РефератыИностранный языкTeTechnologism Essay Research Paper The Internet is

Technologism Essay Research Paper The Internet is

Technologism Essay, Research Paper


The Internet is a network of networks that interconnects computers around


the world, supporting both business and residential users. In 1994, a


multimedia Internet application known as the World Wide Web became


popular. The higher bandwidth needs of this application have highlighted


the limited Internet access speeds available to residential users. Even at 28.8


Kilobits per second (Kbps)—the fastest residential access commonly


available at the time of this writing—the transfer of graphical images can be


frustratingly slow.


This report examines two enhancements to existing residential


communications infrastructure: Integrated Services Digital Network (ISDN),


and cable television networks upgraded to pass bi-directional digital traffic


(Cable Modems). It analyzes the potential of each enhancement to deliver


Internet access to residential users. It validates the hypothesis that upgraded


cable networks can deliver residential Internet access more cost-effectively,


while offering a broader range of services.


The research for this report consisted of case studies of two commercial


deployments of residential Internet access, each introduced in the spring of


1994:


? Continental Cablevision and Performance Systems International (PSI)


jointly developed PSICable, an Internet access service deployed over


upgraded cable plant in Cambridge, Massachusetts;


? Internex, Inc. began selling Internet access over ISDN telephone


circuits available from Pacific Bell. Internex’s customers are residences and


small businesses in the “Silicon Valley” area south of San Francisco,


California.


2.0 The Internet


When a home is connected to the Internet, residential communications


infrastructure serves as the “last mile” of the connection between the


home computer and the rest of the computers on the Internet. This


section describes the Internet technology involved in that connection.


This section does not discuss other aspects of Internet technology in


detail; that is well done elsewhere. Rather, it focuses on the services


that need to be provided for home computer users to connect to the


Internet.


2.1


ISDN and upgraded cable networks will each provide different functionality


(e.g. type and speed of access) and cost profiles for Internet connections. It


might seem simple enough to figure out which option can provide the needed


level of service for the least cost, and declare that option “better.” A key


problem with this approach is that it is difficult to define exactly the needed


level of service for an Internet connection. The requirements depend on


the applications being run over the connection, but these applications are


constantly changing. As a result, so are the costs of meeting the applications’


requirements.


Until about twenty years ago, human conversation was by far the dominant


application running on the telephone network. The network was


consequently optimized to provide the type and quality of service needed for


conversation. Telephone traffic engineers measured aggregate statistical


conversational patterns and sized telephone networks accordingly.


Telephony’s well-defined and stable service requirements are reflected in the


“3-3-3″ rule of thumb relied on by traffic engineers: the average voice call


lasts three minutes, the user makes an average of three call attempts during


the peak busy hour, and the call travels over a bidirectional 3 KHz channel.


In contrast, data communications are far more difficult to characterize. Data


transmissions are generated by computer applications. Not only do existing


applications change frequently (e.g. because of software upgrades), but


entirely new categories—such as Web browsers—come into being quickly,


adding different levels and patterns of load to existing networks.


Researchers can barely measure these patterns as quickly as they are


generated, let alone plan future network capacity based on them.


The one generalization that does emerge from studies of both local and wide-


area data traffic over the years is that computer traffic is bursty. It does not


flow in constant streams; rather, “the level of traffic varies widely over


almost any measurement time scale” (Fowler and Leland, 1991). Dynamic


bandwidth allocations are therefore preferred for data traffic, since static


allocations waste unused resources and limit the flexibility to absorb bursts


of traffic.


This requirement addresses traffic patterns, but it says nothing about the


absolute level of load. How can we evaluate a system when we never know


how much capacity is enough? In the personal computing industry, this


problem is solved by defining “enough” to be “however much I can afford


today,” and relying on continuous price-performance improvements in digital


technology to increase that level in the near future. Since both of the


infrastructure upgrade options rely heavily on digital technology, another


criteria for evaluation is the extent to which rapidly advancing technology


can be immediately reflected in improved service offerings.


