Systems and techniques that facilitate electronic generation of three-dimensional quantum circuit diagrams are provided. In various embodiments, a system can comprise a data component that can access qubit topology data characterizing a quantum computing device. In various aspects, the system can further comprise a rendering component that can render a three-dimensional quantum circuit diagram based on the qubit topology data. In various instances, the qubit topology data can indicate which qubits of the quantum computing device are coupled together. In various cases, the rendering component can render the three-dimensional quantum circuit diagram by generating a two-dimensional qubit configuration model of the quantum computing device based on which qubits of the quantum computing device are coupled together, by extruding one or more qubit lines three-dimensionally outward from the two-dimensional qubit configuration model, and by rendering one or more quantum gates on the one or more qubit lines.

An information processing apparatus (10) is for supporting work by a user who uses drawings for a plant. The information processing apparatus (10) includes a controller (15). The controller (15) is configured to convert a drawing including elements configuring the plant into an abstract model represented by element information indicating the elements and connection information indicating a connection relationship between the elements. The controller (15) is configured to generate display information, when it is judged that a difference exists between one abstract model based on one drawing and another abstract model based on another drawing, for displaying the differing portion in a different form than another portion.

A method for augmenting a three-dimensional model of a component in a computer-aided design (CAD) includes receiving a three-dimensional CAD model of the component. The three-dimensional CAD model includes a plurality of component surfaces. The method further includes generating a first three-dimensional surface representation of a first component surface of the plurality of component surfaces and indexing the first three-dimensional surface representation as a first function-attributed surface (FAS) element by assigning the first three-dimensional surface representation a unique first FAS ID which associates the first FAS element with the component.

A method for augmenting a three-dimensional model of a component in a computer-aided design (CAD) environment includes indexing a first three-dimensional surface representation of a first component surface of the three-dimensional CAD model as a first function-attributed surface (FAS) element by assigning the first three-dimensional surface representation a unique first FAS ID which associates the first FAS element with the component. The first component surface is one of a plurality of component surfaces of the three-dimensional CAD model of the component. The method further includes storing at least one first scalar attribute for the first FAS element as a first FAS dataset and assigning the unique first FAS ID to the first FAS dataset. The method further includes configuring the three-dimensional CAD model to display a FAS tree that includes a plurality of FAS elements associated with the component.

A computer-based method is disclosed for creating and/or editing a feature control frame (FCF) for geometric dimensioning & tolerancing (GD&T) of a model in a computer-aided design (CAD) program. The method includes displaying, in a graphics area of the CAD program, a cell of a FCF for a geometric feature of the model, displaying a context menu adjacent to the cell of the FCF, wherein the context menu comprises a first plurality of user-selectable input options associated with GD&T information for the geometric feature, receiving a user selection of one of the first plurality of user-selectable input options, and subsequently presenting a second plurality of user-selectable input options associated with GD&T information for the geometric feature. The options included in the second plurality of user-selectable input options depend, at least in part, on which of the first plurality of user-selectable input options the user selected.

A method of generating a layout diagram of an IC device includes assigning a leakage constraint to a first schematic net of the IC device and determining a violation of the leakage constraint based on a dummy gate region. The IC layout diagram includes the dummy gate region between a first component of the first schematic net and a second component of a second schematic net of the IC device. The method includes modifying the IC layout diagram in response to the leakage constraint violation, and generating a layout file based on the modified IC layout diagrams.

Automated circuit and layout generation is disclosed. Various embodiments may include a computer system and/or method for generating a circuit layout comprising specifying a circuit schematic to be converted to a circuit layout, receiving a layout script associated with the circuit schematic, the layout script configured to position a plurality of layout instances generated from the circuit schematic, converting the circuit schematic into the plurality of layout instances; and positioning the plurality of layout instances based on the layout script to produce the circuit layout. A circuit may be produced by fabricating a circuit using the layout.

A system and method are provided to enable non-quantum experts to schematically represent, simulate and quantify the performance of physically realistic photonic quantum circuits. The framework offers the flexibility for users—not necessarily familiar with the fundamentals of quantum mechanics—to create circuits and work with simple inputs and outputs, while the complexities of manipulating high dimensionality quantum Hilbert spaces supporting photonic and physical quantum object states are handled with the use of purpose-built tools. The tools include a user-friendly method for defining classical photonic circuits which may be coupled to physical objects such as qubits, quantum input states, as well as classical and quantum measurement devices. The tools feature classical-to-quantum S-matrix conversion, quantum S-matrix extraction, as well as capabilities for defining and extracting quantum error parameters. The framework also supports extraction of post-measurement quantum states for use in subsequent circuits or simulators.

In a method of making work plans for construction machinery, information of the construction machinery at a work site is obtained. The information of the construction machinery is received via a wireless communication. The information of the construction machinery is displayed on a display portion of a server. A work plan of the construction machinery is created on the display portion of the server by using the information of the construction machinery and information stored in the server. The work plan is transmitted to the construction machinery.

An example computing platform is configured to (i) maintain a three-dimensional, federated model of a construction project, where the model includes respective objects created using at least two different authoring tools, (ii) receive, via a client device installed with a viewing tool for displaying the model, one or more user inputs that collectively (a) select a displayed representation of a given object within the model and (b) assign a value for a property of the given object, (iii) based on the one or more inputs, identify a GUID of the given object within a hierarchical data structure for the model and cause the model to be updated by associating the assigned value for the property with the GUID of the given object, and (iv) cause the client device to display, via the viewing tool, the updated model including an indication of the assigned value for the property of the given object.