Search engine

"Search engine" redirects here. For other uses, see Search engine (disambiguation).

A web search engine is designed to search for information on the World Wide Web. The search results are generally presented in a list of results often referred to as search engine results pages (SERPs). The information may consist of web pages, images, information and other types of files. Some search engines also mine data available in databases or open directories. Unlike web directories, which are maintained only by human editors, search engines also maintain real-time information by running an algorithm on a web crawler.

History

Timeline (full list)
Year	Engine	Current status
1993	W3Catalog	Inactive
	Aliweb	Inactive
1994	WebCrawler	Active, Aggregator
	Go.com	Active, Yahoo Search
	Lycos	Active
1995	AltaVista	Inactive (URL redirected to Yahoo!)
	Daum	Active
	Magellan	Inactive
	Excite	Active
	SAPO	Active
	Yahoo!	Active, Launched as a directory
1996	Dogpile	Active, Aggregator
	Inktomi	Acquired by Yahoo!
	HotBot	Active (lycos.com)
	Ask Jeeves	Active (ask.com, Jeeves went away)
1997	Northern Light	Inactive
	Yandex	Active
1998	Google	Active
	MSN Search	Active as Bing
1999	AlltheWeb	Inactive (URL redirected to Yahoo!)
	GenieKnows	Active, rebranded Yellowee.com
	Naver	Active
	Teoma	Active
	Vivisimo	Inactive
2000	Baidu	Active
	Exalead	Acquired by Dassault Systèmes
2002	Inktomi	Acquired by Yahoo!
2003	Info.com	Active
2004	Yahoo! Search	Active, Launched own web search (see Yahoo! Directory, 1995)
	A9.com	Inactive
	Sogou	Active
2005	AOL Search	Active
	Ask.com	Active
	GoodSearch	Active
	SearchMe	Closed
2006	wikiseek	Inactive
	Quaero	Active
	Ask.com	Active
	Live Search	Active as Bing, Launched as rebranded MSN Search
	ChaCha	Active
	Guruji.com	Active
2007	wikiseek	Inactive
	Sproose	Inactive
	Wikia Search	Inactive
	Blackle.com	Active
2008	Powerset	Inactive (redirects to Bing)
	Picollator	Inactive
	Viewzi	Inactive
	Boogami	Inactive
	LeapFish	Inactive
	Forestle	Inactive (redirects to Ecosia)
	VADLO	Active
	DuckDuckGo	Active, Aggregator
2009	Bing	Active, Launched as rebranded Live Search
	Yebol	Active
	Mugurdy	Inactive due to a lack of funding
	Goby	Active
2010	Blekko	Active
	Cuil	Inactive
	Yandex	Active, Launched global (English) search
	Yummly	Active
2011	Interred	Active
	Yandex	Active, Launched turkey search
2012	Volunia	Active , only Power User

During the early development of the web, there was a list of webservers edited by Tim Berners-Lee and hosted on the CERN webserver. One historical snapshot from 1992 remains.^[1] As more webservers went online the central list could not keep up. On the NCSA site new servers were announced under the title "What's New!"^[2]

The very first tool used for searching on the Internet was Archie.^[3] The name stands for "archive" without the "v". It was created in 1990 by Alan Emtage, Bill Heelan and J. Peter Deutsch, computer science students at McGill University in Montreal. The program downloaded the directory listings of all the files located on public anonymous FTP (File Transfer Protocol) sites, creating a searchable database of file names; however, Archie did not index the contents of these sites since the amount of data was so limited it could be readily searched manually.

The rise of Gopher (created in 1991 by Mark McCahill at the University of Minnesota) led to two new search programs, Veronica and Jughead. Like Archie, they searched the file names and titles stored in Gopher index systems. Veronica (Very Easy Rodent-Oriented Net-wide Index to Computerized Archives) provided a keyword search of most Gopher menu titles in the entire Gopher listings. Jughead (Jonzy's Universal Gopher Hierarchy Excavation And Display) was a tool for obtaining menu information from specific Gopher servers. While the name of the search engine "Archie" was not a reference to the Archie comic book series, "Veronica" and "Jughead" are characters in the series, thus referencing their predecessor.

