Nothing happened if the frequency was high. It is only if the frequency changed that there would have been any effect.
The amplitude of a pendulum does not affect its frequency. The frequency of a pendulum depends on the length of the pendulum and the acceleration due to gravity. The period of a pendulum (which is inversely related to frequency) depends only on these factors, not on the amplitude of the swing.
It's not always the same. The frequency of a pendulum depends on its length, on gravity, on the pendulum's exact shape, and on the amplitude. For a small amplitude, and for a pendulum that has all of its mass concentrated in one point, the period is 2 x pi x square root of (L / g) (where L=length, g=gravity). The frequency, of course, is the reciprocal of this.
Frequency refers to the number of complete oscillations of a wave that occur in a given time period, usually measured in hertz (Hz). Amplitude, on the other hand, represents the maximum displacement of a wave from its equilibrium position. In simpler terms, frequency determines the pitch of a sound or the color of light, while amplitude determines the loudness of a sound or the brightness of light.
No, increasing the amplitude of a wave does not change its frequency. Frequency is determined by the number of complete oscillations or cycles of the wave that occur in a given time period, and this remains constant regardless of the wave's amplitude.
Yes, low frequency signals can have large amplitudes. Amplitude refers to the strength or intensity of a signal, while frequency refers to the number of cycles of the signal that occur in a given time period. So, a low frequency signal can still have a high amplitude.
It's not always the same. The frequency of a pendulum depends on its length, on gravity, on the pendulum's exact shape, and on the amplitude. For a small amplitude, and for a pendulum that has all of its mass concentrated in one point, the period is 2 x pi x square root of (L / g) (where L=length, g=gravity). The frequency, of course, is the reciprocal of this.
Amplitude, frequency/period and phase.
# time period # frequency # amplitude
Increase the amplitude and the frequency
The main characteristics of waves are: 1. Amplitude or height of the wave. 2. Wavelength, or the distance between crests. 3. Period or the length of time for a wave to pass a point. 4. Frequency or the number of complete waves passing a point. 5. Speed or the horizontal speed of the wave as it grows.
the properties of sound wave are wave length,amplitude,frequency.
Amplitude is how loud sound is and does not change a sounds pitch. They are independent.
Huge.
Speed, wavelength, frequency, period, amplitude, intensity.
The amplitude of a wave is the maximum displacement from the equilibrium position, while the time period is the time it takes for one complete cycle of the wave. There is no direct relationship between amplitude and time period; they are independent properties of a wave.
Resonance occurs when an object is subjected to a periodic force at its natural frequency, leading to large amplitude oscillations. It can be caused by external forces matching an object's natural frequency, resulting in increased energy transfer and vibration amplitudes. Improper damping, structural faults, and wind-induced vibrations are common causes of resonance in structures and systems.
1/3 second. Hz means cycles per second. Amplitude is not a factor.