All photons have the same speed in a vacuum, no matter what their frequency. They all travel at the speed of light: 299,792,458 meters per second.
No. No natural object emits all its radiation at just one frequency.
After the absorption, the matter has added energy equal to 'hf' the energy of the absorbed photon.
Red waves have the lowest frequency of all light waves; there is no wave with a lower frequency.
You need matter to vibrate at a frequency that is detectable to the listener.
All photons have the same speed in a vacuum, no matter what their frequency. They all travel at the speed of light: 299,792,458 meters per second.
The frequency of the power waveform in a capacitive circuit, or for that matter, an inductive circuit, is the same as the input voltage or current. Its just that the current leads the voltage (capacitor) or lags the voltage (inductor) by a phase angle, the cosine of which is the power factor. It does not matter how many sine waves you have, or what their phase angle is; if they all have the same frequency, the resultant, by Fourier analysis, is still a sine wave of the same frequency.
There isn't any. Whatever frequency you name, no matter how low it is, I can always name a frequency that's lower than yours.
The frequency in a frequency table is the number of occurrences within each class width. The total frequency is the sum of all frequency's within all the classes.
The signal that changes at a higher rate occupies greater bandwidth.
Which frequency? Frequency in Hertz can be accepted as linear frequency. What is non linear is usually the method of "presenting" it, like a non linear logarithmic scale. Also there is the matter of angular frequency defined as w = 2*π*f, where f is linear frequency (Hz or s^-1).
The frequency is unrelated to the fall, so it may have any frequency. Or no frequency at all.
Increasing the frequency of any electromagnetic wave ... or of any wave for that matter ... decreases its wavelength.
Which one of the two you do does not matter.
A: Take 115 volts and multiply by 2.82. The frequency does not matter but he voltage does
Data representation. Cumulative frequency is the sum of all previous frequencies.
No matter what frequency, there are 360 degrees that can be associated with it (the phase). Here's an equation to summarize: V(t) = A sin ([w*t] + p) A is amplitude w = frequency p = phase shift