A Casa da Mãe Joana

[Lucy in the Sky]

Consegui. Dá pra ver aí? Não sei como isso funciona.

 

http://www.facebook.com/login/setashome.php?ref=genlogin#!/profile.php?id=100002127964701

 

 

[Flutotal]

 

Além de "Medo (A Tale of twoSisters)" que o Scofa falou' date=' tem outros filmes orientais que melam a cueca: Audition, Kairo e One Missed Call, sendo este último com menos intensidade.

[/quote']

 

Espiritos (Shutter) é o maior desses orientais.

 

Não vi esse. Me contaram o final e perdi a vontade. Mas um dia ainda tento novamente.

 

Mas acho difícil ser superior a Medo e Kairo.

 

Nossa, mate quem te contou o final, vc perdeu o melhor filme da safra

 

É BEM superior a medo e Kairo, vários cagaços confirmados

 

[Lucy in the Sky]

Mmmbop, ba duba dop

 

Ba du bop, ba duba dop

 

Ba du bop, ba duba dop

 

Ba du

 

Mmmbop, ba duba dop

 

Ba du bop, Ba du dop

 

Ba du bop, Ba du dop

 

Ba du

 

 

Que coisa chata.

 

 

[Flutotal]

Nem vc aguenta viu so?

 

[Lucy in the Sky]

 

Nem vc aguenta viu so?

Eu sou fã de Hanson por causa dos dois últimos CDs. Não gosto da fase pirralhos.

 

[Tensor]

Consegui. Dá pra ver aí? Não sei como isso funciona.http://www.facebook.com/login/setashome.php?ref=genlogin#!/profile.php?id=100002127964701

 

 

 

 

Aceita, te enviei uma solicitação. Vai aparecer um vermelhinho na parte de cima, tu clica e lá vai estar eu.

[Lucy in the Sky]

 

Consegui. Dá pra ver aí? Não sei como isso funciona.http://www.facebook.com/login/setashome.php?ref=genlogin#!/profile.php?id=100002127964701

 

 

 

 

Aceita' date=' te enviei uma solicitação. Vai aparecer um vermelhinho na parte de cima, tu clica e lá vai estar eu.[/quote']

Consegui.

 

Acho que estou encontrando o povo do fórum.

 

[Mr. Scofield]

 

Além de "Medo (A Tale of twoSisters)" que o Scofa falou' date=' tem outros filmes orientais que melam a cueca: Audition, Kairo e One Missed Call, sendo este último com menos intensidade.

[/quote']

 

Espiritos (Shutter) é o maior desses orientais.

Não é de jeito nenhum, A Tale of Two Sisters >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> Shutter. Acho que nossos gostos não batem mesmo.

 

[Mr. Scofield]

 

 

Alta Tensão é bem bom sim. E antecipar o final não tira a qualidade do filme.

Neste caso tira porque todo o filme se baseia em escondê-lo (ao contrário de um Shutter Island, que saber o que vai acontecer chega a ser um prêmio para que você possa observar outros elementos). E nas tentativas de fazê-lo é clichezento e besta.

Mr. Scofield2011-04-29 19:27:10

[Bronson]

Se fizer uma pesquisa na rua ae de heróis mais conhecidos é isso aqui que você vai encontrar:

 

1 - Superman

2 - Bátima

3 - Homem Aranha

4 - Hulk

.

.

.

5 - Mulher Maravilha (a única mulher na parada)

 

 

Abaixo' date=' bem abaixo, vem o resto.

[/quote']

Discordo, nunca que o Superman supera o Polegar Vermelho em popularidade, é sem dúvida o Top 1....

 

[Bronson]

Sociedade do anel cara!!!

Olha' date=' também sou chegado em um anel...[/quote']

Que piada original hein...

Ainda bem que o Cako é chegado em um anel, ruim mesmo é a turma que queima....

[Jack Ryan]

 

Tchurma' date=' vou encerrar hoje a escolha dos melhores filmes da década de 1950. Quem ainda não votou e quiser participar pode passar aqui:

 

 

 

http://www.cinemaemcena.com.br/forum/forum_posts.asp?TID=18112[/quote']Até queria votar, Jack. Mas não vi filme suficientes. Sairia uma lista de 10 com 8 do Hitch. smileys/06.gif" align="absmiddle" alt="06" />

 

 

 

Tudo bem, nada mais justo que o Hitch dominar.

