<P> As with other waves, there are a number of characteristics used to describe a gravitational wave: </P> <Ul> <Li> Amplitude, h, the size of the wave--the fraction of stretching or squeezing in the animation . The amplitude here is roughly h = 0.5 (or 50%). Gravitational waves passing through the Earth show sextillion times this weakness (10). Also denoted as Wavelength, λ, the distance along the wave between points of maximum stretch or squeeze . </Li> <Li> Frequency: Usually denoted f, this is the frequency with which the wave oscillates (1 divided by the amount of time between two successive maximum stretches or squeezes) </Li> <Li> Speed: This is the speed at which a point on the wave (for example, a point of maximum stretch or squeeze) travels . For gravitational waves with small amplitudes, this wave speed is equal to the speed of light (c). </Li> </Ul> <Li> Amplitude, h, the size of the wave--the fraction of stretching or squeezing in the animation . The amplitude here is roughly h = 0.5 (or 50%). Gravitational waves passing through the Earth show sextillion times this weakness (10). Also denoted as Wavelength, λ, the distance along the wave between points of maximum stretch or squeeze . </Li> <Li> Frequency: Usually denoted f, this is the frequency with which the wave oscillates (1 divided by the amount of time between two successive maximum stretches or squeezes) </Li>

What is the wavelength of a gravity wave