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100   $a20141106h20152015  uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aEssentials of vehicle dynamics /$fJoop P. Pauwelussen
205   $a1st edition
210  1$aOxford, England :$cButterworth-Heinemann,$d2015.
210  4$dİ2015
215   $a1 online resource (320 p.)
300   $aDescription based upon print version of record.
311   $a1-322-26372-8 
311   $a0-08-100036-7 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Essentials of Vehicle Dynamics; Copyright Page; Dedication; Contents; Preface; 1 Introduction; 2 Fundamentals of Tire Behavior; 2.1 Tire Input and Output Quantities; 2.2 Free Rolling Tire; 2.3 Rolling Resistance; 2.3.1 Braking/Driving Conditions; 2.3.2 Parasitary Forces: Toe and Camber; 2.3.3 Temperature; 2.3.4 Forward Speed; 2.3.5 Inflation Pressure; 2.3.6 Truck Tires Versus Passenger Car Tires; 2.3.7 Radial Versus Bias-Ply Tires; 2.3.8 Other Effects; 2.4 The Tire Under Braking and Driving Conditions; 2.4.1 Braking Behavior Explained; 2.4.2 Modeling Longitudinal Tire Behavior
327   $a2.5 The Tire Under Cornering Conditions2.5.1 Cornering Behavior Explained; 2.5.2 Modeling Lateral Tire Behavior; 2.6 Combined Cornering and Braking/Driving; 2.6.1 Combined Slip; 2.6.2 Modeling Tire Behavior for Combined Slip; 2.6.3 Approximations in case of Combined Slip; 2.7 Physical Tire Models; 2.7.1 The Brush Model; 2.7.2 The Brush-String Model; 3 Nonsteady-State Tire Behavior; 3.1 Tire Transient Behavior; 3.1.1 The Tire Transient Model; 3.1.2 Applications of the Tire Transient Model; Shimmy of A Trailing Wheel; Single Wheel Vehicle Under Repetitive Braking
327   $a3.2 Dynamic Tire Response to Road Disturbances3.2.1 Introduction to the Rigid Ring Tire Model; 3.2.2 Enveloping Properties of Tires to Road Disturbances; 3.2.3 Dynamic Response to Road Disturbances; 4 Kinematic Steering; 4.1 Axis Systems and Notations; 4.2 Ackermann Steering; 4.3 The Articulated Vehicle; 5 Vehicle Handling Performance; 5.1 Criteria for Good Handling; 5.1.1 ISO 4138: Steady-State Circular Test; 5.1.2 ISO 7401: Lateral Transient Response Test; 5.2 Single-Track Vehicle Modeling; 5.2.1 The Single-Track Model; Remarks Regarding Forces Acting on the Vehicle
327   $a5.2.2 Effect of Body Roll and Lateral Load TransferContact Forces According to Genta and Morello; Contact Forces According to Kiencke and Nielsen; 5.2.3 Alignment and Compliance Effects; 5.2.4 Effect of Combined Slip; 5.3 Steady-State Analysis; 5.3.1 Steady-State Solutions; Remark; 5.3.2 Understeer and Oversteer; Definition 1; Definition 2; Definition 3; Definition 4; 5.3.3 Neutral Steer Point; 5.4 Nonsteady-State Analysis; 5.4.1 Yaw Stability; Ad (i); Ad (ii); Ad (iii); 5.4.2 Frequency Response; 5.5 Graphical Assessment Methods; 5.5.1 Phase Plane Analysis; 5.5.2 Stability Diagram
327   $a5.5.3 The Handling Diagram5.5.4 The MMM Diagram; 5.5.5 The g-g Diagram; 6 The Vehicle-Driver Interface; 6.1 Assessment of Vehicle-Driver Performance; The Inter-Beat-Interval; The Heart Rate Variability; Pupil Diameter and Endogenous Eye Blinks; Blood Pressure Variability; Skin Conduction Response; Facial Muscle Activity; 6.2 The Vehicle-Driver Interface, A System Approach; 6.2.1 Open-Loop and Closed-Loop Vehicle Behavior; 6.2.2 The McRuer Crossover Model; 6.3 Vehicle-Driver Longitudinal Performance; 6.3.1 Following a Single Vehicle; 6.3.2 Driver Model and Driver State Identification
327   $a6.4 Vehicle-Driver Handling Performance
330   $a Essentials of Vehicle Dynamics explains the essential mathematical basis of vehicle dynamics in a concise and clear way, providing engineers and students with the qualitative understanding of vehicle handling performance needed to underpin chassis-related research and development.  Without a sound understanding of the mathematical tools and principles underlying the complex models in vehicle dynamics, engineers can end up with errors in their analyses and assumptions, leading to costly mistakes in design and virtual prototyping activities. Author Joop P. Pauwelussen looks to rectify this by d
606   $aAutomobiles$xDynamics
606   $aMotor vehicles$xDynamics
615  0$aAutomobiles$xDynamics.
615  0$aMotor vehicles$xDynamics.
676   $a629.231
700   $aPauwelussen$b Joop$0891150
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910583466903321
996   $aEssentials of vehicle dynamics$91990474
997   $aUNINA