Abstract: Technical solutions are described for visually depicting health of a cognitive system. An example computer-implemented method includes accessing a query-log of a question input to the cognitive system. The method also includes generating a query-node corresponding to the question. The method also includes configuring animation parameters of the query-node based on the query-log. The method also includes displaying the query-node according to the animation parameters.

Abstract: Technical solutions are described for representing health of a cognitive system. An example computer-implemented method includes displaying an animated set of icons, each icon representing a question input to the cognitive system. Each icon has a respective movement pattern. The computer-implemented method also includes receiving a selection of a first icon from the animated set of icons. The computer-implemented method also includes in response, identifying a category of a first question corresponding to the first icon, determining a subset of the icons corresponding to question from the category, and displaying connectors between the subset of the icons.

Abstract: An approach is provided that selects three attributes that correspond to objects included in a dataset, where each of the three attributes is assigned to a different coordinate value (x, y, and z coordinates). The approach creates a simulated three dimensional (3D) scene of the objects on a display screen by using the x, y, and z coordinate values corresponding to the attributes of each of the objects. The approach further displays, on a 2D screen, a gyroscopic graphical user interface (GUI) that provides three dimensional (3D) control of the simulated 3D scene. In the approach, a gesture from a user receiving at the gyroscopic GUI. Responsively, the approach adjusts the 3D scene displayed on the 2D screen based on the gesture that was received.

Abstract: An approach is provided that displays, on a two dimensional (2D) screen, a gyroscopic graphical user interface (GUI). The gyroscopic GUI provides three dimensional (3D) control of a simulated 3D scene displayed on the 2D screen. In the approach, a gesture from a user receiving at the gyroscopic GUI. Responsively, the approach adjusts the 3D scene displayed on the 2D screen based on the gesture that was received.

Abstract: An approach is provided that displays, on a two dimensional (2D) screen, a gyroscopic graphical user interface (GUI). The gyroscopic GUI provides three dimensional (3D) control of a simulated 3D scene displayed on the 2D screen. In the approach, a gesture from a user receiving at the gyroscopic GUI. Responsively, the approach adjusts the 3D scene displayed on the 2D screen based on the gesture that was received.

Abstract: An approach is provided that selects three attributes that correspond to objects included in a dataset, where each of the three attributes is assigned to a different coordinate value (x, y, and z coordinates). The approach creates a simulated three dimensional (3D) scene of the objects on a display screen by using the x, y, and z coordinate values corresponding to the attributes of each of the objects. The approach further displays, on a 2D screen, a gyroscopic graphical user interface (GUI) that provides three dimensional (3D) control of the simulated 3D scene. In the approach, a gesture from a user receiving at the gyroscopic GUI. Responsively, the approach adjusts the 3D scene displayed on the 2D screen based on the gesture that was received.

Abstract: Technical solutions are described for visually depicting health of a cognitive system. An example computer-implemented method includes accessing a query-log of a question input to the cognitive system. The method also includes generating a query-node corresponding to the question. The method also includes configuring animation parameters of the query-node based on the query-log. The method also includes displaying the query-node according to the animation parameters.

Abstract: Technical solutions are described for representing health of a cognitive system. An example computer-implemented method includes displaying an animated set of icons, each icon representing a question input to the cognitive system. Each icon has a respective movement pattern. The computer-implemented method also includes receiving a selection of a first icon from the animated set of icons. The computer-implemented method also includes in response, identifying a category of a first question corresponding to the first icon, determining a subset of the icons corresponding to question from the category, and displaying connectors between the subset of the icons.