Type(s) de contenu et mode(s) de consultation : Texte noté : électronique

Auteur(s) : Rao, R. Venkata  Voir les notices liées en tant qu'auteur

Titre(s) : Mechanical Design Optimization Using Advanced Optimization Techniques [Texte électronique] / by R. Venkata Rao, Vimal J. Savsani

Édition : 2012

Publication : London : Springer London, 2012

Description matérielle : 1 online resource

Collection : Springer Series in Advanced Manufacturing

Note(s) : Mechanical design includes an optimization process in which designers always consider objectives such as strength, deflection, weight, wear, corrosion, etc. depending on the requirements. However, design optimization for a complete mechanical assembly leads to a complicated objective function with a large number of design variables. It is a good practice to apply optimization techniques for individual components or intermediate assemblies than a complete assembly. Analytical or numerical methods for calculating the extreme values of a function may perform well in many practical cases, but may

Autre(s) auteur(s) : Savsani, Vimal J.. Fonction indéterminée  Voir les notices liées en tant qu'auteur

Sujet(s) : Ingénierie  Voir les notices liées en tant que sujet
Algorithmes  Voir les notices liées en tant que sujet
Conception technique  Voir les notices liées en tant que sujet
Génie industriel  Voir les notices liées en tant que sujet

Indice(s) Dewey :  670 (23e éd.) = Fabrication industrielle  Voir les notices liées en tant que sujet ; 620.004 2 (23e éd.) = Ingénierie et activités connexes - Conception technique  Voir les notices liées en tant que sujet

Identifiants, prix et caractéristiques : ISBN 9781447127482

Identifiant de la notice  : ark:/12148/cb44663099x

Notice n° :  FRBNF44663099 (notice reprise d'un réservoir extérieur)

Table des matières : Mechanical DesignOptimization Using Advanced Optimization Techniques; Preface; Contents; 1 Introduction; 2 Advanced Optimization Techniques; 2.1 ... Genetic Algorithm; 2.1.1 Selection; 2.1.2 Crossover; 2.1.3 Mutation; 2.2 ... Artificial Immune Algorithm; 2.3 ... Differential Evolution; 2.4 ... Biogeography-Based Optimization; 2.4.1 Migration; 2.4.2 Mutation; 2.5 ... Particle Swarm Optimization; 2.5.1 Modifications in PSO; 2.6 ... Artificial Bee Colony Algorithm; 2.6.1 Modifications in ABC; 2.7 ... Harmony Elements Algorithm; 2.7.1 Modifications in HEA; 2.8 ... Hybrid Algorithms; 2.8.1 HPABCHPABC; 2.8.2 HBABCHBABC.
2.8.3 HDABCHDABC2.8.4 HGABCHGABC; 2.9 ... Shuffled Frog Leaping Algorithm; 2.10 ... Grenade Explosion Algorithm; References; 3 Mechanical Design Optimization Using the Existing Optimization Techniques; 3.1 ... Description of Different Mechanical Design Optimization Problems; 3.1.1 Example 1: Optimization of a Gear Train; 3.1.2 Example 2: Optimization of a Radial Ball Bearing; 3.1.3 Example 3: Optimization of a Belleville SpringBelleville spring; 3.1.4 Example 4: Optimization of a Multiple Disc Clutch Brake; 3.1.5 Example 5: Optimization of a Robot Gripper.
3.1.6 Example 6: Optimization of a Hydrodynamic Thrust Bearing3.1.7 Example 7: Discrete Optimization of a Four Stage Gear Train; 3.2 ... Applications of Advanced Optimization Techniques to Different Design Optimization Problems of Mechanical Elements; 3.2.1 Example 1: Optimization of Gear Train; 3.2.2 Example 2: Optimization of Radial Ball Bearing; 3.2.3 Example 3: Optimization of Belleville SpringBelleville spring; 3.2.4 Example 4: Optimization of Multiple Disc Clutch Brake; 3.2.5 Example 5: Optimization of a Robotic Gripper; 3.2.6 Example 6: Optimization of a Hydrostatic Thrust Bearing.
3.2.7 Example 7: Discrete Optimization of a Four Stage Gear TrainReferences; 4 Applications of Modified Optimization Algorithms to the Unconstrained and Constrained Problems; 4.1 ... Unconstrained Benchmark Functions (BM-UC); 4.2 ... Constrained Benchmark Functions (BM-C); 4.3 ... Additional Mechanical Element Design Optimization Problems (MD); 4.3.1 Example 8: Design of Pressure Vessel; 4.3.2 Example 9: Design of Welded Beam; 4.3.3 Example 10: Design of Tension/Compression Spring; 4.3.4 Example 11: Design of a Speed ReducerSpeed reducer; 4.3.5 Example 12: Design of Stiffened Cylindrical Shell.
4.3.6 Example 13: Design of Step Cone Pulley4.3.7 Example 14: Design of Screw Jack; 4.3.8 Example 15: Design of C-ClampC-clamp; 4.3.9 Example 16: Design of Hydrodynamic Bearing; 4.3.10 Example 17: Design of Cone Clutch; 4.3.11 Example 18: Design of Cantilever Support; 4.3.12 Example 19: Design of Hydraulic Cylinder; 4.3.13 Example 20: Design of Planetary Gear Train; 4.4 ... Applications of Modified PSOModified PSO; 4.5 ... Applications of Modified ABCModified ABC; 4.6 ... Applications of Modified HEAModified HEA; References.