Analog and Digital Comparison

Technologies for analog-to-digital and digital-to-analog conversions There is no actual all analog or all digital telecommunications going on technologically today (Goleniewsk & Wilson Jarrett, 2007, Chapter Chapter 1, Analog Versus Digital Transmission). One day, developers hope to make the network 100% digital. Connecting to the internet or just making a call to your mother two states over is a mixture of both when it comes to communicating from one terminal to the next. That being said, it takes codecs and modems for a successful conversion to occur.
Say you are calling another state from a land line. This call will start out analog at your telephone and then must be converted to digital. When you pick your phone up, it connects to a codec. Your voice can range from 100Hz to 10,000Hz depending on many factors. The average Hz a phone company will allot is 4,000 which works for virtually all people. Codec is short for coder-decoder and it works by minimizing the amount of bits per second that will carry the voice to the multiplexer. In the case of a cellular network, the data will have to be compressed even further so that the most efficient transmission can occur. The codec will then transfer the data to a multiplexer. This particular multiplexer is a TDM (time division multiplexer). This will allow for one channel to be open at a time. This does make sense since it would not be good to take over a phone line once it is being used. From the TDM, it will go via satellite and the process will be reversed to meet the person on the other end of the line. A modem is what connects your home computer to the ISP (internet service provider). It is not to be confused with a router, which connects computers and other devices to the internet the modem is using. The computer can either be connected via an Ethernet cable or a wifi connection. The modem is connected to a dish outside of the building that is signaling with a satellite. The satellite will then transmit to an FDM (frequency time division multiplexer) which can be a tower receiver that is connected to the facility which is hardwired. Internet service providers choose the FDM because they have many subscribers that do not use a time share data plan on the web. Like a satellite television provider, they must have many channels available twenty-four hours a day.

Comparing Analog Modulation Technologies With analog technology it is possible to send and receive digital information in a variety of formats. These include amplitude modulation, frequency modulation, phase modulation, quadrature amplitude modulation (QAM). All of these modulation methods transmit binary information using varying techniques and each has its own advantages and disadvantages. Generally these techniques operate on the idea that the current is being measured at steady intervals to determine the amplitude, frequency, or phase of the current’s wave. Each technique would has a standard current and deviates from that standard in some way in order to differentiate between bits of one or zero. The amplitude is the height of the wave and it indicates the signal strength (Goleniewski, 2007). Amplitude modulation represents the binary codes by presenting ones and zeros as either the presence or absence of a wave. Amplitude modulation is not always ideal because noise spikes can affect the signal reception and interfere with the transfer of data. With this type of modulation interrupted connections can also effect the data that is received because the absence of a signal may be interpreted as a zero. There is not an effective way to determine that the signal has been interrupted (Blanchard, 2001). The frequency is the oscillations of the wave per second, different frequencies operate at different oscillation speeds (Goleniewski, 2007). Frequency modulation is a method where two separate frequencies are used to represent the ones and zeros of binary code. This method can be more reliable than amplitude modulation because there is always a constant signal and it is easy to tell when there is an interruption in the transmission (Blanchard, 2001). Another basic form of data transmission uses the phases of the wave. The phase is basically where the wave is at a specific point in time as compared to a reference point (Goleniewski, 2007). Phase Modulation relies on altering the phase of a frequency at each interval. This type of modulation is more complex and requires better equipment because of the necessity to alter the phases and detect phase changes (Blanchard, 2001). Quadrature Amplitude Modulation (QAM) is a method which combines amplitude and phase modulation to send multiple data streams at the same time. For this method at least two signals would be used and the signals would differ from each other by a quarter of a cycle of their phase. This separation of the phases by quarters is why it is called Quadrature Amplitude Modulation. This method can increase the rate of data transfer as compared to the other methods and is possible because the currents intersect at right angles and this makes it possible to use sine and cosine to calculate the value of each signal (Poole, n.d.).

