Geometrical Optics: Adapted to the Use of the Higher Classes in Schools, Etc |
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Page ix
... Acceleration - Constant Acceleration — F Falling Bodies - Bodies Projected vertically Upwar Newton's Laws of Motion - -Motion on an Inclined P - Variable Acceleration Harmonic Motion Mo with Repulsive Force Acting - Resistance varies as ...
... Acceleration - Constant Acceleration — F Falling Bodies - Bodies Projected vertically Upwar Newton's Laws of Motion - -Motion on an Inclined P - Variable Acceleration Harmonic Motion Mo with Repulsive Force Acting - Resistance varies as ...
Page 4
... acceleration of gravity ( see Art . 76 ) , may be expressed G M : = 9 • Both G and g vary for different localities , but the quotient is constant ; that is , the quantity of matter in a body is independent of its position with reference ...
... acceleration of gravity ( see Art . 76 ) , may be expressed G M : = 9 • Both G and g vary for different localities , but the quotient is constant ; that is , the quantity of matter in a body is independent of its position with reference ...
Page 66
... acceleration about the instantaneous axis of rota- tion and an acceleration of translation along that axis . Such a system of forces is called a screw wrench . The instantaneous axis is called the central axis . This axis passes through ...
... acceleration about the instantaneous axis of rota- tion and an acceleration of translation along that axis . Such a system of forces is called a screw wrench . The instantaneous axis is called the central axis . This axis passes through ...
Page 126
... acceleration . usually represented by g and equals approximately 32.2 ft . per second squared . The value of g varies slightly with the height above the sea level and the latitude , but for the purposes of engineering it may usually be ...
... acceleration . usually represented by g and equals approximately 32.2 ft . per second squared . The value of g varies slightly with the height above the sea level and the latitude , but for the purposes of engineering it may usually be ...
Page 127
... the force , and the acceleration is proportional to the force applied . Third Law . To every action of a force there is always an equal and opposite reaction . The first law has already been made use of , MOTION IN A STRAIGHT LINE 127.
... the force , and the acceleration is proportional to the force applied . Third Law . To every action of a force there is always an equal and opposite reaction . The first law has already been made use of , MOTION IN A STRAIGHT LINE 127.
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a₁ acceleration angle angular velocity arrow axes axis of rotation axle center of gravity cloth coefficient of friction compression concurrent forces consider constant cord cosē couple Crown 8vo curve cylinder diameter direction disk distance dt dt Edition equal fcap Find the center fly wheel forces acting formula gravity axis hammer horizontal inch inertia with respect kinetic energy length lens line of action M₁ M₂ mass mirror moment of inertia motion moving P₁ P₂ pencil pendulum perpendicular plane point of application preceding problem prism pulley R₁ radians per second radius rays refraction represented resistance revolutions revolutions per minute rigid body seen shaft shown in Fig Simpson's Rule speed square Suppose surface T₁ tangential tension tion v₁ vertical weight work-energy equation x-axis zero