4 장 신호(Signals) 4.1 아날로그와 디지털(Analog and Digital)

4 장 신호(Signals) 4.1 아날로그와 디지털(Analog and Digital)
4.2 비주기와 주기 신호(Aperiodic and periodic) 4.3 아날로그 신호(Analog signal) 4.4 디지털 신호(Digital signal) 4.5 요약

신호(cont’d) Information can be voice, image, numeric data, characters, code, picture, and so on To be transmitted, information must be into electromagnetic signals.

신호(cont’d) Transformation of Information to Signals

4.1 Analog and Digital Analog information: continuous(연속: 무게, 키)
Digital information: discrete(불연속, 이산: 학생수) Analog and digital clocks

Analog and Digital(cont’d)
Analog signals can have any value in a range. Digital signals can have only a limited number of values. Comparison of analog and digital signals

4.2 Aperiodic and periodic signals
~ consists of a continuously repeated pattern. The periodic of a signal(T) is expressed in seconds.

Aperiodic and periodic signals(cont’d)
Example of periodic signals

Aperiodic signals(비주기 신호) ~ changes constantly without exhibiting a pattern or cycle that repeat over time.

Example of aperiodic signals

4.3 Analog signals ~ can be classified as simple or complex.
Simple Analog signals the sine wave is the most fundamental form of a periodic analog signal.

Analog signals(cont’d)
A sine wave

Sine wave can be fully described by three characteristics amplitude(진폭) period(주기), frequency(주파수) phase(위상)

Amplitude(진폭) ~ refer to the height of the signal. 특정 순간의 신호 값; voltage(전압), amperes(전류), watts(전력) Period(주기), Frequency(주파수) Period ~ refers to the amount of time, in seconds, a signal needs to complete one cycle. Frequency ~ refers to number of periods a signal makes over the course of one second.(주기의 역수(1/t), 초당 주기의 반복 횟수)

Frequency=1/Period, Period=1/Frequency f = 1 / T , T = 1 / f Unit of Frequency ~ is expressed in Hertz(Hz). Unit of Period ~ is expressed in seconds.

Units of frequency and period

Example 4.1 A sine wave have a frequency of 8KHz. What is its period ? Solution Let T be the period and f be the frequency. Then, T = 1/f = 1/8,000 = = 125 s

Example 4.2 A sine wave completes one cycle in 25 s. what is its frequency? Solution Let T be the period and f be the frequency. Then, f = 1/T = 1/(25*10-6) = 40,000 = 40 KHz

Phase(위상) ~ describes the position of the waveform relative to time zero(단일 주기내에서 시간에 대한 상대적인 위치).

Relationship between different phases

Amplitude change(진폭 변조)

Frequency change(주파수 변조)

Phase change(위상 변조)

More about Frequency Frequency is rate of change with respect to time Change in a short span of time means high frequency. Change in a long span of time means low frequency. Two Extremes If a signal does not change al all, its frequency is zero. If a signal changes instantaneously, its frequency is infinity.

Time versus Frequency Domain Time Domain : instantaneous amplitude with respect to time. Frequency Domain : maximum amplitude with respect to frequency.

Time and Frequency domains

Time and Frequency domains for different signals

Complex Signals A periodic signal decomposed into two sine waves. A signal with a DC component A composite signal decomposed into four components. Complex waveform

A signal with a DC component

Complex waveform

Frequency Spectrum and Bandwidth The frequency spectrum of a signal is the combination of all sine wave signals that make signal. The bandwidth of a signal is the width of the frequency spectrum.

Bandwidth

Example 4.3 If a period signal is decomposed into five sine waves with frequencies of 100, 300, 500, 700, and 900 Hz, What is the bandwidth? Solution Let fh be the highest frequency, fl be the lowest frequency, and B be the bandwidth. Then, B = fh - fl = = 800 Hz

Example 4.4 A signal has a bandwidth of 20 KHz. The highest frequency is 60 KHz. What is the lowest frequency? Solution Let. fh : highest frequency fl : lowest frequency B : Bandwidth B = fh - fl  20 = 60 - fl = fl = = 40 KHz

4.4 Digital Signals A digital signals

Digital Signals(cont’d)
Amplitude(진폭), periodic(주기), phase(위상)

Bit Interval and Bit Rate Bit Interval ~ is the time required to send one single bit. Bit Rate ~ is the number of bits sent in one second.

Bit rate and bit interval

Decomposition of a Digital Signal Harmonics(고조파) of a digital signal

Exact and significant spectrums

The bit rate has a relationship to the significant bandwidth such that when the bit rate increases, the significant bandwidth widens.

Bit rates and significant spectrums

Medium Bandwidth and Significant Bandwidth corruption of a digital signal due to insufficient medium bandwidth

Medium Bandwidth and Data Rate : Channel Capacity Medium Bandwidth and Data Rate

Use of Analog Signals to Transmit Digital Data Example 4.5 What bandwidth is required for data being sent at a rate of 10 bps using analog signals? Assume the each signal element is one bit. Solution

Example 4.6 compare the bandwidths required for analog data being sent at 1,000 and 10,000 bps Solution 10 bps - 5 Hz 1,000 bps Hz 10,000 bps - 5,000 Hz As the data rate increases, the bandwidth also increases.

Example 4.7 We want to transmit 10 pictures per second. Each picture is made 5-by-5 pixels. What is the required bandwidth using digital encoding. Solution 1 page = 25 pixels 25 bit/picture * 10 = 250 bps 125 Hz

Example 4.8 A television screen is composed of a grid of 525 lines by 700 columns(total of 367,500 pixels). A pixel can be black or white(0 or 1). Thirty complete screens(frames) are scanned in one second. What is the theoretical bandwidth required? Solution Bandwidth = (30 * 367,500)/2 = 11,025,000/2 = 5,512,500 = 6 MHz(근사값)

Example 4.8

4.5 요약

4 장 신호(Signals) 4.1 아날로그와 디지털(Analog and Digital)

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4 장 신호(Signals) 4.1 아날로그와 디지털(Analog and Digital)

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