# Difference between revisions of "RMS amplitude"

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Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude. | Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude. | ||

− | <math> = \sqrt{\tfrac{1}{T} \int_{0}^{T} \tfrac{1-cos(2\omega t)}{2} dt }</math> | + | <math> = A \sqrt{\tfrac{1}{T} \int_{0}^{T} \tfrac{1-cos(2\omega t)}{2} dt }</math> |

Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude. | Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude. | ||

− | <math>= A \sqrt{\tfrac{1}{ | + | <math>= A \sqrt{\tfrac{1}{T} [\tfrac{T}{2} - \tfrac{sin(2\omega t)}{4\omega }]_0^T }</math> |

Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude. | Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude. |

## Revision as of 10:57, 21 October 2019

The root mean square amplitude (RMS) is a commonly used technique to display amplitude values in a specified window of stack data. With RMS amplitude, hydrocarbon indicators can be mapped directly by measure reflectivity in a zone of interest.

### Definition

In statistics, RMS is typical value of a number (n) of values of a quantity (x_{1}, x_{2}, x_{3}…) equal to the square root of the sum of the squares of the values divided by n. ^{[1]}

In geophysics, RMS amplitude is the square root of the average of the squares of a series of measurements. The auto correlation value (without normalizing) for zero lag is the mean square value. For a sine wave, the RMS value is () times the peak amplitude.^{[2]}

### Mathematical Expression

The RMS value of a set of values is the square root of the arithmetic mean of the squares of the values, or the square of the function that defines the continuous-time waveform. ^{[3]} It’s also known as the quadratic mean of amplitude and is a particular case of the generalized mean with exponent 2.
In a set of n values {x_1,x_2,…,x_n}, the RMS is

The RMS of the corresponding formula for a continuous waveform f(t) defined over the interval [T1, T2] is

and the RMS for a function over all time is

For a sine wave

where y is displacement, t is time, f is frequency, and A is amplitude (the peak deviation of the function from zero)

Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude.

Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude.

Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude.

Thus, the RMS=√2/2 A, it’s 0.707 times the maximum amplitude.