Cable networks satisfy these evaluation criteria more effectively than


telephone networks because:


? Coaxial cable is a higher quality transmission medium than twisted


copper wire pairs of the same length. Therefore, fewer wires, and


consequently fewer pieces of associated equipment, need to be


installed and maintained to provide the same level of aggregate


bandwidth to a neighborhood. The result should be cost savings and


easier upgrades.


? Cable’s shared bandwidth approach is more flexible at allocating any


particular level of bandwidth among a group of subscribers. Since it


does not need to rely as much on forecasts of which subscribers will


sign up for the service, the cable architecture can adapt more readily


to the actual demand that materializes.


? Telephony’s dedication of bandwidth to individual customers limits


the peak (i.e. burst) data rate that can be provided cost-effectively.


In contrast, the dynamic sharing enabled by cable’s bus architecture


can, if the statistical aggregation properties of neighborhood traffic


cooperate, give a customer access to a faster peak data rate than the


expected average data rate.


2.2 Why focus on Internet access?


Internet access has several desirable properties as an application to


consider for exercising residential infrastructure. Internet technology is


based on a peer-to-peer model of communications. Internet usage


encompasses a wide mix of applications, including low- and high-


bandwidth as well as asynchronous and real-time communications.


Different Internet applications may create varying degrees of


symmetrical (both to and from the home) and asymmetrical traffic


flows. Supporting all of these properties poses a challenge for existing


residential communications infrastructures.


Internet access differs from the future services modeled by other studies


described below in that it is a real application today, with growing


demand. Aside from creating pragmatic interest in the topic, this factor


also makes it possible to perform case studies of real deployments.


Finally, the Internet’s organization as an “Open Data Network” (in the


language of (Computer Science and Telecommunications Board of the


National Research Council, 1994)) makes it a service worthy of study


from a policy perspective. The Internet culture’s expectation of


interconnection and cooperation among competing organizations may


clash with the monopoly-oriented cultures of traditional infrastructure


organizations, exposing policy issues. In addition, the Internet’s status


as a public data network may make Internet access a service worth


encouraging for the public good. Therefore, analysis of costs to provide


this service may provide useful input to future policy debates.


3.0 Technologies


This chapter reviews the present state and technical evolution of


residential cable network infrastructure. It then discusses a topic not


covered much in the literature, namely, how this infrastructure can be


used to provide Internet access. It concludes with a qualitative


evaluation of the advantages and disadvantages of cable-based Internet


access. While ISDN is extensively described in the literature, its use as


an Internet access medium is less well-documented. This chapter


briefly reviews local telephone network technology, including ISDN


and future evolutionary technologies. It concludes with a qualitative


evaluation of the advantages and disadvantages of ISDN-based Internet


access.


3.1 Cable Technology


Residential cable TV networks follow the tree and branch architecture.


In each community, a head end is installed to receive satellite and


traditional over-the-air broadcast television signals. These signals are


then carried to subscriber’s homes over coaxial cable that runs from the


head end throughout the community


Figure 3.1: Coaxial cable tree-and-branch topology


To achieve geographical coverage of the community, the cables


emanating from the head end are split (or “branched”) into multiple


cables. When the cable is physically split, a portion of the signal power


is split off to send down the branch. The signal content, however, is not


split: the same set of TV channels reach every subscriber in the


community. The network thus follows a logical bus architecture. With


this architecture, all channels reach every subscriber all the time,


whether or not the subscriber’s TV is on. Just as an ordinary television


includes a tuner to select the over-the-air channel the viewer wishes to


watch, the subscriber’s cable equipment includes a tuner to select


among all the channels received over the cable.


3.1.1. Technological evolution


The development of fiber-optic transmission technology has led cable


network developers to shift from the purely coaxial tree-and-branch


architecture to an approach referred to as Hybrid Fiber and Coax(HFC)


networks. Transmission over fiber-optic cable has two main advantages


over coaxial cable:


? A wider range of frequencies can be sent over the fiber, increasing


the bandwidth available for transmission;


? Signals can be transmitted greater distances without amplification.


