An information processing apparatus includes a processor, and the processor is configured to: acquire three-dimensional image data for printing processing for modeling a three-dimensional modeled object by forming respective images on recording media and stacking the recording media, and other image data for other printing processing, determine an arrangement to form at least one of the respective images and at least a part of the other image data on same one of the recording media so as to reduce a difference between a height corresponding to the number of recording media to which the other image data is to be recorded and a height of the three-dimensional modeled object, and output image forming information for forming the three-dimensional image data and the other image data on the recording media to an image forming apparatus based on the determined arrangement.

A machining program generation support device includes: a CAD data analysis unit which analyzes the CAD data so as to obtain CAD shape information; a machining program analysis unit which. analyzes the machining program in the middle of being produced so as to obtain machining shape information in the middle of being produced; a shape matching unit which performs matching of shapes of the CAD shape information and the machining shape information in the middle of being produced so as to obtain. matching shape information; and a candidate shape program generation unit that predicts, based on the CAD shape information, a candidate shape following the matching shape information, and that thereby predicts a candidate shape following the machining shape information in the middle of being produced so as to automatically generate a machining program for the candidate shape following the machining program in the middle of being produced.

In accordance with some embodiments, systems, methods, and media for controlling support structures and build orientation are provided. In some embodiments, a method for additive manufacturing a part using a three dimensional (3D) printing system, the 3D printing system including a print head and a build plate is provided, the method comprising: receiving a plurality of physical constraints associated with the part; optimizing a build orientation of the part to identify an optimized build orientation b* for the part with respect to a design domain defined by the physical constraints based on the plurality of physical constraints, and a plurality of design constraints using at least one variable associated with build orientation as an optimization variable, the plurality of design constraints comprising: an initial build orientation b.sup.0; and a critical surface slope angle and generating a part model based on the optimized build orientation b*.

A manufacturing system is disclosed herein. The manufacturing system includes one or more stations, a monitoring platform, and a control module. Each station of the one or more stations is configured to perform at least one step in a multi-step manufacturing process for a component. The monitoring platform is configured to monitor progression of the component throughout the multi-step manufacturing process. The control module is configured to dynamically adjust processing parameters of each step of the multi-step manufacturing process to achieve a desired final quality metric for the component.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for determining a suitable building layout for a property. One of the operations is performed by optionally, receiving building module parameters for section of qualifying building modules. displaying, via a user interface, a graphical representation of two or more building modules. A user may customize a building layout from the two or more building modules. The system displays an assembled building layout including two or more building modules. The system receives a confirmation of the assembled building layout for 3D printing. Based on the assembled building layout, instructions are generated and transmitted to one or more 3D printers to manufacture one or more building structures based on the selected building layout with potential subsequent modification of the preconfigured positions of windows, doors and walls of the building.

According to a laser cutting method, a processed part is laser-cut so that the processed part doesn't drop off from a sheet-shaped workpiece. In the laser cutting method, a cut slit of a pressing protrusion, which is curved due to a laser cutting process along an outline of the processed part and then presses a peripheral surface of the processed part, is preliminarily formed around the processed part to be cut out from the workpiece. Then, the laser cutting process is carried out along the outline of the processed part. The pressing protrusion curves toward the processed part due to the laser cutting process of the processed part, and then the processed part is retained by the pressing protrusion.

A sewn product making apparatus such as a sewing robot can be used to produce a variety of products over a broad range of sizes, shapes or materials. Various examples are provided related to the automation of sewing robots, and the making of sewn products. In one example, among others, a system can generate a product making path using a product construction file, and instruct a sewing device and fabric mover(s) to automatically sew the product based upon the product making path. The product making path can be modified when a deviation is detected, and the sewing adjusted based upon the modified product making path. The product construction file can be generated using information from a computer aided design associated with the product.

An information processing apparatus includes a processor, and the processor is configured to acquire, in printing processing for modeling a three-dimensional modeled object by forming respective images on recording media and stacking the recording media, a print job including at least one of two-dimensional image data for forming a two-dimensional image and three-dimensional image data for modeling a three-dimensional modeled object, an instruction of a user for the print job, and attribute information of a plurality of printing apparatuses that are candidates to perform the print job, and select a printing apparatus to perform the acquired print job from the plurality of printing apparatuses based on whether the image data contained in the print job is two-dimensional image data or three-dimensional image data, the attribute information, and the instruction of the user.

An information processing apparatus includes a processor, and the processor is configured to: acquire three-dimensional image data for printing processing for modeling a three-dimensional modeled object by forming respective images on recording media and stacking the recording media, and other image data for other printing processing, determine an arrangement to form at least one of the respective images and at least a part of the other image data on same one of the recording media so as to reduce a difference between a height corresponding to the number of recording media to which the other image data is to be recorded and a height of the three-dimensional modeled object, and output image forming information for forming the three-dimensional image data and the other image data on the recording media to an image forming apparatus based on the determined arrangement.

Examples disclosed herein relate to determining 3D print part placement. In one implementation, a processor generates a user interface to receive user input related to multiple divisions of 3D print parts and a relative ordering between the divisions. The processor may determine part placement information for the parts in the divisions in a 3D print build area based on user input to the user interface. The processor may translate the determined part placement information into 3D printer instructions.