A method for automated manufacturing strategy generation can include: identifying features of a desired part from a virtual model; and determining a tactic strategy based on the identified features. The method can additionally include: determining a toolpath primitive for each tactic; combining the toolpath primitives for the tactics to generate a master toolpath; and translating the master toolpath into machine code.

Provided is a technique for converting an NC program into an NC program capable of ensuring appropriate precision in working while avoiding the occurrence of differences in levels caused by correction during the cutting of a cut surface of a workpiece. In the NC program conversion processing method to convert a conversion source NC program (1424) and generate a conversion result NC program (1425), the method includes based on a plurality of blocks in the conversion source NC program (1424), identifying a contactless portion tool path, which is a path on which a tool of a work machine executing the conversion source NC program does not come into contact with a workpiece during the processes corresponding to the blocks; identifying contactless blocks, which are the blocks having only the contactless portion tool path as a path; determining the tool route correction quantity in the tool radial direction in a work process of the workpiece according to the following blocks, which are one or more of the blocks following the contactless blocks; and creating blocks including descriptions for correcting the tool route by the tool route correction quantity, before the following blocks.

A numerical controller which performs program restart after machining is stopped in the middle of a machining cycle is provided with a program restart unit. The numerical controller can use the program restart unit to acquire a restart position located in a machining area defined by the machining cycle, create a new machining area by dividing the defined machining area in the restart position, and restart the machining for the new machining area.

A method for automated manufacturing strategy generation can include: identifying features of a desired part from a virtual model; and determining a tactic strategy based on the identified features. The method can additionally include: determining a toolpath primitive for each tactic; combining the toolpath primitives for the tactics to generate a master toolpath; and translating the master toolpath into machine code.

A method for automated manufacturing strategy generation can include: identifying features of a desired part from a virtual model; and determining a tactic strategy based on the identified features. The method can additionally include: determining a toolpath primitive for each tactic; combining the toolpath primitives for the tactics to generate a master toolpath; and translating the master toolpath into machine code.

A system and method capable of encoding design intent for an article of manufacture wherein the original design intent encoding is abstract from any particular manufacturing process or machine, but allows for dynamic process adjustment accounting for real-world variations of stock material such that the design intent is preserved and the processing time and effort are not significantly affected. Because design intent is preserved, tool selection and machine process can be optimized to maximize quality and minimize manufacturing time and cost.

A system and method capable of encoding design intent for an article of manufacture wherein the original design intent encoding is abstract from any particular manufacturing process or machine, but allows for dynamic process adjustment accounting for real-world variations of stock material such that the design intent is preserved and the processing time and effort are not significantly affected. Because design intent is preserved, tool selection and machine process can be optimized to maximize quality and minimize manufacturing time and cost.

A numerical controller which performs program restart after machining is stopped in the middle of a machining cycle is provided with a program restart unit. The numerical controller can use the program restart unit to acquire a restart position located in a machining area defined by the machining cycle, create a new machining area by dividing the defined machining area in the restart position, and restart the machining for the new machining area.

Provided is a control apparatus and a control method capable of satisfying the demand for both of processing speed and control accuracy in a case in which control following a target trajectory is executed by sequentially executing an application program. The control apparatus an instruction value output unit that outputs an instruction value for each control period and a command interpreting unit that sequentially interprets an application program and generates an internal command. The command interpreting unit calculates a passage point on the target trajectory for each period set in advance and generates the internal command in accordance with calculated passage points and changes a period at which the passage points are calculated to a length designated by a special command in a case in which the special command defined in advance is executed in the sequential interpretation of the application program.

A method and control apparatus for generating control data for controlling a tool on a machine tool for machining a clamped-in workpiece, the machine tool having a control apparatus and a tool for controlling the tool, comprising: generating a path program using a setpoint geometry of generated setpoint parameters, the path program describing a path having supporting points and line elements; controlling the machine tool according to the generated path program; detecting actual parameters by a feedback loop; iteratively optimizing the path program using the detected actual parameters for generating a new path program with a new path, the new path program being dynamically supplied in real time and the new path program dynamically changing and/or dynamically replacing the previous path program; providing CAM functionality for changing an order of the supporting points; and embodying both the path program and the new path program as a CNC program.