[Judy Rush]

 

Internet

From Wikipedia, the free encyclopedia

This article is about the public worldwide computer network system. For other uses, see Internet (disambiguation).

Page semi-protected

Internet

Internet map 1024.jpg

Visualization from the Opte Project of the various routes through a portion of the Internet

Computer network types by area

 

    Body (BAN)

    Personal (PAN)

    Near-me (NAN)

    Storage (SAN)

    Local (LAN)

        Home (HAN)

    Campus (CAN)

    Metropolitan (MAN)

    Wide (WAN)

    Global (GAN)

    Internet

    Interplanetary Internet

 

This box: view · talk · edit

 

The Internet is a global system of interconnected computer networks that use the standard Internet Protocol Suite (TCP/IP) to serve billions of users worldwide. It is a network of networks that consists of millions of private, public, academic, business, and government networks, of local to global scope, that are linked by a broad array of electronic, wireless and optical networking technologies. The Internet carries a vast range of information resources and services, such as the inter-linked hypertext documents of the World Wide Web (WWW) and the infrastructure to support electronic mail.

 

Most traditional communications media including telephone, music, film, and television are reshaped or redefined by the Internet, giving birth to new services such as Voice over Internet Protocol (VoIP) and IPTV. Newspaper, book and other print publishing are adapting to Web site technology, or are reshaped into blogging and web feeds. The Internet has enabled or accelerated new forms of human interactions through instant messaging, Internet forums, and social networking. Online shopping has boomed both for major retail outlets and small artisans and traders. Business-to-business and financial services on the Internet affect supply chains across entire industries.

 

The origins of the Internet reach back to research of the 1960s, commissioned by the United States government in collaboration with private commercial interests to build robust, fault-tolerant, and distributed computer networks. The funding of a new U.S. backbone by the National Science Foundation in the 1980s, as well as private funding for other commercial backbones, led to worldwide participation in the development of new networking technologies, and the merger of many networks. The commercialization of what was by the 1990s an international network resulted in its popularization and incorporation into virtually every aspect of modern human life. As of 2009, an estimated quarter of Earth's population used the services of the Internet.

 

The Internet has no centralized governance in either technological implementation or policies for access and usage; each constituent network sets its own standards. Only the overreaching definitions of the two principal name spaces in the Internet, the Internet Protocol address space and the Domain Name System, are directed by a maintainer organization, the Internet Corporation for Assigned Names and Numbers (ICANN). The technical underpinning and standardization of the core protocols (IPv4 and IPv6) is an activity of the Internet Engineering Task Force (IETF), a non-profit organization of loosely affiliated international participants that anyone may associate with by contributing technical expertise.

Contents

[hide]

 

    1 Terminology

    2 History

    3 Technology

        3.1 Protocols

        3.2 Structure

    4 Governance

    5 Modern uses

    6 Services

        6.1 Information

        6.2 Communication

        6.3 Data transfer

    7 Access

    8 Social impact

    9 See also

    10 Notes

    11 References

    12 External links

 

Terminology

See also: Internet capitalization conventions

 

Internet is a short form of the technical term internetwork,[1] the result of interconnecting computer networks with special gateways or routers. The Internet is also often referred to as the Net.

 

The term the Internet, when referring to the entire global system of IP networks, has been treated as a proper noun and written with an initial capital letter. In the media and popular culture a trend has also developed to regard it as a generic term or common noun and thus write it as "the internet", without capitalization. Some guides specify that the word should be capitalized as a noun but not capitalized as an adjective.

Depiction of the Internet as a cloud in network diagrams

 

The terms Internet and World Wide Web are often used in everyday speech without much distinction. However, the Internet and the World Wide Web are not one and the same. The Internet is a global data communications system. It is a hardware and software infrastructure that provides connectivity between computers. In contrast, the Web is one of the services communicated via the Internet. It is a collection of interconnected documents and other resources, linked by hyperlinks and URLs.[2]

 

In many technical illustrations when the precise location or interrelation of Internet resources is not important, extended networks such as the Internet are often depicted as a cloud.[3] The verbal image has been formalized in the newer concept of cloud computing.

