Loading DocumentIn sufisticated systems such as Super conductors and highly advanced mechanical systems that have precision in their engineering techniques. There is a chance of there being an abundance of energy that is easy to maintain throughout the system. This can result in energy remaining unchanged for a few seconds.
We can sketch out a graph that can be used to show the change in energy. Specifically kinetic energy. This is called a Kinetic timescale graph.
Kinetic timescale graph
As you've seen, the y axes is for the level of energy, and the x axes is for the time taken for separate energy levels to rise.
Energy charge is the increase in energy, while energy discharge is the decrease in energy. Static kinetism is energy that is unchanged throughout the whole process.
These graphs can help bring insight into how changes can be made in energy production In terms of optimizing mechanical input to create the best quality source of energy for wide-spead use.
We can use the finnet formula for kinetic energy.
Finnet formula implementation
For the minimum amount of energy at the end of a kinetic discharge, we can use the same formulas but just with some rearrangement. We take the net energy minus the energy that would have been generated within the time frame of the discharge. That would make the energy lost. And then the net energy minus the energy lost would be our total energy at the end of that discharge.
Formula re-configuration for Kinetic discharge
Static kinetism is presented as a small period in time that allows energy to remain unchanged. This implies that of a system is producing kinetic energy at a high proficiency, it may remain the same for some time. As it may be at a state of generating equal amounts of energy and movement.