tanong q rin yan....hehe
The frequency of a harmonic in a sound wave is always an integer multiple of the fundamental frequency. It cannot be higher than the fundamental frequency.
The speed of a wave is equal to the product of its wavelength and frequency. This relationship is described by the equation: speed = wavelength x frequency. In other words, as the wavelength increases, the frequency decreases, and vice versa, to maintain a constant wave speed.
Well, I wasn't actually there, so I didn't observe anything. But from my education and personal experience, I know that the product of the wavelength and frequency of any wave is the wave's speed. So I should expect that the product of wavelength and frequency for any color of light, and for that matter, any electromagnetic wave, is always the same number, and ought to always be very close to the speed of light in the medium in which you observed it, or would have observed it had you been there.
The product of (frequency) times (wavelength) is always the same number ... it's the speed of the wave. So if the frequency increases, the wavelength must decrease, to keep the product constant.
The product of (wavelength) x (frequency) is always equal to the wave's speed.
Yes. There are certainly other kinds of motion, whose angular frequency is not constant, but those are not called "simple harmonic" motion.
The frequency of a harmonic in a sound wave is always an integer multiple of the fundamental frequency. It cannot be higher than the fundamental frequency.
Period, T , and frequency, f , are always the inverse of each other; f = 1/T
The product of a wave's frequency and its wavelength is always its speed.
The product of a wave's frequency and its wavelength is always its speed.
Frequency is inversely proportional to the wavelength.Their product is always the speed of the wave.
Their product is always the speed of the sound.
The product of (frequency) multiplied by (wavelength) is always the same number.The number is the speed of the wave.
Whatever the wavelength and frequency happen to be, their product is always equal to the speed.
Wavelength and frequency must be inversely proportional, because their product is always the same number . . . the wave speed.
The speed of a wave is equal to the product of its wavelength and frequency. This relationship is described by the equation: speed = wavelength x frequency. In other words, as the wavelength increases, the frequency decreases, and vice versa, to maintain a constant wave speed.
An oscillator is something that produces an output that repeats regularly. In the electronics field this will be an electrical waveform, often but not always a sine wave. The most important property of an oscillator is its frequency : the rate at which the output repeats. This is measured in Hertz (Hz for short). One Hertz is one repetition (aka cycle) per second. One MegaHertz (MHz) is one million repetitions per second. One of the problems in designing a high quality oscillator is maintaining the output frequency at the value required. One method is to control it by a quartz crystal; this is cut so that it vibrates mechanically at the design frequency, and is coupled to the electronics by the piezo-electric effect. A 12 MHz crystal oscillator is an electronic circuit, whose output frequency is controlled by a quartz crystal to repeat 12 million times per second. (Note. Oscillators don't have to be electronic. Other examples are a guitar string, a flute or a pendulum. An electronic oscillator is the only one that can be crystal controlled.)