Chapter 2 / 2.6
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2.6 REVISION QUESTIONS
- Write an equation for the sinusoidal voltage waveform as a function of distance travelled.
- Write an equation for the sinusoidal voltage waveform as a function of the time it has been travelling.
- Write an equation for the relationship between wavelength and frequency.
- Sketch a 2-V, 1-kHz sine wave and a 4-V, 10-kHz sine wave in the time domain and the frequency domain.
- Write an equation for a sinusoidal waveform, including the three wave properties of amplitude, frequency, and phase.
- List the frequency ranges of the HF, VHF, UHF and SHF frequency bands. Briefly describe the communications uses of each band.
- List four advantages of digital signals over analog signals.
- Describe the difference between baud rate, data rate, and information rate.
- Describe the difference between synchronous and asynchronous data transmission.
- Explain why a perfectly rectangular digital pulse requires infinite bandwidth, and describe the practical consequence of this requirement.
- A binary polar NRZ signal is transmitted at 8 bps. (a) Where does the first spectral null occur? (b) How does this change if the bit rate is doubled?
- Describe inter-symbol interference (ISI) using both the time-domain and frequency-domain viewpoints.
- Why does increasing the order of an M-ary signaling scheme reduce symbol rate but increase sensitivity to noise?
- Explain why regeneration is possible for digital signals but not for analog signals.
- A communication channel has a bandwidth of 3 kHz.
(a) What is the maximum symbol rate for a noiseless channel?
(b) Why is this rate not achievable in practice?
- Distinguish clearly between: transmission rate, information rate, and channel capacity.
- Give two reasons why modern high-speed systems prefer serial transmission over parallel transmission.
- Explain why most long-distance communication systems use bandpass transmission rather than baseband transmission.
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