Exemplified methods and systems facilitate presentation of data derived from measurements of the heart in a non-invasive procedure (e.g., via phase space tomography analysis). In particular, the exemplified methods and systems facilitate presentation of such measurements in a graphical user interface, or GUI (e.g., associated with a healthcare provider web portal to be used by physicians, researchers, or patients, and etc.) and/or in a report for diagnosis of heart pathologies and disease. The presentation facilitates a unified and intuitive visualization that includes three-dimensional visualizations and two-dimensional visualizations that are concurrently presented within a single interactive interface and/or report.

Exemplified methods and systems facilitate presentation of data derived from measurements of the heart in a non-invasive procedure (e.g., via phase space tomography analysis). In particular, the exemplified methods and systems facilitate presentation of such measurements in a graphical user interface, or GUI (e.g., associated with a healthcare provider web portal to be used by physicians, researchers, or patients, and etc.) and/or in a report for diagnosis of heart pathologies and disease. The presentation facilitates a unified and intuitive visualization that includes three-dimensional visualizations and two-dimensional visualizations that are concurrently presented within a single interactive interface and/or report.

Exemplified methods and systems facilitate presentation of data derived from measurements of the heart in a non-invasive procedure (e.g., via phase space tomography analysis). In particular, the exemplified methods and systems facilitate presentation of such measurements in a graphical user interface, or GUI (e.g., associated with a healthcare provider web portal to be used by physicians, researchers, or patients, and etc.) and/or in a report for diagnosis of heart pathologies and disease. The presentation facilitates a unified and intuitive visualization that includes three-dimensional visualizations and two-dimensional visualizations that are concurrently presented within a single interactive interface and/or report.

An API classification unit (231) extracts as omittable internal data processing, from among internal data processing included in execution data processing which is data processing executed by an outside data processing device which is a data processing device outside, internal data processing that is required to be executed when the outside data processing device executes the execution data processing, but is omittable from the execution when a data processing apparatus (10) executes the execution data processing, due to a difference in an execution environment between the outside data processing device and the data processing apparatus (10). An execution unit (235) executes the execution data processing while omitting the execution of the omittable internal data processing extracted by the API classification unit (231).

An automation system includes at least one field device and at least one control unit. The automation system is configured to provide an application interface via which a data transfer of administration data for administration of the at least one field device can be performed from the at least one control unit to the at least one field device.

A motor control wizard implements a simple workflow for creating an application-specific program for operation of a motor control system. The wizard prompts for selection of an application area, which sensitizes the system to tune certain motor control parameters in accordance with the demands of the selected application area. The wizard also prompts for selection of a target devices, such as a particular type of motor with a set of basic operating parameters. With the target device and application area known, the wizard runs an automatic adaptation step without requiring additional user-settable parameters. The adaptation step yields an adapted motor control program based characteristics of the motor control system obtained via the adaptation step. The wizard then confirms operation of the motor using the adapted program. Additional features allow the user to fine tune parameters beyond this set of initial configuration parameters.

Exemplified methods and systems facilitate presentation of data derived from measurements of the heart in a non-invasive procedure (e.g., via phase space tomography analysis). In particular, the exemplified methods and systems facilitate presentation of such measurements in a graphical user interface, or GUI (e.g., associated with a healthcare provider web portal to be used by physicians, researchers, or patients, and etc.) and/or in a report for diagnosis of heart pathologies and disease. The presentation facilitates a unified and intuitive visualization that includes three-dimensional visualizations and two-dimensional visualizations that are concurrently presented within a single interactive interface and/or report.

A motor control wizard implements a simple workflow for creating an application-specific program for operation of a motor control system. The wizard prompts for selection of an application area, which sensitizes the system to tune certain motor control parameters in accordance with the demands of the selected application area. The wizard also prompts for selection of a target devices, such as a particular type of motor with a set of basic operating parameters. With the target device and application area known, the wizard runs an automatic adaptation step without requiring additional user-settable parameters. The adaptation step yields an adapted motor control program based characteristics of the motor control system obtained via the adaptation step. The wizard then confirms operation of the motor using the adapted program. Additional features allow the user to fine tune parameters beyond this set of initial configuration parameters.

Embodiments of the disclosure relate to real-time debugging systems and methods. In one embodiment, a system that includes a server module and a client module can be provided. The server module can be executable on a first computer and can be adapted to use a native communications format for interactive transfer of industrial automation data between the first computer and at least one industrial automation element. The client module, which can be executable on the same computer as the server module or on a different computer, can include a debugging application configured to use a universal communications format for communicatively interacting with the server module for accessing the industrial automation data and debugging one or more programming portions associated with the industrial automation data.

Client-side endpoint configuration can be accomplished by allowing a client to include as part of an API request, a desired endpoint for subsequent notifications from a server. The endpoint can be an endpoint identifier, such as a Uniform Resource Identifier (URI) or a domain name. When a web service receives the API request from a client device, the web service can generate a response to the request and send the response to the endpoint identified in the request. The API request can asynchronously communicate with the client device whenever the response is completed.