The main disadvantage of fiber is that the optical components required


to send and receive data over it are expensive. Because lasers are still


too expensive to deploy to each subscriber, network developers have


adopted an intermediate Fiber to the Neighborhood (FTTN)approach.


Figure 3.3: Fiber to the Neighborhood (FTTN) architecture


Various locations along the existing cable are selected as sites for


neighborhood nodes. One or more fiber-optic cables are then run from


the head end to each neighborhood node. At the head end, the signal is


converted from electrical to optical form and transmitted via laser over


the fiber. At the neighborhood node, the signal is received via laser,


converted back from optical to electronic form, and transmitted to the


subscriber over the neighborhood’s coaxial tree and branch network.


FTTN has proved to be an appealing architecture for telephone


companies as well as cable operators. Not only Continental


Cablevision and Time Warner, but also Pacific Bell and Southern New


England Telephone have announced plans to build FTTN networks.


Fiber to the neighborhood is one stage in a longer-range evolution of


the cable plant. These longer-term changes are not necessary to provide


Internet service today, but they might affect aspects of how Internet


service is provided in the future.


3.2 ISDN Technology


Unlike cable TV networks, which were built to provide only local


redistribution of television programming, telephone networks provide


switched, global connectivity: any telephone subscriber can call any


other telephone subscriber anywhere else in the world. A call placed


from a home travels first to the closest telephone company Central


Office (CO) switch. The CO switch routes the call to the destination


subscriber, who may be served by the same CO switch, another CO


switch in the same local area, or a CO switch reached through a long-


distance network.


Figure 4.1: The telephone network


The portion of the telephone network that connects the subscriber to


the closest CO switch is referred to as the local loop. Since all calls


enter and exit the network via the local loop, the nature of the local


connection directly affects the type of service a user gets from the


global telephone network.


With a separate pair of wires to serve each subscriber, the local


telephone network follows a logical star architecture. Since a Central


Office typically serves thousands of subscribers, it would be unwieldy


to string wires individually to each home. Instead, the wire pairs are


aggregated into groups, the largest of which are feeder cables. At


intervals along the feeder portion of the loop, junction boxes are placed.


In a junction box, wire pairs from feeder cables are spliced to wire pairs


in distribution cables that run into neighborhoods. At each subscriber


location, a drop wire pair (or pairs, if the subscriber has more than one


line) is spliced into the distribution cable.


Since distribution cables are either buried or aerial, they are disruptive


and expensive to change. Consequently, a distribution cable usually


contains as many wire pairs as a neighborhood might ever need, in


advance of actual demand.


Implementation of ISDN is hampered by the irregularity of the local


loop plant. Referring back to Figure 4.3, it is apparent that loops are of


different lengths, depending on the subscriber’s distance from the


Central Office. ISDN cannot be provided over loops with loading coils


or loops longer than 18,000 feet (5.5 km).


4.0 Internet Access


This section will outline the contrasts of access via the cable plant with


respect to access via the local telephon network.


4.1 Internet Access Via Cable


The key question in providing residential Internet access is what kind of


network technology to use to connect the customer to the Internet For


residential Internet delivered over the cable plant, the answer is


broadband LAN technology. This technology allows transmission of


digital data over one or more of the 6 MHz channels of a CATV cable.


Since video and audio signals can also be transmitted over other


channels of the same cable, broadband LAN technology can co-exist


with currently existing services.


Bandwidth


The speed of a cable LAN is described by the bit rate of the modems


used to send data over it. As this technology improves, cable LAN


speeds may change, but at the time of this writing, cable modems range


in speed from 500 Kbps to 10 Mbps, or roughly 17 to 340 times the bit


rate of the familiar 28.8 Kbps telephone modem. This speed represents


the peak rate at which a subscriber can send and receive data, during


the periods of time when the medium is allocated to that subscriber. It


does not imply that every subscriber can transfer data at that rate


simultaneously. The effective average bandwidth seen by each


subscriber depends on how busy the LAN is. Therefore, a cable LAN


will appear to provide a variable bandwidth connection to the Internet


Full-time connections


Cable LAN bandwidth is allocated dynamically to a subscriber only


when he has traffic to send. When he is not transferring traffic, he does


not consume transmission resources. Consequently, he can always be


connected to the Internet Point of Presence without requiring an


expensive dedication of transmission resources.


