Hi sir, I was wondering why ds would be zero? Wouldn't a particle in circular motion have some sort of change in displacement over time? (e.g at 90° or so)andrewkirk said:It will be the latter - a dot product. Consider uniform circular motion, in which the acceleration is always perpendicular to the velocity. ds will be zero because the speed is constant, but dv will not, as the velocity is changing direction. So the simple multiplicative equality will not hold because the LHS is zero but the RHS is not. But the dot product equality will hold, as both sides will be zero (because dv is perpendicular to v).
Ah, I was interpreting your s as meaning 'speed' (=|v|) but based on your response, I see you mean it to refer to displacement.Iqminiclip said:Hi sir, I was wondering why ds would be zero? Wouldn't a particle in circular motion have some sort of change in displacement over time? (e.g at 90° or so)
This equation is known as the Fundamental Theorem of Calculus, and it represents the relationship between the rate of change of a variable (a or v) and the total change of another variable (ds or dv).
This equation is used in many scientific fields, such as physics, engineering, and biology, to calculate important quantities like velocity, acceleration, and displacement.
In this equation, a represents acceleration, ds represents displacement, v represents velocity, and dv represents change in velocity.
No, this equation can be used for both one-dimensional and multi-dimensional motion. In multi-dimensional motion, the variables would represent the components in each direction (e.g. x, y, and z).
Yes, this equation can be derived from the chain rule of calculus, which states that the derivative of a composite function is equal to the product of the derivatives of its individual components.