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You can't, since the slope of the graph means average velocity and the area of the graph has no meaning. The only way to find instantaneous velocity from position-time gragh is by plugging the data into the kinematic equations to get the answer. Edit: Actually you can if you take the derivative of the equation of the curve it will give you the equation of the velocity curve
g - 6 = 12In order to isolate the variable 'g' you must add 6 to both sides of the equation.In algebra, you must perform the opposite operation of the one presented in the problem. For example, the equation above has "minus 6". The opposite opporation for subtraction is addition. So in this case you must ADD 6 to both sides of the equation. Performing the operation to both sides of the equation is essentially multiplying the entire equation by 1, and any time you multiply something by 1 you get the same thing. Because of this, adding to both sides of the equation does not change the final answer.So..g - 6 = 12+6 +6g = 18
the distance between the solar time i.e Mean time apparent solar time is stated as equation of time. M.t-A.t=equation of time
Simply put, kinematics is really just physics without forces or masses. That is, you deal with velocities, accelerations, time, etc. So a kinematic equation will have those variables.The kinematic equation of motion could be any of the four equations I list, or any variation of them (they can be rewritten in a number of ways):let d = distance, v = velocity, i = initial velocity, a = acceleration, t = timev = i + atd = it + (1/2)t2v2 = i2 + 2add = (1/2)(i + v)tThe equations describe the motion, whether it describing it's acceleration, velocity, distance traveled along a certain axis, all with respect to time.
The word isolate was a new formation of word isolation and was created in 1786. It was created during a time period where French language was being manipulated.
To calculate standard time, subtract the equation of time from the sundial time, then subtract the longitude from the answer you get.
The time-independent Schr
The time dependent equation is more general. The time independent equation only applies to standing waves.
The kinematic equation for velocity states that Vf = Vo + at. Assuming that the nut starts from rest, Vo goes to zero. This means that the final velocity of the nut is the gravitational constant times time i.e. Vf = at. If the nut falls on earth then the final velocity would be 98.1 m/s or 322 ft/s.
I assume that the "speed" equation is velocity equals distance divided by time (v=d/t). To get 't' on the left side, we'll multiply both sides by 't': (vt=dt/t) and the two 't's on the right side cancel out (because t divided by t is 1): (vt=d). Now we move the v to the right side by dividing both sides by 'v': (vt/v=d/v). Just the 't's in the step before, now we have a v divided by a v on the left side, so they cancel out, and our final equation is time equals distance divided by velocity: t=d/v
The basic definition of speed is: speed = distance / time Solve this equation for distance, or solve it for time, to get two additional versions of the equation.
Distance ÷ Time (distance divided by time)