4.2 Internet Access Via Telephone Company


In contrast to the shared-bus architecture of a cable LAN, the telephone


network requires the residential Internet provider to maintain multiple


connection ports in order to serve multiple customers simultaneously.


Thus, the residential Internet provider faces problems of multiplexing


and concentration of individual subscriber lines very similar to those


faced in telephone Central Offices.


The point-to-point telephone network gives the residential Internet


provider an architecture to work with that is fundamentally different


from the cable plant. Instead of multiplexing the use of LAN


transmission bandwidth as it is needed, subscribers multiplex the use of


dedicated connections to the Internet provider over much longer time


intervals. As with ordinary phone calls, subscribers are allocated fixed


amounts of bandwidth for the duration of the connection. Each


subscriber that succeeds in becoming active (i.e. getting connected to


the residential Internet provider instead of getting a busy signal) is


guaranteed a particular level of bandwidth until hanging up the call.


Bandwidth


Although the predictability of this connection-oriented approach is


appealing, its major disadvantage is the limited level of bandwidth that


can be economically dedicated to each customer. At most, an ISDN


line can deliver 144 Kbps to a subscriber, roughly four times the


bandwidth available with POTS. This rate is both the average and the


peak data rate. A subscriber needing to burst data quickly, for example


to transfer a large file or engage in a video conference, may prefer a


shared-bandwidth architecture, such as a cable LAN, that allows a


higher peak data rate for each individual subscriber. A subscriber who


needs a full-time connection requires a dedicated port on a terminal


server. This is an expensive waste of resources when the subscriber is


connected but not tr

ansferring data.


The Internet is a network of networks that interconnects computers around


the world, supporting both business and residential users. In 1994, a


multimedia Internet application known as the World Wide Web became


popular. The higher bandwidth needs of this application have highlighted


the limited Internet access speeds available to residential users. Even at 28.8


Kilobits per second (Kbps)—the fastest residential access commonly


available at the time of this writing—the transfer of graphical images can be


frustratingly slow.


This report examines two enhancements to existing residential


communications infrastructure: Integrated Services Digital Network (ISDN),


and cable television networks upgraded to pass bi-directional digital traffic


(Cable Modems). It analyzes the potential of each enhancement to deliver


Internet access to residential users. It validates the hypothesis that upgraded


cable networks can deliver residential Internet access more cost-effectively,


while offering a broader range of services.


The research for this report consisted of case studies of two commercial


deployments of residential Internet access, each introduced in the spring of


1994:


? Continental Cablevision and Performance Systems International (PSI)


jointly developed PSICable, an Internet access service deployed over


upgraded cable plant in Cambridge, Massachusetts;


? Internex, Inc. began selling Internet access over ISDN telephone


circuits available from Pacific Bell. Internex’s customers are residences and


small businesses in the “Silicon Valley” area south of San Francisco,


California.


2.0 The Internet


When a home is connected to the Internet, residential communications


infrastructure serves as the “last mile” of the connection between the


home computer and the rest of the computers on the Internet. This


section describes the Internet technology involved in that connection.


This section does not discuss other aspects of Internet technology in


detail; that is well done elsewhere. Rather, it focuses on the services


that need to be provided for home computer users to connect to the


Internet.


2.1


ISDN and upgraded cable networks will each provide different functionality


(e.g. type and speed of access) and cost profiles for Internet connections. It


might seem simple enough to figure out which option can provide the needed


level of service for the least cost, and declare that option “better.” A key


problem with this approach is that it is difficult to define exactly the needed


level of service for an Internet connection. The requirements depend on


the applications being run over the connection, but these applications are


constantly changing. As a result, so are the costs of meeting the applications’


requirements.


