There are several kinds of dipole; the most common is the half-wave dipole.
Its total length is fairly close to half the wavelength of the design frequency.
The length needs to be adjusted slightly to compensate for the thickness of the elements and for end-effects.
If the length is wrong by ten or twenty percent it will alter the feed impedance, but have little effect on the gain.
Wavelength = (speed) / (frequency) =(299,792,458) / (1,240,000) = 241.768 meters
Of course. The wavelength and amplitude have no influence on each other.
Wavelength = speed/frequency = 30/10 = 3 meters
Frequency = (speed) / (wavelength) = 900/9 = 100 Hz.
0.0003 nanometres.
The speed of the wave would depend on the tension, the length of the rope, and the mass per length unit.On the other hand, there is a general relation for waves: speed = wavelength x frequency. This doesn't help in this particular case - you need more data.By the way, Hz. is a unit of frequency. Wavelength would be measured in meters.The speed of the wave would depend on the tension, the length of the rope, and the mass per length unit.On the other hand, there is a general relation for waves: speed = wavelength x frequency. This doesn't help in this particular case - you need more data.By the way, Hz. is a unit of frequency. Wavelength would be measured in meters.The speed of the wave would depend on the tension, the length of the rope, and the mass per length unit.On the other hand, there is a general relation for waves: speed = wavelength x frequency. This doesn't help in this particular case - you need more data.By the way, Hz. is a unit of frequency. Wavelength would be measured in meters.The speed of the wave would depend on the tension, the length of the rope, and the mass per length unit.On the other hand, there is a general relation for waves: speed = wavelength x frequency. This doesn't help in this particular case - you need more data.By the way, Hz. is a unit of frequency. Wavelength would be measured in meters.
The give-away should be the word "length" which is hidden in the word "wavelength". Wavelength has the dimensions of length, and is most often stated in meters or centimeters (radio), nanometers (light), etc.
The equation to use in this case is:speed (of the wave) = wavelength x frequency If the frequency is in hertz, and the wavelength is in meters, the speed will be in meters/second.
Wavelength at 2 MHz = 149.896 meters Wavelength at 56 Hz = 5,353.437 meters Lower frequency --> longer wavelength. Higher frequency --> shorter wavelength When you multiply (frequency) times (wavelength), the result is always the same number.
Just multiply the frequency by the wavelength. In this case, the product will be in meters per second.
"Meters" is not frequency. It's wavelength. If you know the wavelength in meters, divide 300 by it, and the result is the frequency in MHz. If you know the frequency in MHz, divide 300 by it, and the result is the wavelength in meters.
Wavelength is a length. Hence, the metric unit for it is "meter". Frequency is a reciprocal of time. Hence, the unit for it is "per second", named "Hertz".
The wavelength is the size of the wave in meters. The frequency is the number of waves that occur in a scond.
Meters are a unit of measurement of length and have no relation to weight. One metric tonne is 1000 Kilograms.
Microwaves have an approximate length of 10 to the 8th power nano meters.This means that they have an incredibly long wavelength.Since wave length and energy are inversely related, that means the wavelength is long which makes the energy low.10 to the 8th power of nano meters is just a confusing way to say 20 meters
Always the lower wavelength lambda has a higher frequency f and the higher wavelength has the lower frequency. Speed of medium c = lambda times frequency f = c / wavelength lambda = c / f The wavelength 1x10-5 meters has a higher frequency than the wavelength 1x10-7 meters.
Wavelength = (speed) / (frequency)= (15) / (5.4) = 2.777 meters (rounded, repeating)