History

Main article: History of the Internet

 

The USSR's launch of Sputnik spurred the United States to create the Advanced Research Projects Agency (ARPA, later DARPA) in February 1958 to regain a technological lead.[4][5] ARPA created the Information Processing Technology Office (IPTO) to further the research of the Semi Automatic Ground Environment (SAGE) program, which had networked country-wide radar systems together for the first time. The IPTO's purpose was to find ways to address the US military's concern about survivability of their communications networks, and as a first step interconnect their computers at the Pentagon, Cheyenne Mountain, and Strategic Air Command headquarters (SAC). J. C. R. Licklider, a promoter of universal networking, was selected to head the IPTO. Licklider moved from the Psycho-Acoustic Laboratory at Harvard University to MIT in 1950, after becoming interested in information technology. At MIT, he served on a committee that established Lincoln Laboratory and worked on the SAGE project. In 1957 he became a Vice President at BBN, where he bought the first production PDP-1 computer and conducted the first public demonstration of time-sharing.

Professor Leonard Kleinrock with the first ARPANET Interface Message Processors at UCLA

 

At the IPTO, Licklider's successor Ivan Sutherland in 1965 got Lawrence Roberts to start a project to make a network, and Roberts based the technology on the work of Paul Baran,[6] who had written an exhaustive study for the United States Air Force that recommended packet switching (opposed to circuit switching) to achieve better network robustness and disaster survivability. Roberts had worked at the MIT Lincoln Laboratory originally established to work on the design of the SAGE system. UCLA professor Leonard Kleinrock had provided the theoretical foundations for packet networks in 1962, and later, in the 1970s, for hierarchical routing, concepts which have been the underpinning of the development towards today's Internet.

 

Sutherland's successor Robert Taylor convinced Roberts to build on his early packet switching successes and come and be the IPTO Chief Scientist. Once there, Roberts prepared a report called Resource Sharing Computer Networks which was approved by Taylor in June 1968 and laid the foundation for the launch of the working ARPANET the following year.

 

After much work, the first two nodes of what would become the ARPANET were interconnected between Kleinrock's Network Measurement Center at the UCLA's School of Engineering and Applied Science and Douglas Engelbart's NLS system at SRI International (SRI) in Menlo Park, California, on 29 October 1969. The third site on the ARPANET was the Culler-Fried Interactive Mathematics center at the University of California at Santa Barbara, and the fourth was the University of Utah Graphics Department. In an early sign of future growth, there were already fifteen sites connected to the young ARPANET by the end of 1971.

 

In an independent development, Donald Davies at the UK National Physical Laboratory developed the concept of packet switching in the early 1960s, first giving a talk on the subject in 1965, after which the teams in the new field from two sides of the Atlantic ocean first became acquainted. It was actually Davies' coinage of the wording packet and packet switching that was adopted as the standard terminology. Davies also built a packet-switched network in the UK, called the Mark I in 1970.[7] Bolt, Beranek & Newman (BBN), the private contractors for ARPANET, set out to create a separate commercial version after establishing "value added carriers" was legalized in the U.S.[8] The network they established was called Telenet and began operation in 1975, installing free public dial-up access in cities throughout the U.S. Telenet was the first packet-switching network open to the general public.[9]

 

Following the demonstration that packet switching worked on the ARPANET, the British Post Office, Telenet, DATAPAC and TRANSPAC collaborated to create the first international packet-switched network service. In the UK, this was referred to as the International Packet Switched Service (IPSS), in 1978. The collection of X.25-based networks grew from Europe and the US to cover Canada, Hong Kong and Australia by 1981. The X.25 packet switching standard was developed in the CCITT (now called ITU-T) around 1976. X.25 was independent of the TCP/IP protocols that arose from the experimental work of DARPA on the ARPANET, Packet Radio Net, and Packet Satellite Net during the same time period.

