A method of developing a product is provided that includes generating a digital system model (DSM) that describes the product and a manufacturing process for the product, and generating a digital twin (DTw) of an instance of a component of the manufacturing process, the DTw including a digital replica of the instance. The method includes receiving attribute data for attributes of process/process characteristics subject to sources of variation that affect product quality. The digital replica is executed with input of the attribute data, and thereby updating the DTw to replicate the instance of the component of the manufacturing process as performed. A data analysis of the manufacturing process is performed based on the DTw as updated, and the manufacturing process is modified based on the data analysis to reduce variability in one or more product characteristics. The DTws of multiple instances may be used to generate further improvement.

A design supporting apparatus includes an acquisition unit that acquires information regarding a design change, and an output unit that outputs information indicating that the design change is able to be coped with in a case where the design change is able to be coped with through replacement of a tool or a component with respect to a facility in the current manufacturing line, and outputs information indicating that the design change is not able to be coped with in a case where the design change is not able to be coped with even through replacement of the tool or the component with respect to the facility in the current manufacturing line.

A design supporting apparatus includes an acquisition unit that acquires information regarding a design change, and an output unit that outputs information indicating that the design change is able to be coped with in a case where the design change is able to be coped with through replacement of a tool or a component with respect to a facility in the current manufacturing line, and outputs information indicating that the design change is not able to be coped with in a case where the design change is not able to be coped with even through replacement of the tool or the component with respect to the facility in the current manufacturing line.

A computer system can automatically resolve anomalies within an architectural design by receiving a digital architectural design comprising a first furniture sub-component, a second furniture sub-component, and a third furniture sub-component. The system can then identify one or more joints between the various furniture sub-components. After identifying the joints, the system can include identifying an anomaly at the intersection of the joints. The anomaly can be created when the joints fail to create a proper corner. The system can then automatically resolve the anomaly by changing the type of at least one of the joints within the digital architectural design.

Methods and systems allow for creating a variable spatial framework for use in designing and manufacturing an architectural component. The spatial framework can define a three-dimensional space having a plurality of boundaries. The system can receive an input to divide the three-dimensional space into multiple independent cells. Each independent cell can comprise an independently executable software object. A plurality of boundaries of the spatial framework can automatically adjust upon receiving an input defining a manufacturing constraint.

A method for design data change control and solution generation for an electromechanical product is provided. A first change event is received. The first change event includes a first change priority. If the first change priority is higher than a second change priority of a second change event that is currently executed, and a change buffer time of the second change event ends or execution of the second change event is completed within the change buffer time, design data of the electromechanical product is changed based on the first change event to obtain a change result. The change buffer time is configured to characterize a time during which the second change event is able to be continuously executed when switching to a change event with a higher execution priority. An electromechanical product design solution is generated based on the change result.