Fundamentals of Vibration
Fundamentals of Vibration
Vibration
Vibration is a mechanical movement around an equilibrium point. In other words, it is a mechanical phenomenon
where a dynamic external force is applied onto structures or floors, causing the oscillation motion that repeats itself after an interval of time. Among the sources of vibration, the low frequency vibration is not perceptible during daily activities, and adversely affect vibrationsensitive metrology tools in the fields of semiconductor, display, electron microscopy, life sciences and photonics.
Classification of Vbiration
Periodic noise is defined as the known magnitude of the excitation acting on a vibratory system at any given time. It is generally caused by rotating machinery. Random noise is caused by unpredictable excitation such as wind velocity, road roughness, foot and vehicular traffic, and ground motion during various activities.
Measurement Unit of Vibration
Vibration can be measured in units of displacement, velocity and acceleration. The shape and frequency of the vibration are the same regardless of which of the three measurement units, used to express vibration, except for the difference in the phase. Sinusoidal signals, displacement, velocity and acceleration amplitudes are related mathematically by a function of
frequency and time. If the phase is not a factor to be considered, the velocity is obtained by dividing the acceleration signal by a factor proportional to frequency, and the displacement can be calculated by dividing the acceleration signal by a factor proportional to the squire of frequency.
Relationship between Displacement, Velocity and Acceleration
Sources of Vibration
1) Ground Vibration
2) Acoustic Noise
3) Direct force applied to a payload installed on a vibration isolation platform

Ground (seismic) vibrations indicate all the factors that cause vibrations on a floor. The factors include foot and vehicular traffic, wind blowing buildings and HVAC systems.

Acoustic noises are the air currents caused by the HVAC ventilation.

A direct force is a force that directly applied to a payload on a vibration isolation platform, including cables connecting instruments and motorized linear stages.
Frequency
Frequency is defined as the number of events of a repetitive motion cycle during the period of 1 second and measured in hertz (Hz).
Natural Frequency
The natural frequency is the frequency at which the system resonates or oscillates when the system is not disturbed by an
external force. A higher stiffness and a lower mass indicates the high natural frequency and a lower stiffness and a a higher mass indicates the low natural frequency.
Forced Frequency
If an object is subject to an external force, resulting vibrations and the frequency of that external force is known as forced frequency. When the forced frequency coincides with the natural frequency of the vibration isolation system, the amplitudes of vibration peaks which is known as resonance.
Resonance
Resonance occurs if a forced frequency coincides with a natural frequency of the system, resulting large oscillations. Frequency at which the response amplitude is a relative maximum is known as resonant frequency.
Vibration Amplitude
Peak of Vibration Amplitude
Frequency
Measurement of Vibration Amplitude (Quantifying Vibration Level)
The magnitude of displacement, velocity, or acceleration from its zero value (rest value) is known as amplitude. The amplitude of vibration can be expressed as peaktopeak, peak, Root Mean Square.

Peak
The peak value only indicates the maximum excursion of the vibration amplitude from the equilibrium point,
no account is taken of the time history of the wave.

PeaktoPeak
The peaktopeak value indicates the distance from a negative peak to a positive peak.

Root Mean Square (RMS)
The RMS value indicates the square root of the average of the squared values of vibration amplitudes. The RMS value both takes the time history of the wave into account and gives an amplitude value which is directly related to the engergy content. The RMS value of a sine wave is 0.707 times the peak amplitude and the RMS value is poportional to the area under the sine wave curve representing the vibration energy. The RMS value is used for the vibration criterion curves with the international standards organization (ISO), which are widely accepted throughout the world as
a environmental vibration standard to determine whether the vibration amplitude of installation sites is appropriate for equipment specifications.

Average
The average value indicates an average variation of vibration over time. However, the average value is considered of limited practical interest because it has no direct relationship with any useful physical qunaitiy.
Vibration Isolation
Vibration isolation is defined as the process to isolate an object from sources of vibration. The theory of vibration isolation is to make the natural frequency of the system lower than the forced frequency and suppress the resonance at the natural frequency of the system. As technology advances, the vibration isolation technique is essentially required to isolate vibration sensitive metrology instruments from vibrations.
Transmissibility (T) indicates the ratio of the vibration amplitude of the vibration transmitted to a vibration isolated platform to that of the exciting vibration. The efficiency of the vibration isolation improves with the lower natural frequency, meaning that the lower T value is the better vibration isolation performance.
The frequency ratio is a function of the forced frequency and the natural frequency of the system and is used as an evaluation criterion to determine vibration isolation performance.
For the frequency ratio in the range (0 < frequency ratio < 1.414), the T is greater than 1 for all values of damping ratio (ζ), indicating vibration amplifications and transmission and damper helps to reduce the vibration amplifications. When the frequency ratio is equal to 1, vibration amplitude is maximized (resonance), and the amplified T value is minimized depending on damping ratio. The vibration isolation system with the higher damping ratio reduces more the vibration amplitudes than the vibration isolation system with the less damping ratio. However, there is a trade off between vibration isolation performance and damping ratio that as the damping ratio increases, the T declines more slowly.