Until about twenty years ago, human conversation was by far the dominant


application running on the telephone network. The network was


consequently optimized to provide the type and quality of service needed for


conversation. Telephone traffic engineers measured aggregate statistical


conversational patterns and sized telephone networks accordingly.


Telephony’s well-defined and stable service requirements are reflected in the


“3-3-3″ rule of thumb relied on by traffic engineers: the average voice call


lasts three minutes, the user makes an average of three call attempts during


the peak busy hour, and the call travels over a bidirectional 3 KHz channel.


In contrast, data communications are far more difficult to characterize. Data


transmissions are generated by computer applications. Not only do existing


applications change frequently (e.g. because of software upgrades), but


entirely new categories—such as Web browsers—come into being quickly,


adding different levels and patterns of load to existing networks.


Researchers can barely measure these patterns as quickly as they are


generated, let alone plan future network capacity based on them.


The one generalization that does emerge from studies of both local and wide-


area data traffic over the years is that computer traffic is bursty. It does not


flow in constant streams; rather, “the level of traffic varies widely over


almost any measurement time scale” (Fowler and Leland, 1991). Dynamic


bandwidth allocations are therefore preferred for data traffic, since static


allocations waste unused resources and limit the flexibility to absorb bursts


of traffic.


This requirement addresses traffic patterns, but it says nothing about the


absolute level of load. How can we evaluate a system when we never know


how much capacity is enough? In the personal computing industry, this


problem is solved by defining “enough” to be “however much I can afford


today,” and relying on continuous price-performance improvements in digital


technology to increase that level in the near future. Since both of the


infrastructure upgrade options rely heavily on digital technology, another


criteria for evaluation is the extent to which rapidly advancing technology


can be immediately reflected in improved service offerings.


Cable networks satisfy these evaluation criteria more effectively than


telephone networks because:


? Coaxial cable is a higher quality transmission medium than twisted


copper wire pairs of the same length. Therefore, fewer wires, and


consequently fewer pieces of associated equipment, need to be


installed and maintained to provide the same level of aggregate


bandwidth to a neighborhood. The result should be cost savings and


easier upgrades.


? Cable’s shared bandwidth approach is more flexible at allocating any


particular level of bandwidth among a group of subscribers. Since it


does not need to rely as much on forecasts of which subscribers will


sign up for the service, the cable architecture can adapt more readily


to the actual demand that materializes.


? Telephony’s dedication of bandwidth to individual customers limits


the peak (i.e. burst) data rate that can be provided cost-effectively.


In contrast, the dynamic sharing enabled by cable’s bus architecture


can, if the statistical aggregation properties of neighborhood traffic


cooperate, give a customer access to a faster peak data rate than the


expected average data rate.


2.2 Why focus on Internet access?


Internet access has several desirable properties as an application to


consider for exercising residential infrastructure. Internet technology is


based on a peer-to-peer model of communications. Internet usage


encompasses a wide mix of applications, including low- and high-


bandwidth as well as asynchronous and real-time communications.


Different Internet applications may create varying degrees of


symmetrical (both to and from the home) and asymmetrical traffic


flows. Supporting all of these properties poses a challenge for existing


residential communications infrastructures.


Internet access differs from the future services modeled by other studies


described below in that it is a real application today, with growing


demand. Aside from creating pragmatic interest in the topic, this factor


also makes it possible to perform case studies of real deployments.


Finally, the Internet’s organization as an “Open Data Network” (in the


language of (Computer Science and Telecommunications Board of the


National Research Council, 1994)) makes it a service worthy of study


from a policy perspective. The Internet culture’s expectation of


interconnection and cooperation among competing organizations may


clash with the monopoly-oriented cultures of traditional infrastructure


organizations, exposing policy issues. In addition, the Internet’s status


as a public data network may make Internet access a service worth


encouraging for the public good. Therefore, analysis of costs to provide


this service may provide useful input to future policy debates.