 

The early ARPANET ran on the Network Control Program (NCP), implementing the host-to-host connectivity and switching layers of the protocol stack, designed and first implemented in December 1970 by a team called the Network Working Group (NWG) led by Steve Crocker. To respond to the network's rapid growth as more and more locations connected, Vinton Cerf and Robert Kahn developed the first description of the now widely used TCP protocols during 1973 and published a paper on the subject in May 1974. Use of the term "Internet" to describe a single global TCP/IP network originated in December 1974 with the publication of RFC 675, the first full specification of TCP that was written by Vinton Cerf, Yogen Dalal and Carl Sunshine, then at Stanford University. During the next nine years, work proceeded to refine the protocols and to implement them on a wide range of operating systems. The first TCP/IP-based wide-area network was operational by 1 January 1983 when all hosts on the ARPANET were switched over from the older NCP protocols.

T3 NSFNET Backbone, c. 1992

 

In 1985, the United States' National Science Foundation (NSF) commissioned the construction of the NSFNET, a university 56 kilobit/second network backbone using computers called "fuzzballs" by their inventor, David L. Mills. The following year, NSF sponsored the conversion to a higher-speed 1.5 megabit/second network that became operational in 1988. A key decision to use the DARPA TCP/IP protocols was made by Dennis Jennings, then in charge of the Supercomputer program at NSF. The NSFNET backbone was upgraded to 45 Mbps in 1991 and decommissioned in 1995 when it was replaced by new backbone networks operated by commercial Internet Service Providers.

 

The opening of the NSFNET to other networks began in 1988.[10] The US Federal Networking Council approved the interconnection of the NSFNET to the commercial MCI Mail system in that year and the link was made in the summer of 1989. Other commercial electronic mail services were soon connected, including OnTyme, Telemail and Compuserve. In that same year, three commercial Internet service providers (ISPs) began operations: UUNET, PSINet, and CERFNET. Important, separate networks that offered gateways into, then later merged with, the Internet include Usenet and BITNET. Various other commercial and educational networks, such as Telenet (by that time renamed to Sprintnet), Tymnet, Compuserve and JANET were interconnected with the growing Internet in the 1980s as the TCP/IP protocol became increasingly popular. The adaptability of TCP/IP to existing communication networks allowed for rapid growth. The open availability of the specifications and reference code permitted commercial vendors to build interoperable network components, such as routers, making standardized network gear available from many companies. This aided in the rapid growth of the Internet and the proliferation of local-area networking. It seeded the widespread implementation and rigorous standardization of TCP/IP on UNIX and virtually every other common operating system.

This NeXT Computer was used by Sir Tim Berners-Lee at CERN and became the world's first Web server.

 

Although the basic applications and guidelines that make the Internet possible had existed for almost two decades, the network did not gain a public face until the 1990s. On 6 August 1991, CERN, a pan-European organization for particle research, publicized the new World Wide Web project. The Web was invented by British scientist Tim Berners-Lee in 1989. An early popular web browser was ViolaWWW, patterned after HyperCard and built using the X Window System. It was eventually replaced in popularity by the Mosaic web browser. In 1993, the National Center for Supercomputing Applications at the University of Illinois released version 1.0 of Mosaic, and by late 1994 there was growing public interest in the previously academic, technical Internet. By 1996 usage of the word Internet had become commonplace, and consequently, so had its use as a synecdoche in reference to the World Wide Web.

 

Meanwhile, over the course of the decade, the Internet successfully accommodated the majority of previously existing public computer networks (although some networks, such as FidoNet, have remained separate). During the late 1990s, it was estimated that traffic on the public Internet grew by 100 percent per year, while the mean annual growth in the number of Internet users was thought to be between 20% and 50%.[11] This growth is often attributed to the lack of central administration, which allows organic growth of the network, as well as the non-proprietary open nature of the Internet protocols, which encourages vendor interoperability and prevents any one company from exerting too much control over the network.[12] The estimated population of Internet users is 1.97 billion as of 30 June 2010.[13]

 

From 2009 onward, the Internet is expected to grow significantly in Brazil, Russia, India, China, and Indonesia (BRICI countries). These countries have large populations and moderate to high economic growth, but still low Internet penetration rates. In 2009, the BRICI countries represented about 45 percent of the world's population and had approximately 610 million Internet users, but by 2015, Internet users in BRICI countries will double to 1.2 billion, and will triple in Indonesia.[14][15]

