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∙ 15y agoThe graph of force of friction vs total weight is typically linear, following the equation of force of friction = coefficient of friction * total weight. As total weight increases, the force of friction also increases proportionally. The slope of the graph represents the coefficient of friction.
The slope of a friction vs weight graph represents the coefficient of friction, which is a measure of the resistance encountered when one object slides over another. A higher slope indicates greater friction between the two surfaces, while a lower slope indicates less resistance.
The skin friction coefficient decreases with increasing Reynolds number until a certain point, known as the transition point. After this point, the skin friction coefficient tends to stabilize or slightly increase. This graph typically displays a curve with a gradual decrease followed by a plateau.
To create a force-time graph from an acceleration-time graph, you would first integrate the acceleration values to obtain the velocity-time graph, and then integrate the velocity values to get the displacement-time graph. Finally, you can use Newton's second law (F = m*a) to relate the acceleration to the force and derive the force-time graph.
The area under a force-distance graph represents the work done. It is equal to the force applied multiplied by the distance moved in the same direction as the force.
No, in general, the force vs acceleration graph does not always pass through the origin. This is because there may be a non-zero force acting on an object even when it is at rest. The presence of a non-zero force at rest would lead to a non-zero intercept on the force vs acceleration graph.
no
The slope of a friction vs weight graph represents the coefficient of friction, which is a measure of the resistance encountered when one object slides over another. A higher slope indicates greater friction between the two surfaces, while a lower slope indicates less resistance.
Use Newton's Second Law. Specifically, if you assume that the mass remains constant, then force will be proportional to acceleration. Force divided by mass yields acceleration (without friction, etc.).
The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.The momentum-time graph is the integral of the force-time graph. that is, it is the area under the curve of the f-t graph.
It is not, if it is a graph of force against acceleration.
The y-intercept on a force vs acceleration graph represents the value of the force when the acceleration is zero. In other words, it indicates the minimum force required to keep an object at rest or to overcome any opposing forces acting on the object.
no, work done is the area under a force-distance graph
The skin friction coefficient decreases with increasing Reynolds number until a certain point, known as the transition point. After this point, the skin friction coefficient tends to stabilize or slightly increase. This graph typically displays a curve with a gradual decrease followed by a plateau.
To create a force-time graph from an acceleration-time graph, you would first integrate the acceleration values to obtain the velocity-time graph, and then integrate the velocity values to get the displacement-time graph. Finally, you can use Newton's second law (F = m*a) to relate the acceleration to the force and derive the force-time graph.
The slope of a force vs. time graph is equal to the change in momentum or the Impulse.
A Force-time graph shows the variation of force with respect to time. More usefully the area under such a graph gives the quantity Ft or impulse, which is equal to the change in momentum of an object. Ft = Mv-Mu
The area under a force-distance graph represents the work done. It is equal to the force applied multiplied by the distance moved in the same direction as the force.