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Written for the engineer as well as the race car enthusiast and students, this is a companion workbook to the original classic book, Race Car Vehicle Dynamics, and includes: Detailed worked solutions to all of the problems Problems for every chapter in Race Car Vehicle Dynamics, including many new problems The Race Car Vehicle Dynamics Program Suite (for Windows) with accompanying exercises Experiments to try with your own vehicle Educational appendix with additional references and course outlines Over 90 figures and graphs This workbook is widely used as a college textbook and has been an SAE International best seller since it's introduction in 1995. Buy the set and save! Race Car Vehicle Dynamics

This set includes: Race Car Vehicle Dynamics, Race Car Vehicle Dynamics - Problems, Answers and Experiments Purchase both the book and the workbook as a set and save!

Chassis Design: Principles and Analysis is based on Olley's technical writings, and is the first complete presentation of his life and work. This new book provides insight into the development of chassis technology and its practical application by a master. Many examples are worked out in the text and the analytical developments are grounded by Olley's years of design experience. Well-illustrated with over 400 figures and tables, as well as numerous appendices.

The MRA Moment Method computer program automates an original approach to the analysis of race car handling. For a given speed and power/braking condition, the computer solution covers the full maneuvering envelope and presents the results graphically in one figure. The model is based on a comprehensive nonlinear vehicle representation utilizing tire, chassis, and aerodynamic input data as available to race car designers and developers. The paper will first explain and illustrate the Moment Method in general terms, with some graphical examples. The ability of the technique to model the behavior of an F.1 car traversing a small bump in mid-corner on a Grand Prix circuit is then reviewed. The results correlate well with the driver comments relative to changes in directional stability (plow/spin) as the car pitches over the bump. It also correlates well with the lateral acceleration/speed that the driver is willing to use in this corner.

Written for the engineer as well as the race car enthusiast, Race Car Vehicle Dynamics includes much information that is not available in any other vehicle dynamics text. Truly comprehensive in its coverage of the fundamental concepts of vehicle dynamics and their application in a racing environment, this book has become the definitive reference on this topic. Although the primary focus is on the race car, the engineering fundamentals detailed are also applicable to passenger car design and engineering. Authors Bill and Doug Milliken have developed many of the original vehicle dynamics theories and principles covered in this book, including the Moment Method, "g-g" Diagram, pair analysis, lap time simulation, and tire data normalization. The book also includes contributions from other experts in the field.

This paper defines an active suspension and gives a brief history of the development of the LOTUS system, the only successful fully-active embodiment to date. The modal approach and overall system are described. The performance and potential of active suspension relative to the conventional suspension is discussed. Off-road applications are reviewed. The paper concludes with a statement on the future of generalized active control.

An approach to the study of static stability and control of the automobile, that is based on a concept of tethered vehicle testing using a yaw constraint, is described. The supporting theory, however, stands alone as a method of analysis, Graphical methods are developed in which sideforce, yaw moment, and lateral acceleration coordinates define performance plots. These plots reveal certain well-known steady-state performance parameters as well as a new one that defines static stability quantitatively. The theory is presented for the linear automobile with tire sideforce saturation but is applicable, by testing or computer simulation, to the non-linear case.