3.0 Technologies


This chapter reviews the present state and technical evolution of


residential cable network infrastructure. It then discusses a topic not


covered much in the literature, namely, how this infrastructure can be


used to provide Internet access. It concludes with a qualitative


evaluation of the advantages and disadvantages of cable-based Internet


access. While ISDN is extensively described in the literature, its use as


an Internet access medium is less well-documented. This chapter


briefly reviews local telephone network technology, including ISDN


and future evolutionary technologies. It concludes with a qualitative


evaluation of the advantages and disadvantages of ISDN-based Internet


access.


3.1 Cable Technology


Residential cable TV networks follow the tree and branch architecture.


In each community, a head end is installed to receive satellite and


traditional over-the-air broadcast television signals. These signals are


then carried to subscriber’s homes over coaxial cable that runs from the


head end throughout the community


Figure 3.1: Coaxial cable tree-and-branch topology


To achieve geographical coverage of the community, the cables


emanating from the head end are split (or “branched”) into multiple


cables. When the cable is physically split, a portion of the signal power


is split off to send down the branch. The signal content, however, is not


split: the same set of TV channels reach every subscriber in the


community. The network thus follows a logical bus architecture. With


this architecture, all channels reach every subscriber all the time,


whether or not the subscriber’s TV is on. Just as an ordinary television


includes a tuner to select the over-the-air channel the viewer wishes to


watch, the subscriber’s cable equipment includes a tuner to select


among all the channels received over the cable.


3.1.1. Technological evolution


The development of fiber-optic transmission technology has led cable


network developers to shift from the purely coaxial tree-and-branch


architecture to an approach referred to as Hybrid Fiber and Coax(HFC)


networks. Transmission over fiber-optic cable has two main advantages


over coaxial cable:


? A wider range of frequencies can be sent over the fiber, increasing


the bandwidth available for transmission;


? Signals can be transmitted greater distances without amplification.


The main disadvantage of fiber is that the optical components required


to send and receive data over it are expensive. Because lasers are still


too expensive to deploy to each subscriber, network developers have


adopted an intermediate Fiber to the Neighborhood (FTTN)approach.


Figure 3.3: Fiber to the Neighborhood (FTTN) architecture


Various locations along the existing cable are selected as sites for


neighborhood nodes. One or more fiber-optic cables are then run from


the head end to each neighborhood node. At the head end, the signal is


converted from electrical to optical form and transmitted via laser over


the fiber. At the neighborhood node, the signal is received via laser,


converted back from optical to electronic form, and transmitted to the


subscriber over the neighborhood’s coaxial tree and branch network.


FTTN has proved to be an appealing architecture for telephone


companies as well as cable operators. Not only Continental


Cablevision and Time Warner, but also Pacific Bell and Southern New


England Telephone have announced plans to build FTTN networks.


Fiber to the neighborhood is one stage in a longer-range evolution of


the cable plant. These longer-term changes are not necessary to provide


Internet service today, but they might affect aspects of how Internet


service is provided in the future.


3.2 ISDN Technology


Unlike cable TV networks, which were built to provide only local


redistribution of television programming, telephone networks provide


switched, global connectivity: any telephone subscriber can call any


other telephone subscriber anywhere else in the world. A call placed


from a home travels first to the closest telephone company Central


Office (CO) switch. The CO switch routes the call to the destination


subscriber, who may be served by the same CO switch, another CO


switch in the same local area, or a CO switch reached through a long-


distance network.


Figure 4.1: The telephone network


The portion of the telephone network that connects the subscriber to


the closest CO switch is referred to as the local loop. Since all calls


enter and exit the network via the local loop, the nature of the local


connection directly affects the type of service a user gets from the


global telephone network.


