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Consider two pendulums are oscillating with different frequency . And when these are come in contact with each other after sometime it will oscillate with a frequency intermediate of other two. This new frequency will be resonance when both pendulum is now oscillating with max frequency that can individually acquire.
If an oscillating object is subjected to small impulses of the same frequency as the object's natural frequency of oscillation, its amplitude will build up rapidly, depending on how much damping is present. This is caused resonance.
Any electric charge undergoing acceleration will produce Electromagnetic waves. This is by far the most common way.If an oscillating electric field is synchronized with an oscillating magnetic field of exactly the same frequency a beam of light will be produce where the two fields are orthogonal in all dimensions.
An Oscillating motion is one that moves forwards and backwards in an arc or circle repeatedly.
The energy varies with the frequency, Energy = h x frequency where h is Planck's constant 2/3E-33 Joule second. The higher the frequency the higher the energy. When the frequency of an oscillating wave {WaveForm aka Particle} increases so in general does it's Energy.
Consider two pendulums are oscillating with different frequency . And when these are come in contact with each other after sometime it will oscillate with a frequency intermediate of other two. This new frequency will be resonance when both pendulum is now oscillating with max frequency that can individually acquire.
When the frequency is less than expected.
You either Decrease mass or increase spring force.
The frequency is 300/30 = 10 Hz The time period is 30/300 = 0.10 seconds
You need to know the probability of the event in question. Then the expected frequency for that event occurring is that probability times the number of times the experiment was repeated.
For goodness of fit test using Chisquare test, Expected frequency = Total number of observations * theoretical probability specified or Expected frequency = Total number of observations / Number of categories if theoretical frequencies are not given. For contingency tables (test for independence) Expected frequency = (Row total * Column total) / Grand total for each cell
If strings with different density are used, the oscillating frequency will change, assuming that tension is maintained the same. With higher density, the frequency will go down; with lower density, the frequency will go up.The equation for frequency1 is ...f = k * tension0.5 / length / mass-per-unit-length0.5... so the frequency is inversely proportional to the square root of mass per unit length, which is related to density.--------------------------------------------------1"The Science of Musical Sound", John R. Pierce, Scientific American Library, 1983, page 22.
P. Kartaschoff has written: 'Frequency and time' -- subject(s): Frequencies of oscillating systems, Measurement, Time measurements
Meyer's oscillating disc method is a technique used to determine the molecular weight of a polymer by measuring the change in weight of a solution containing the polymer as it oscillates at a specific frequency. This method allows for accurate determination of molecular weight and can be used to study the size and structure of macromolecules.
The tower was oscillating due to the strength of the wind.
The oscillating object was observed by the students.
True.