Technology

Protocols

Main article: Internet Protocol Suite

 

The complex communications infrastructure of the Internet consists of its hardware components and a system of software layers that control various aspects of the architecture. While the hardware can often be used to support other software systems, it is the design and the rigorous standardization process of the software architecture that characterizes the Internet and provides the foundation for its scalability and success. The responsibility for the architectural design of the Internet software systems has been delegated to the Internet Engineering Task Force (IETF).[16] The IETF conducts standard-setting work groups, open to any individual, about the various aspects of Internet architecture. Resulting discussions and final standards are published in a series of publications, each called a Request for Comments (RFC), freely available on the IETF web site. The principal methods of networking that enable the Internet are contained in specially designated RFCs that constitute the Internet Standards. Other less rigorous documents are simply informative, experimental, or historical, or document the best current practices (BCP) when implementing Internet technologies.

 

The Internet Standards describe a framework known as the Internet Protocol Suite. This is a model architecture that divides methods into a layered system of protocols (RFC 1122, RFC 1123). The layers correspond to the environment or scope in which their services operate. At the top is the Application Layer, the space for the application-specific networking methods used in software applications, e.g., a web browser program. Below this top layer, the Transport Layer connects applications on different hosts via the network (e.g., client–server model) with appropriate data exchange methods. Underlying these layers are the core networking technologies, consisting of two layers. The Internet Layer enables computers to identify and locate each other via Internet Protocol (IP) addresses, and allows them to connect to one-another via intermediate (transit) networks. Lastly, at the bottom of the architecture, is a software layer, the Link Layer, that provides connectivity between hosts on the same local network link, such as a local area network (LAN) or a dial-up connection. The model, also known as TCP/IP, is designed to be independent of the underlying hardware which the model therefore does not concern itself with in any detail. Other models have been developed, such as the Open Systems Interconnection (OSI) model, but they are not compatible in the details of description, nor implementation, but many similarities exist and the TCP/IP protocols are usually included in the discussion of OSI networking.

 

The most prominent component of the Internet model is the Internet Protocol (IP) which provides addressing systems (IP addresses) for computers on the Internet. IP enables internetworking and essentially establishes the Internet itself. IP Version 4 (IPv4) is the initial version used on the first generation of the today's Internet and is still in dominant use. It was designed to address up to ~4.3 billion (109) Internet hosts. However, the explosive growth of the Internet has led to IPv4 address exhaustion which is estimated to enter its final stage in approximately 2011.[17] A new protocol version, IPv6, was developed in the mid 1990s which provides vastly larger addressing capabilities and more efficient routing of Internet traffic. IPv6 is currently in commercial deployment phase around the world and Internet address registries (RIRs) have begun to urge all resource managers to plan rapid adoption and conversion.[18]

 

IPv6 is not interoperable with IPv4. It essentially establishes a "parallel" version of the Internet not directly accessible with IPv4 software. This means software upgrades or translator facilities are necessary for every networking device that needs to communicate on the IPv6 Internet. Most modern computer operating systems are already converted to operate with both versions of the Internet Protocol. Network infrastructures, however, are still lagging in this development. Aside from the complex physical connections that make up its infrastructure, the Internet is facilitated by bi- or multi-lateral commercial contracts (e.g., peering agreements), and by technical specifications or protocols that describe how to exchange data over the network. Indeed, the Internet is defined by its interconnections and routing policies.

Structure

 

The Internet structure and its usage characteristics have been studied extensively. It has been determined that both the Internet IP routing structure and hypertext links of the World Wide Web are examples of scale-free networks. Similar to the way the commercial Internet providers connect via Internet exchange points, research networks tend to interconnect into large subnetworks such as GEANT, GLORIAD, Internet2 (successor of the Abilene Network), and the UK's national research and education network JANET. These in turn are built around smaller networks (see also the list of academic computer network organizations).