With a separate pair of wires to serve each subscriber, the local


telephone network follows a logical star architecture. Since a Central


Office typically serves thousands of subscribers, it would be unwieldy


to string wires individually to each home. Instead, the wire pairs are


aggregated into groups, the largest of which are feeder cables. At


intervals along the feeder portion of the loop, junction boxes are placed.


In a junction box, wire pairs from feeder cables are spliced to wire pairs


in distribution cables that run into neighborhoods. At each subscriber


location, a drop wire pair (or pairs, if the subscriber has more than one


line) is spliced into the distribution cable.


Since distribution cables are either buried or aerial, they are disruptive


and expensive to change. Consequently, a distribution cable usually


contains as many wire pairs as a neighborhood might ever need, in


advance of actual demand.


Implementation of ISDN is hampered by the irregularity of the local


loop plant. Referring back to Figure 4.3, it is apparent that loops are of


different lengths, depending on the subscriber’s distance from the


Central Office. ISDN cannot be provided over loops with loading coils


or loops longer than 18,000 feet (5.5 km).


4.0 Internet Access


This section will outline the contrasts of access via the cable plant with


respect to access via the local telephon network.


4.1 Internet Access Via Cable


The key question in providing residential Internet access is what kind of


network technology to use to connect the customer to the Internet For


residential Internet delivered over the cable plant, the answer is


broadband LAN technology. This technology allows transmission of


digital data over one or more of the 6 MHz channels of a CATV cable.


Since video and audio signals can also be transmitted over other


channels of the same cable, broadband LAN technology can co-exist


with currently existing services.


Bandwidth


The speed of a cable LAN is described by the bit rate of the modems


used to send data over it. As this technology improves, cable LAN


speeds may change, but at the time of this writing, cable modems range


in speed from 500 Kbps to 10 Mbps, or roughly 17 to 340 times the bit


rate of the familiar 28.8 Kbps telephone modem. This speed represents


the peak rate at which a subscriber can send and receive data, during


the periods of time when the medium is allocated to that subscriber. It


does not imply that every subscriber can transfer data at that rate


simultaneously. The effective average bandwidth seen by each


subscriber depends on how busy the LAN is. Therefore, a cable LAN


will appear to provide a variable bandwidth connection to the Internet


Full-time connections


Cable LAN bandwidth is allocated dynamically to a subscriber only


when he has traffic to send. When he is not transferring traffic, he does


not consume transmission resources. Consequently, he can always be


connected to the Internet Point of Presence without requiring an


expensive dedication of transmission resources.


4.2 Internet Access Via Telephone Company


In contrast to the shared-bus architecture of a cable LAN, the telephone


network requires the residential Internet provider to maintain multiple


connection ports in order to serve multiple customers simultaneously.


Thus, the residential Internet provider faces problems of multiplexing


and concentration of individual subscriber lines very similar to those


faced in telephone Central Offices.


The point-to-point telephone network gives the residential Internet


provider an architecture to work with that is fundamentally different


from the cable plant. Instead of multiplexing the use of LAN


transmission bandwidth as it is needed, subscribers multiplex the use of


dedicated connections to the Internet provider over much longer time


intervals. As with ordinary phone calls, subscribers are allocated fixed


amounts of bandwidth for the duration of the connection. Each


subscriber that succeeds in becoming active (i.e. getting connected to


the residential Internet provider instead of getting a busy signal) is


guaranteed a particular level of bandwidth until hanging up the call.


Bandwidth


Although the predictability of this connection-oriented approach is


appealing, its major disadvantage is the limited level of bandwidth that


can be economically dedicated to each customer. At most, an ISDN


line can deliver 144 Kbps to a subscriber, roughly four times the


bandwidth available with POTS. This rate is both the average and the


peak data rate. A subscriber needing to burst data quickly, for example


to transfer a large file or engage in a video conference, may prefer a


shared-bandwidth architecture, such as a cable LAN, that allows a


higher peak data rate for each individual subscriber. A subscriber who


needs a full-time connection requires a dedicated port on a terminal


server. This is an expensive waste of resources when the subscriber is


connected but not transferring data.

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