' kHz ' and ' decibels ' are units for measuring completely different quantities. Neither one can be converted to the other one, any more than you can convert ' 30 miles per hour ' into dollars and cents.
One year is equal to twelve months.
One Gaz Equal To 9 Sqt Feet
One dime is equal to 1/10 of a dollar. Ten dimes are equal to one dollar. Four quarters are also equal to one dollar.
One tenth as many.
1 mhz =1000khz
There are basically two radio broadcast bands as we know them. One is the AM (amplitude modulation) band, and the other is the FM (frequency modulation) band. The AM band is from 520 KHz to 1700 KHz (0.52 MHz to 1.7 MHz). The FM band is from 87.5 MHz to 108.0 MHz. Other bands are used commercially, but these two bands represent the broadcast bands used in the U.S.Note: 1 KHz = 1,000 Hz (Hertz, cycles per second, or cps), and 1 MHz = 1,000,000 HzIn the USA ...-- Commercial AM radio stations operate with carrier frequenciesspaced every 10 KHz between 550 KHz and 1700 KHz.-- Commercial FM radio stations operate with carrier frequenciesspaced every 200 KHz between 88.1 MHz and 107.9 MHz.
One hertz is equal to one cycle per second. Hence, one kilohertz (kHz) is equal to 103 cycles per second, one megahertz (MHz) is 106 cycles per second, and one gigahertz (GHz) is 109 cycles per second.
Hz (Hertz) is the unit of frequency equal to one cycle per second, while kHz (kilohertz) is equal to one thousand cycles per second. In other words, 1 kHz is equal to 1000 Hz.
1 million cycles per second is 1 MHz (1 megahertz). Each cycle has a period of 1 microsecond (one millionth of a second).
GSM Band 890 to 915= 25 MHz One GSM Channel BW= 200 KHz Total GSM channels=25MHz/200KHz=125
MHz and GHz are a measure of frequency. In science frequency = 1/time for one cycle. If a wave takes 0.5 seconds to complete a wave, the frequency is 2 Hz. MHz and GHz in computers measure the same thing. It measures the frequency of the processor (ie, how many cycles it completes in a set time) again, if each cycles takes 0.5 seconds, then your computing speed is 2 Hz. a GHz (giga hertz) is equal to 1000 Mhz (mega hertz) a MHz is equal to 1,000,000 Hz. how is mhz and ghz is measured?
There are 1 million hertz (Hz) in one megahertz (MHz).
It can't. FM (like broadcast AM) has two *sidebands*, one at a higher frequency than the transmitter's carrier, one at a lower frequency. The modulating signal (voice, music, etc) of any trasnmitter creates one or more pairs of side frequencies within the two sidebands. A broadcast AM signal can only produce two side frequencies, so an AM transmitter at 1.5 MHz, with a 1 kHz modulating tone (fm), would put out its carrier (fc) at 1.5 MHz, a lower side frequncy at (1.5 - 0.001) = 1.499 MHz, then its carrier at 1.5 MHz, and then the upper side frequency at (1.5 + 0.001) = 1.501 MHz. The AM signal can never be wider than twice the highest modulating frequency (fm), spanning from (fc - fm) to (fc + fm), a span of 2 x fm. Be aware that special-purpose AM systems can generate just *one* sideband - we won't go into that amount of detail apart from noting it. FM signals can be wider than twice the highest modulating frequency. The complete analysis needs the mathematical Fourier Transform, but we can think of it this way. Stronger frequency modulation shows up as a larger change in the transmitted signal frequency. An FM signal at 100 MHz, modulated by a 1 KHz tone, *can* put out a lower side frequency at (100 - 0.001) = 99.999 MHz and an upper side frequency at (100 + 0.001) = 100.001 MHz. You could receive this just fine, but it would sound "weak" compared to normal broadcasts. It's possible to increase the frequency shift to (say) five times. Now, the sidebands must extend from (100 - 5x0.001) = 99.995 MHz to (100 + 5x0.001) = 100.005 MHz. How do we account for the original 1 KHz tone creating a bandwidth of 2x5 kHz? The answer is that we actually have *five* lower side frequencies, at -5, -4, -3, -2, -1 kHz below the carrier, and *five* upper side frequencies at +1, +2, +3 +4 and +5 kHz above the carrier. Notice that they are multiples of the original 1 kHz modulating frequency. These can, in fact, be shown on the instrument called a spectrum analyser. Your question? As with broadcast AM, an FM signal has only two sidebands. In FM, the strength of modulation (the modulation index) controls the number of individual side frequencies, and thus the total bandwidth of the signal. Can an FM signal have *infinite* numbers of side frequencies? Not really. It can have a *very large* number of side frequencies with very great modulation strength. In practice, this would take up *a lot* of the FM radio band, so broadcast FM commonly uses a maximum modulation index of 5.0. This means that a fully-modulating 15 kHz signal would give a bandwidth of -(15 x 5) to +(15 x 5) kHz, which is +/- 75 kHz.
It can be as many as you wish... Actually, Frequency & Hertz is totally two different category or level. Frequency is a measurement parameter/ variable. Hertz is the unit of measurement for a parameter/ variable. This can be analogue as Frequency - Velocity Hertz - miles/ second
The acronym MHz stands for megahertz, which is a unit of frequency equal to one million cycles per second. It is commonly used to measure the clock speed of computer processors and the frequency of electronic signals.
Yes, electromagnetic waves are classified based on their wavelengths. The electromagnetic spectrum ranges from gamma rays with the shortest wavelengths to radio waves with the longest wavelengths. Each type of wave, such as visible light or microwaves, falls within a specific range of wavelengths.