message on the message bus matching the message filter.