Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A system is provided for monitoring computing server performance using an artificial intelligence-based plugin. In particular, the system may be configured to continuously aggregate computing performance metric data of a computing device in the network, such as a server. The system may analyze the performance metric data using an artificial intelligence-based process to identify the hardware and/or software layers affected by computing workloads. Based on identifying the affected layers, the system may predict the impact of future workloads on the server and, based on the predictions, generate one or more recommendations for remediating server outages or downtime which may be caused by unanticipated volumes of network traffic, system calls, and the like. In this way, the system may provide an efficient way to optimize the use of computing resources within the network environment.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: Embodiments of the present invention provide a system for creating configurational blocks used for building continuous real-time software logical sequences. The system is configured for creating a set of configurational blocks associated with building one or more real-time software logical sequences, displaying the set of configurational blocks, via a graphical user interface to a user, allowing the user to select one or more configurational blocks from the set of configuration blocks, receiving the one or more configurational blocks and one or more links associated with connection of the one or more configurational blocks from the user, via the graphical user interface, and generating a continuous real-time software logical sequence based on the one or more configurational blocks and the one or more links received from the user.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A mobile application development device having a platform processor, a native application converter engine, and a mobile platform framework engine configured to facilitate the development and deployment of mobile applications configured to be run on different mobile operating systems from code that is developed independently and agnostic of the mobile operating system on which it will ultimately run.

Abstract: A computer-executable mechanism captures code modifications for a computer-executable process from a development environment into build packages that may be deployed onto specified target environments with trace, audit, code compliance and rollback options from one single web portal. The mechanism supports build package code changes from different sources, automated test of the resulting build packages, and phantom source control of all packaged code base to reduce the burden on developers to manually source control code. The computer-executable mechanism supports a portal web server for building and deploying build packages to render user responses to configurable actions that may be passed on to a job sequencer to execute a series of jobs. A computer-executable roll-back mechanism takes a snapshot of the target environment prior to deployment of a build package so that a complete release rollback or an incremental release rollback may occur as needed.

Abstract: A computer-executable mechanism captures code modifications for a computer-executable process from a development environment into build packages that may be deployed onto specified target environments with trace, audit, code compliance and rollback options from one single web portal. The mechanism supports build package code changes from different sources, automated test of the resulting build packages, and phantom source control of all packaged code base to reduce the burden on developers to manually source control code. The computer-executable mechanism supports a portal web server for building and deploying build packages to render user responses to configurable actions that may be passed on to a job sequencer to execute a series of jobs. A computer-executable roll-back mechanism takes a snapshot of the target environment prior to deployment of a build package so that a complete release rollback or an incremental release rollback may occur as needed.

Abstract: A computer-executable mechanism captures code modifications for a computer-executable process from a development environment into build packages that may be deployed onto specified target environments with trace, audit, code compliance and rollback options from one single web portal. The mechanism supports build package code changes from different sources, automated test of the resulting build packages, and phantom source control of all packaged code base to reduce the burden on developers to manually source control code. The computer-executable mechanism supports a portal web server for building and deploying build packages to render user responses to configurable actions that may be passed on to a job sequencer to execute a series of jobs. A computer-executable roll-back mechanism takes a snapshot of the target environment prior to deployment of a build package so that a complete release rollback or an incremental release rollback may occur as needed.

Abstract: A computer-executable mechanism captures code modifications for a computer-executable process from a development environment into build packages that may be deployed onto specified target environments with trace, audit, code compliance and rollback options from one single web portal. The mechanism supports build package code changes from different sources, automated test of the resulting build packages, and phantom source control of all packaged code base to reduce the burden on developers to manually source control code. The computer-executable mechanism supports a portal web server for building and deploying build packages to render user responses to configurable actions that may be passed on to a job sequencer to execute a series of jobs. A computer-executable roll-back mechanism takes a snapshot of the target environment prior to deployment of a build package so that a complete release rollback or an incremental release rollback may occur as needed.

Abstract: An axial flow gas turbine (20) includes a rotor (13) and a stator, and a hot gas path through which hot gas passes. The rotor (13) includes a rotor shaft (15) with axial slots for receiving a plurality of blades (B1-B3) arranged in a series of blade rows, with rotor heat shields (R1, R2) interposed between adjacent blade rows. The rotor shaft (15) is configured to axially conduct a main flow of cooling air along the rotor heat shields (R1, R2) and the lower parts of the blades (B1-B3), and the rotor shaft (15) supplies the interior of the blades (B1-B3) with cooling air (18). Stable and predictable cooling air parameters at any blade row inlet are secured by providing air-tight cooling channels (21), which extend axially through the rotor shaft (15) separate from the main flow of cooling air (17), and supply the blades (B1-B3) with cooling air (18).

Abstract: An axial flow gas turbine (20) includes a rotor (13) and a stator, and a hot gas path through which hot gas passes. The rotor (13) includes a rotor shaft (15) with axial slots for receiving a plurality of blades (B1-B3) arranged in a series of blade rows, with rotor heat shields (R1, R2) interposed between adjacent blade rows. The rotor shaft (15) is configured to axially conduct a main flow of cooling air along the rotor heat shields (R1, R2) and the lower parts of the blades (B1-B3), and the rotor shaft (15) supplies the interior of the blades (B1-B3) with cooling air (18). Stable and predictable cooling air parameters at any blade row inlet are secured by providing air-tight cooling channels (21), which extend axially through the rotor shaft (15) separate from the main flow of cooling air (17), and supply the blades (B1-B3) with cooling air (18).

Abstract: A stator heat shield (6) for a gas turbine (1) includes an outside (11) which in the installed state faces a hot gas path (9) of the gas turbine (1), and an inside (12) facing away from the outside (11). A plurality of ribs (13) are formed on the inside (12) and extend axially in the installed state with regard to an axis of rotation (8) of a rotor (3) of the gas turbine (1) and, in the circumferential direction, are spaced a distance apart from one another. At least one baffle plate (14) is arranged on the inside (12) and is in contact with the ribs (13). At least one groove (16) is designed in an end face (15) bordering the stator heat shield (6) in the circumferential direction, into which at least one sealing element (18) can be inserted. A plurality of bores (19) are included, each opening at a distance from the groove (16) in the direction of the outside (11) at the inside (12) at one end and on the end face (15) at the other end and arranged a distance apart from one another in the axial direction.

Abstract: A stator heat shield (6) for a gas turbine (1) includes an outside (11) which in the installed state faces a hot gas path (9) of the gas turbine (1), and an inside (12) facing away from the outside (11). A plurality of ribs (13) are formed on the inside (12) and extend axially in the installed state with regard to an axis of rotation (8) of a rotor (3) of the gas turbine (1) and, in the circumferential direction, are spaced a distance apart from one another. At least one baffle plate (14) is arranged on the inside (12) and is in contact with the ribs (13). At least one groove (16) is designed in an end face (15) bordering the stator heat shield (6) in the circumferential direction, into which at least one sealing element (18) can be inserted. A plurality of bores (19) are included, each opening at a distance from the groove (16) in the direction of the outside (11) at the inside (12) at one end and on the end face (15) at the other end and arranged a distance apart from one another in the axial direction.