The minimum zone tolerance is a non linear method to find a global solution to the roundness evaluation problem. Metaheuristics such as genetic algorithms, ant colony systems and particle swarm optimization concurrently process a set of solution candidates (chromosomes, ants, particles etc.) within a given search-space. Computation experiments carried out with an effective genetic algorithm have shown that the optimal sampling strategy providing sufficient accuracy at acceptable processing time represents a compromise between number of sample points and search-space size. An estimate of the neighborhood of the centroid containing the minimum zone center is given
In order to compute geometric tolerances, the distance between the actual geometry and the nominal o...
As far as machine parts are concerned, accuracy can be defined in many aspects. In order for a workp...
The paper presents a novel heuristic procedure (further called the AH Method) to investigate functio...
Roundness is one of the most common features in machining. The minimum zone tolerance (MZT) approach...
According to ISO 1101, “A geometrical tolerance applied to a feature defines the tolerance zone with...
Roundness is one of the most common features in machining. The minimum zone tolerance (MZT) approach...
Roundness is one of the most common features in machining, and various criteria may be used for roun...
MESH is an ε-approximate algorithm to find the minimum zone center of a given roundness profile, wit...
The minimum zone tolerance (MZT) meets the ISO 1101 definition of roundness error: it determines two...
Roundness is one of the most common features in machining, and various criteria may be used for roun...
The minimum zone sphericity tolerance is derived from the ANSI and ISO standards for roundness and h...
Form deviation of machined components need to be controlled within the required tolerance values for...
Estimating any geometric tolerance requires to sample a cloud of points on the feature to check, and...
AbstractWhether roundness error can be evaluated accurately and efficiently or not will directly inf...
The form error evaluation of cylinders and cones is very important in precision coordinate metrology...
In order to compute geometric tolerances, the distance between the actual geometry and the nominal o...
As far as machine parts are concerned, accuracy can be defined in many aspects. In order for a workp...
The paper presents a novel heuristic procedure (further called the AH Method) to investigate functio...
Roundness is one of the most common features in machining. The minimum zone tolerance (MZT) approach...
According to ISO 1101, “A geometrical tolerance applied to a feature defines the tolerance zone with...
Roundness is one of the most common features in machining. The minimum zone tolerance (MZT) approach...
Roundness is one of the most common features in machining, and various criteria may be used for roun...
MESH is an ε-approximate algorithm to find the minimum zone center of a given roundness profile, wit...
The minimum zone tolerance (MZT) meets the ISO 1101 definition of roundness error: it determines two...
Roundness is one of the most common features in machining, and various criteria may be used for roun...
The minimum zone sphericity tolerance is derived from the ANSI and ISO standards for roundness and h...
Form deviation of machined components need to be controlled within the required tolerance values for...
Estimating any geometric tolerance requires to sample a cloud of points on the feature to check, and...
AbstractWhether roundness error can be evaluated accurately and efficiently or not will directly inf...
The form error evaluation of cylinders and cones is very important in precision coordinate metrology...
In order to compute geometric tolerances, the distance between the actual geometry and the nominal o...
As far as machine parts are concerned, accuracy can be defined in many aspects. In order for a workp...
The paper presents a novel heuristic procedure (further called the AH Method) to investigate functio...