2.27 The damping force for shock absorbers for heavy trucks often exhibits a nonlinear relationshipwith the relative velocity between the piston and cylinder of the damper. A typical damper forcerelationship isF₁ =4500*/²+v²where Fd is the damper force (in N), i is the relative velocity between the piston and the cylinder (inm/s), and v= 0.2 m/s. Use MATLAB to plot the damper force versus relative velocity for-1.5≤ ≤ 1.5 m/s. Describe the nature of the damper force for "small" and "large" values ofrelative velocities.

A non-linear relationship of damper force as the function of relative velocity:To find:To plot the…

2.27 The damping force for shock absorbers for heavy trucks often exhibits a nonlinear relationship with the relative velocity between the piston and cylinder of the damper. A typical damper force relationship is 4500+ √² + v² where Fa is the damper force (in N), i is the relative velocity between the piston and the cylinder (in m/s), and v= 0.2 m/s. Use MATLAB to plot the damper force versus relative velocity for -1.5 1.5 m/s. Describe the nature of the damper force for "small" and "large" values of relative velocities. F₁ =

2.27 The damping force for shock absorbers for heavy trucks often exhibits a nonlinear relationship with the relative velocity between the piston and cylinder of the damper. A typical damper force relationship is 4500+ √² + v² where Fa is the damper force (in N), i is the relative velocity between the piston and the cylinder (in m/s), and v= 0.2 m/s. Use MATLAB to plot the damper force versus relative velocity for -1.5 1.5 m/s. Describe the nature of the damper force for "small" and "large" values of relative velocities. F₁ =

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

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