Carl R. Nave - HyperPhysics Index
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- Book:HyperPhysics Index
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- Publisher:Georgia State University
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- Year:2016
- City:Atlanta
- Rating:3 / 5
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Using Google to Search HyperPhysics To find the coverage of a specific term or phrase in HyperPhysics, you can make use of the domain constraint in Google to search only HyperPhysics. For example, if you want to find out what HyperPhysics has about eclipses, you can enter the following in Google's search window: eclipse site:hyperphysics.phy-astr.gsu.edu You can then just click on Google search and it will give you a list of the occurrences of this term or search string in the HyperPhysics domain. This process has been implemented for you in the search box on the main screen of . | |
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Acceleration Acceleration is defined as the rate of change of quantity, and an object will have non-zero acceleration if its speed and/or direction is changing. The average acceleration is given by  where the small arrows indicate the vector quantities. The operation of subtracting the initial from the final velocity must be done by since they are inherently vectors. The for acceleration can be implied from the definition to be meters/second divided by seconds, usually written m/s2. The instantaneous acceleration at any time may be obtained by taking the limit of the average acceleration as the time interval approaches zero. This is the of the velocity with respect to time:  | |
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Velocity The average speed of an object is defined as the distance traveled divided by the time elapsed. Velocity is a divided by the time. For the special case of straight line motion in the x direction, the average velocity takes the form:  The for velocity can be implied from the definition to be meters/second or in general any distance unit over any time unit. You can approach an expression for the instantaneous velocity at any point on the path by taking the limit as the time interval gets smaller and smaller. Such a limiting process is called a and the instantaneous velocity can be defined as  | |
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Average Velocity, Straight Line The average speed of an object is defined as the distance traveled divided by the time elapsed. Velocity is a divided by the time. For the special case of straight line motion in the x direction, the average velocity takes the form: | |
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Average Velocity, General The average speed of an object is defined as the distance traveled divided by the time elapsed. Velocity is a expressions do not work. |
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