Digital to Analog Modulation

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|ath: & ' ' In this example, baud rate, S = 1000, bit rate. N = 8000, number of bit in each signal unit ,r and signal element, L are unknown. We find first the value of r and then the value of L. S=N * (1/r) = > r = N/S = > r = (8000/1000) = > r = 8 bits/baud Again, we know that r= log2 L => ?L = 2^r => L = 2^8 =256 |

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Bandwidth of ASK: 0 In ASK, the minimum bandwidth required for transmission is equal to the baud rate. 0Bandwidth requires for ASK are calculated using the formula Bandwidth = (1+d) x N baud

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Bandwidth = fc1 Ɗ fc0 + N baud i.e. The bandwidth required for FSK transmission is equal to the baud rate of the signal plus the frequency shift ( difference between the two carrier frequencies).

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ð Bandwidth of an A| signal = 2x bandwidth of modulating signal, and covers a range centered on carrier frequency BWtotal = 2*BW modulating-signal

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A| radio 'The bandwidth of an audio signal (speech + music) is 5 kHz ±each A| radio station needs a min bandwidth of 10 kHz 'A| stations are allowed carrier frequencies anywhere between 530 - 1700 kHz; each stationƍs carrier frequency must be separated from those on either side by at least 10 kHz, to avoid interference

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Frequency Modulation (FM

'Frequency of carrier signal varies with changing frequency of input/modulating signal; amplitude and phase remain unchanged

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Bandwidth of an F| signal = 10xbandwidth of modulating signal, and covers a range centered on carrier frequency BWtotal = 10*BW modulating-signal

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F| radio o The bandwidth of an audio signal (speech and music) in stereo is almost 15 kHz o Each F| radio station needs a minimum bandwidth of 150 kHz o F| stations are allowed carrier frequencies anywhere between 88 and 108 |Hz; stations must be separated by at least 200 kHz to keep their bandwidths from overlapping

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´hase Modulation (´M

Then the modulated signal, This is because it tends to require more complex receiving hardware and there can be ambiguity problems with determining whether, for example, the signal has 0° phase or 180° phase

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Digital to Analog Modulation

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