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- https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019v2/Book%3A_Custom_Physics_textbook_for_JJC/06%3A_The_Laws_of_Motion/6.15%3A_Drawing_Free-Body_DiagramsA free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s secon...A free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s second law. To draw a free-body diagram, draw the object of interest, draw all forces acting on that object, and resolve all force vectors into x- and y-components.
- https://phys.libretexts.org/Courses/Muhlenberg_College/MC%3A_Physics_121_-_General_Physics_I/06%3A_Newton's_Laws_of_Motion/6.08%3A_Drawing_Free-Body_DiagramsA free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s secon...A free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s second law. To draw a free-body diagram, draw the object of interest, draw all forces acting on that object, and resolve all force vectors into x- and y-components.
- https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Physics_I_(2211)/06%3A_Newton's_Laws_of_Motion/6.08%3A_Linear_motionThe acceleration of the block in segment \(i\) is given by: \[\begin{aligned} a_i = \frac{F_i}{m}\end{aligned}\] If the speed of the block is \(v_0\) at the beginning of segment 1 (\(x=x_0\)), we can ...The acceleration of the block in segment \(i\) is given by: \[\begin{aligned} a_i = \frac{F_i}{m}\end{aligned}\] If the speed of the block is \(v_0\) at the beginning of segment 1 (\(x=x_0\)), we can find its speed at the end of segment 1 (\(x=x_1\)), \(v_1\), using kinematics and the fact that the acceleration in segment 1 is \(a_1\): \[\begin{aligned} v_1^2-v_0^2 &= 2a_1(x_1 - x_0)\\ v_1^2 &=v_0^2+ 2a_1\Delta x\\ \therefore v_1^2 &=v_0^2+2\frac{F_1}{m}\Delta x\end{aligned}\] We can now easily…
- https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_I_-_Classical_Mechanics_(Gea-Banacloche)/06%3A_Interactions_II_-_Forces/6.04%3A_Free-Body_DiagramsIn a free-body diagram, a potentially very complicated object is replaced symbolically by a dot or a small circle, and all the forces acting on the object are drawn (approximately to scale and properl...In a free-body diagram, a potentially very complicated object is replaced symbolically by a dot or a small circle, and all the forces acting on the object are drawn (approximately to scale and properly labeled) as acting on the dot. Then, since I know that there is an acceleration to the right, I need to draw \(F^t\) greater than \(F^k\), since the net force on the block must be to the right as well.
- https://phys.libretexts.org/Courses/Merrimack_College/Conservation_Laws_Newton's_Laws_and_Kinematics_version_2.0/14%3A_N1)_Newton's_Laws/14.05%3A_Free-Body_DiagramsIn a free-body diagram, a potentially very complicated object is replaced symbolically by a dot or a small circle, and all the forces acting on the object are drawn (approximately to scale and properl...In a free-body diagram, a potentially very complicated object is replaced symbolically by a dot or a small circle, and all the forces acting on the object are drawn (approximately to scale and properly labeled) as acting on the dot. Then, since I know that there is an acceleration to the right, I need to draw \(F^t\) greater than \(F^k\), since the net force on the block must be to the right as well.
- https://phys.libretexts.org/Bookshelves/University_Physics/Book%3A_Introductory_Physics_-_Building_Models_to_Describe_Our_World_(Martin_Neary_Rinaldo_and_Woodman)/06%3A_Applying_Newtons_Laws/6.02%3A_Linear_motionWe can describe the motion of an object whose velocity vector does not continuously change direction as “linear” motion. For example, an object that moves along a straight line in a particular directi...We can describe the motion of an object whose velocity vector does not continuously change direction as “linear” motion. For example, an object that moves along a straight line in a particular direction, then abruptly changes direction and continues to move in a straight line can be modeled as undergoing linear motion over two different segments. An object moving around a circle, with its velocity vector continuously changing direction, would not be considered to be undergoing linear motion.
- https://phys.libretexts.org/Courses/Gettysburg_College/Gettysburg_College_Physics_for_Physics_Majors/15%3A_N1)_Newton's_Laws/15.05%3A_Free-Body_DiagramsIn a free-body diagram, a potentially very complicated object is replaced symbolically by a dot or a small circle, and all the forces acting on the object are drawn (approximately to scale and properl...In a free-body diagram, a potentially very complicated object is replaced symbolically by a dot or a small circle, and all the forces acting on the object are drawn (approximately to scale and properly labeled) as acting on the dot. Then, since I know that there is an acceleration to the right, I need to draw \(F^t\) greater than \(F^k\), since the net force on the block must be to the right as well.
- https://phys.libretexts.org/Courses/Berea_College/Introductory_Physics%3A_Berea_College/06%3A_Applying_Newtons_Laws/6.02%3A_Linear_motionWe can describe the motion of an object whose velocity vector does not continuously change direction as “linear” motion. For example, an object that moves along a straight line in a particular directi...We can describe the motion of an object whose velocity vector does not continuously change direction as “linear” motion. For example, an object that moves along a straight line in a particular direction, then abruptly changes direction and continues to move in a straight line can be modeled as undergoing linear motion over two different segments. An object moving around a circle, with its velocity vector continuously changing direction, would not be considered to be undergoing linear motion.
- https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019/Book%3A_Physics_(Boundless)/05%3A_The_Laws_of_Motion/5.15%3A_Drawing_Free-Body_DiagramsA free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s secon...A free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s second law. To draw a free-body diagram, draw the object of interest, draw all forces acting on that object, and resolve all force vectors into x- and y-components.
- https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Physics_I_(2211)/06%3A_Newton's_Laws_of_Motion/6.04%3A_Drawing_Free-Body_DiagramsThe interface with the inclined plane exerts external forces of N B and f B , and the interface with object B exerts the normal force N AB and friction f AB ; N AB is directed away from object B, and ...The interface with the inclined plane exerts external forces of N B and f B , and the interface with object B exerts the normal force N AB and friction f AB ; N AB is directed away from object B, and f AB is opposing the tendency of the relative motion of object B with respect to object A.
- https://phys.libretexts.org/Workbench/PH_245_Textbook_V2/03%3A_Module_2_-_Multi-Dimensional_Mechanics/3.03%3A_Objective_2.c./3.3.07%3A_Drawing_Free-Body_DiagramsA free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s secon...A free-body diagram is a useful means of describing and analyzing all the forces that act on a body to determine equilibrium according to Newton’s first law or acceleration according to Newton’s second law. To draw a free-body diagram, draw the object of interest, draw all forces acting on that object, and resolve all force vectors into x- and y-components.