 

Many computer scientists describe the Internet as a "prime example of a large-scale, highly engineered, yet highly complex system".[19] The Internet is extremely heterogeneous; for instance, data transfer rates and physical characteristics of connections vary widely. The Internet exhibits "emergent phenomena" that depend on its large-scale organization. For example, data transfer rates exhibit temporal self-similarity. The principles of the routing and addressing methods for traffic in the Internet reach back to their origins the 1960s when the eventual scale and popularity of the network could not be anticipated. Thus, the possibility of developing alternative structures is investigated.[20]

Governance

Main article: Internet governance

ICANN headquarters in Marina Del Rey, California, United States

 

The Internet is a globally distributed network comprising many voluntarily interconnected autonomous networks. It operates without a central governing body. However, to maintain interoperability, all technical and policy aspects of the underlying core infrastructure and the principal name spaces are administered by the Internet Corporation for Assigned Names and Numbers (ICANN), headquartered in Marina del Rey, California. ICANN is the authority that coordinates the assignment of unique identifiers for use on the Internet, including domain names, Internet Protocol (IP) addresses, application port numbers in the transport protocols, and many other parameters. Globally unified name spaces, in which names and numbers are uniquely assigned, are essential for the global reach of the Internet. ICANN is governed by an international board of directors drawn from across the Internet technical, business, academic, and other non-commercial communities. The government of the United States continues to have the primary role in approving changes to the DNS root zone that lies at the heart of the domain name system.[citation needed] ICANN's role in coordinating the assignment of unique identifiers distinguishes it as perhaps the only central coordinating body on the global Internet. On 16 November 2005, the World Summit on the Information Society, held in Tunis, established the Internet Governance Forum (IGF) to discuss Internet-related issues.

Modern uses

 

The Internet is allowing greater flexibility in working hours and location, especially with the spread of unmetered high-speed connections and web applications.

 

The Internet can now be accessed almost anywhere by numerous means, especially through mobile Internet devices. Mobile phones, datacards, handheld game consoles and cellular routers allow users to connect to the Internet from anywhere there is a wireless network supporting that device's technology. Within the limitations imposed by small screens and other limited facilities of such pocket-sized devices, services of the Internet, including email and the web, may be available. Service providers may restrict the services offered and wireless data transmission charges may be significantly higher than other access methods.

 

Educational material at all levels from pre-school to post-doctoral is available from websites. Examples range from CBeebies, through school and high-school revision guides, virtual universities, to access to top-end scholarly literature through the likes of Google Scholar. In distance education, help with homework and other assignments, self-guided learning, whiling away spare time, or just looking up more detail on an interesting fact, it has never been easier for people to access educational information at any level from anywhere. The Internet in general and the World Wide Web in particular are important enablers of both formal and informal education.

 

The low cost and nearly instantaneous sharing of ideas, knowledge, and skills has made collaborative work dramatically easier, with the help of collaborative software. Not only can a group cheaply communicate and share ideas, but the wide reach of the Internet allows such groups to easily form in the first place. An example of this is the free software movement, which has produced, among other programs, Linux, Mozilla Firefox, and OpenOffice.org. Internet "chat", whether in the form of IRC chat rooms or channels, or via instant messaging systems, allow colleagues to stay in touch in a very convenient way when working at their computers during the day. Messages can be exchanged even more quickly and conveniently than via email. Extensions to these systems may allow files to be exchanged, "whiteboard" drawings to be shared or voice and video contact between team members.

 

Version control systems allow collaborating teams to work on shared sets of documents without either accidentally overwriting each other's work or having members wait until they get "sent" documents to be able to make their contributions. Business and project teams can share calendars as well as documents and other information. Such collaboration occurs in a wide variety of areas including scientific research, software development, conference planning, political activism and creative writing. Social and political collaboration is also becoming more widespread as both Internet access and computer literacy grow. From the flash mob 'events' of the early 2000s to the use of social networking in the 2009 Iranian election protests, the Internet allows people to work together more effectively and in many more ways than was possible without it[neutrality is disputed].