Specific modulation techniques used in 56K modems, Asymmetrical Digital Subscriber Lines, and Wi-Fi There are different modulation techniques that correspond to different technologies, particularly for 56k modems, ADSL and Wi-Fi. Modulation is a method for transmitting information, and gives the name for the devices used to achieve such transmission. Modems are MOdulators/DEModulators. They package the digital information for transmission over an analog signal, like those of telephone lines. For 56k modems, modulators package the initial information from digital to analog, so demodulators can convert it from analog to digital. The information is transmitted through an analog signal on a specific frequency, the carrier. Due to its analog nature, that transmission is very susceptible to interference from electric fields and impedance. Asymmetrical digital subscriber line (or ADSL), supports up to twelve megabits in its down link, and up to one point eight megabits in its uplink, depending on the DSL standard employed. Newer technologies dubbed ADSL two provide higher speeds for both downloading and uploading data. The term Asymmetric refers to the characteristic of offering different speeds for uploading and downloading data, the latter providing usually much higher speeds. As this specification was designed with the home consumer in mind, higher downloads speeds are usually preferred or needed over upload speeds contrary to the business sector.

As the ADSL transmission goes through the same twisted-wire pair channel as the normal voice band, the Discrete Multitone code was designed to overcome the variation of the transmission functions versus the frequency within range of interest. To achieve that, the Discrete Fourier Transform techniques were used to divide the modulated signal into various orthogonal signals. The downstream signal was divided into 256 discrete subcarriers, and the upstream signal into 32. The quadrature amplitude modulation (QAM) was employed, making the subcarriers able to use their own frequency band, making it possible to process the subcarriers independently of other subcarriers. Wi-Fi was developed for wireless communication over short distances, and it means Wireless Fidelity. It uses a radio network, and operates in the principle of a sender and a receiver. Wi-Fi systems use two primary radio transmission techniques, with a third deprecated option that is no longer preferred nor used; Direct Sequence Spread Spectrum’s (DSSS), OFDM and Frequency Hopping Spread Spectrum (FHSS). DSSS defines as channels groups of frequencies 22MHz wide. OFDM uses a 64-channel and one of two levels of Quadrature Amplitude Modulation (16, or 64-QAM).

The T(X) and the synchronous optical network (SONET) digital hierarchy SONET is described as being a Synchronous Optical Network (SONET) and was designed by the American National Standard institute or otherwise known as ANSI for the use of telephone network in the mid 1980’s. AT&T forced the breakup of Telephone and Telegraph in the United States that created many other telephone companies. With all of these different companies trying to work with each other it was soon apparent that there was going to be some issues. This is when fiber optic cables came around. These cables were used for long distant voice traffic. These cables were proven to be very expensive to work with as well as difficult to maintain and keep running. This is when SONET was developed by the ANSI. SONET became the new standard used by these companies. SONET like Ethernet is a layer one protocol known as interface layer technology or in the Open Systems Interconnection (OSI) model is termed the physical layer. Here SONET acts like a carrier for multiple different levels of protocols. For example, SONET is able to act as a carrier that is able to configure the data that is trying to be used into internet protocol (IP) packets. This information is than sent over the speeds of 155 megabits per second all the way to 2.5 megabytes per second. In order for this to be possible, SONET will take several channels that are not being used and pair them together to send the data packet. The SONET path makes it possible for sending and receiving this information by being able to detect where the beginning and end is in the stream of bits that are being sent across. The biggest advantage of using SONET is that it will help with reducing the chances that the information that is being sent across the internet is going to be damaged or lost by creating signal checks. This will tell if there is going to be enough power to send the information.
References
Goleniewsk, L., & Wilson Jarrett, K. (2007). Telecommunications Essentials. The Complete Global Source, Second Edition (2nd ed.). Retrieved from The University of Phoenix eBook Collection database

Blanchard, E. (2001). Introduction to Networking: and Data Communications. Retrieved from http://epq.com.co/softw_internet/nag1/c4049.htm

Goleniewski, L. (2007). Telecommunications essentials. (2nd ed.) Boston, MA: Pearson.
Poole, I. (n.d.). What is QAM - Quadrature Amplitude Modulation. Retrieved from http://www.radio-electronics.com/info/rf-technology-design/quadrature-amplitude-modulation-qam/what-is-qam-tutorial.php

TutorialsPoint.com. (n.d.). Wi-Fi Radio Modulation. Retrieved from http://www.tutorialspoint.com/wi-fi/wifi_radio_modulation.htm

Woodford, C. (2014, May 16). Broadband Internet. Retrieved from http://www.explainthatstuff.com/howbroadbandworks.html

Margaret Rouse (2014). Synchronous Optical Network. [ONLINE] Available at: http://searchnetworking.techtarget.com/definition/Synchronous-Optical-Network

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Analog and Digital Comparison
NTC/362 - FUNDAMENTALS OF NETWORKING
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September 8, 2014