(frequency) = (speed) / (wavelength) = (15 m per sec) / (3 m) = 5 per sec = 5 Hz.
For any wave, the speed of the wave is the product of its frequency and of its wavelength.
The period is ' 1 ' divided by the frequency. (The reciprocal of the frequency.)The question tells us the frequency . . . "3 per second".So the period is 1/3rd of a second .Having the frequency, the wavelength doesn't give us any more information (except thatnow we know the speed of the wave, but that's irrelevant at the moment.)
period and frequency are reciprocals period (T) = 1/frequency (1/f) period = 1/18
A vector quantity is a physical quantity having magnitude and direction both. For e.g. velocity is a vector quantity and in physics it is velocity is generally denoted as: v (bar) = 2i+3j+4k where in general, i=velocity in x-direction j=velocity in y-direction k=velocity in z-direction 2,3 and 4 are magnitudes respective to their directions.
Certainly. For example, a pendulum at its left-most position.
The speed of a wave = (frequency) x (wavelength) = 2.5 meters per second.
The frequency of light with a wavelength of 447 nm can be calculated using the equation: frequency = speed of light / wavelength. Plugging in the values, the frequency is approximately 6.71 x 10^14 Hz.
The frequency of a sound wave can be calculated using the formula: frequency = velocity / wavelength. Plugging in the values given, we get frequency = 341 m/s / 0.8 m = 426.25 Hz. Therefore, the frequency of the sound wave is 426.25 Hertz.
For any wave, the speed of the wave is the product of its frequency and of its wavelength.
A light having one wavelength is called monochromatic light. This means that all the waves in the light are of the same frequency and color.
Pitch is the perceptual quality of sound that is primarily determined by the frequency of the sound wave. Higher frequency sounds are perceived as having a higher pitch, while lower frequency sounds are perceived as having a lower pitch. As frequency increases, pitch also increases and vice versa. Wavelength is inversely related to frequency, meaning that as frequency increases, wavelength decreases and vice versa.
Color light waves differ in terms of their wavelength and frequency. Each color corresponds to a different wavelength within the electromagnetic spectrum. For example, red light has a longer wavelength and lower frequency than blue light. This difference in wavelength is what gives each color its unique appearance to the human eye.
Because red light has minimum frequency and thus it has maximum wavelength.
They are both transverse waves, albeit having different wavelength and frequency. I think that velocity of the waves will also be different as x-rays travel at the speed of light.
Frequency, wavelength, and color are interconnected in the electromagnetic spectrum. Higher frequencies correspond to shorter wavelengths and colors towards the blue end of the spectrum, while lower frequencies are associated with longer wavelengths and colors towards the red end of the spectrum. For example, violet light has higher frequency, shorter wavelength, and is located at the blue end of the visible light spectrum, while red light has lower frequency, longer wavelength, and is located at the red end of the spectrum.
Wavelength, frequency, and energy levels. Each color corresponds to a specific range of these properties, with red having the longest wavelength and lowest frequency, and violet having the shortest wavelength and highest frequency.
The wavelength can be calculated using the formula: wavelength = speed / frequency. Substitute the values: wavelength = 27 miles per second / 215 Hz = 0.125 miles or 660 feet.