 

The Internet allows computer users to remotely access other computers and information stores easily, wherever they may be across the world. They may do this with or without the use of security, authentication and encryption technologies, depending on the requirements. This is encouraging new ways of working from home, collaboration and information sharing in many industries. An accountant sitting at home can audit the books of a company based in another country, on a server situated in a third country that is remotely maintained by IT specialists in a fourth. These accounts could have been created by home-working bookkeepers, in other remote locations, based on information emailed to them from offices all over the world. Some of these things were possible before the widespread use of the Internet, but the cost of private leased lines would have made many of them infeasible in practice. An office worker away from their desk, perhaps on the other side of the world on a business trip or a holiday, can open a remote desktop session into his normal office PC using a secure Virtual Private Network (VPN) connection via the Internet. This gives the worker complete access to all of his or her normal files and data, including email and other applications, while away from the office. This concept has been referred to among system administrators as the Virtual Private Nightmare,[21] because it extends the secure perimeter of a corporate network into its employees' homes.

Services

Information

 

Many people use the terms Internet and World Wide Web, or just the Web, interchangeably, but the two terms are not synonymous. The World Wide Web is a global set of documents, images and other resources, logically interrelated by hyperlinks and referenced with Uniform Resource Identifiers (URIs). URIs allow providers to symbolically identify services and clients to locate and address web servers, file servers, and other databases that store documents and provide resources and access them using the Hypertext Transfer Protocol (HTTP), the primary carrier protocol of the Web. HTTP is only one of the hundreds of communication protocols used on the Internet. Web services may also use HTTP to allow software systems to communicate in order to share and exchange business logic and data.

 

 

Judy Rush2011-05-12 21:59:31

[Thiago Araujo]

"Espiritos" é espetacular....

 

Renato, arrisco a dizer que o top 01 hoje é Homem-Aranha....

[Thiago Araujo]

"Triangulo do medo" revi duas vezes...a cada revisão acho cada vez mais genial...

[Judy Rush]

 

E o vilão  mais conhecido:

 

Eu acho que em ordem são esses:

 

1) Coringa

2) Mulher gato

3) Lex

4) Pinguim

5) Charada

 

 

[Thiago Araujo]

E o vilão  mais conhecido:

Eu acho que em ordem são esses:

1) Coringa
2) Mulher gato
3) Lex
4) Pinguim
5) Charada

 

 

Concordo com o Coringa...não faço ideia com os demais do ranking....

[flower]

Hora do almoço' date=' me vou, senão perco o sorteio do bife [/quote'] Como é isto? rifa???

[flower]

E o vilão  mais conhecido:

Eu acho que em ordem são esses:

1) Coringa
2) Mulher gato
3) Lex
4) Pinguim
5) Charada

1) Collor

2) Arruda

3) Beira Mar

4) Wellington Menezes

[Renato]

Acho que a Mulher Gato não é muito vista como vilã...

[Renato]

 

Renato' date=' arrisco a dizer que o top 01 hoje é Homem-Aranha....

[/quote']

 

filme ou popularidade do personagem?

 

Se for popularidade você está completamente equivocado.

[Tensor]

eu acho que é assim:

 

 

 

01. Coringa

 

02. Mulher Gato

 

03. Magneto

 

04. Venon

 

05. Duende Verde

[Tensor]

Ah, o Renato, antes tu disse que a Mulher Maravilha seria a quinta, abaixo do Super, Batman, Homem Aranhe e Hulk. Na hora eu não lembrei de um, mas o Capitão América é mais conhecido que ela. Não tanto aqui, mas em outros países, e principalmente nos Estados Unidos, ele é um dos heróis mais idolatrados.

[Renato]

Ah' date=' o Renato, antes tu disse que a Mulher Maravilha seria a quinta, abaixo do Super, Batman, Homem Aranhe e Hulk. Na hora eu não lembrei de um, mas o Capitão América é mais conhecido que ela. Não tanto aqui, mas em outros países, e principalmente nos Estados Unidos, ele é um dos heróis mais idolatrados.[/quote']

 

acho que só nos EUA mesmo...

 

O Robocop ficaria na frente dele, por exemplo

[Renato]

eu acho que é assim:

01. Coringa
02. Mulher Gato
03. Magneto
04. Venon
05. Duende Verde

 

 

Tênsor vive em um mundo a parte