In the summer of 1993, no search engine existed yet for the web, though numerous specialized catalogues were maintained by hand. Oscar Nierstrasz at the University of Geneva wrote a series of Perl scripts that would periodically mirror these pages and rewrite them into a standard format which formed the basis for W3Catalog, the web's first primitive search engine, released on September 2, 1993.^[4]

In June 1993, Matthew Gray, then at MIT, produced what was probably the first web robot, the Perl-based World Wide Web Wanderer, and used it to generate an index called 'Wandex'. The purpose of the Wanderer was to measure the size of the World Wide Web, which it did until late 1995. The web's second search engine Aliweb appeared in November 1993. Aliweb did not use a web robot, but instead depended on being notified by website administrators of the existence at each site of an index file in a particular format.

JumpStation (released in December 1993^[5]) used a web robot to find web pages and to build its index, and used a web form as the interface to its query program. It was thus the first WWW resource-discovery tool to combine the three essential features of a web search engine (crawling, indexing, and searching) as described below. Because of the limited resources available on the platform on which it ran, its indexing and hence searching were limited to the titles and headings found in the web pages the crawler encountered.

One of the first "full text" crawler-based search engines was WebCrawler, which came out in 1994. Unlike its predecessors, it let users search for any word in any webpage, which has become the standard for all major search engines since. It was also the first one to be widely known by the public. Also in 1994, Lycos (which started at Carnegie Mellon University) was launched and became a major commercial endeavor.

Soon after, many search engines appeared and vied for popularity. These included Magellan, Excite, Infoseek, Inktomi, Northern Light, and AltaVista. Yahoo! was among the most popular ways for people to find web pages of interest, but its search function operated on its web directory, rather than full-text copies of web pages. Information seekers could also browse the directory instead of doing a keyword-based search.

In 1996, Netscape was looking to give a single search engine an exclusive deal to be the featured search engine on Netscape's web browser. There was so much interest that instead a deal was struck with Netscape by five of the major search engines, where for $5 million per year each search engine would be in rotation on the Netscape search engine page. The five engines were Yahoo!, Magellan, Lycos, Infoseek, and Excite.^[6][7]

Search engines were also known as some of the brightest stars in the Internet investing frenzy that occurred in the late 1990s.^[8] Several companies entered the market spectacularly, receiving record gains during their initial public offerings. Some have taken down their public search engine, and are marketing enterprise-only editions, such as Northern Light. Many search engine companies were caught up in the dot-com bubble, a speculation-driven market boom that peaked in 1999 and ended in 2001.

Around 2000, Google's search engine rose to prominence.^{[citation needed]} The company achieved better results for many searches with an innovation called PageRank. This iterative algorithm ranks web pages based on the number and PageRank of other web sites and pages that link there, on the premise that good or desirable pages are linked to more than others. Google also maintained a minimalist interface to its search engine. In contrast, many of its competitors embedded a search engine in a web portal.

By 2000, Yahoo! was providing search services based on Inktomi's search engine. Yahoo! acquired Inktomi in 2002, and Overture (which owned AlltheWeb and AltaVista) in 2003. Yahoo! switched to Google's search engine until 2004, when it launched its own search engine based on the combined technologies of its acquisitions.

Microsoft first launched MSN Search in the fall of 1998 using search results from Inktomi. In early 1999 the site began to display listings from Looksmart blended with results from Inktomi except for a short time in 1999 when results from AltaVista were used instead. In 2004, Microsoft began a transition to its own search technology, powered by its own web crawler (called msnbot).

Microsoft's rebranded search engine, Bing, was launched on June 1, 2009. On July 29, 2009, Yahoo! and Microsoft finalized a deal in which Yahoo! Search would be powered by Microsoft Bing technology.

How web search engines work

A search engine operates in the following order:

1. Web crawling
2. Indexing
3. Searching

Web search engines work by storing information about many web pages, which they retrieve from the HTML itself. These pages are retrieved by a Web crawler (sometimes also known as a spider) — an automated Web browser which follows every link on the site. Exclusions can be made by the use of robots.txt. The contents of each page are then analyzed to determine how it should be indexed (for example, words can be extracted from the titles,page content, headings, or special fields called meta tags). Data about web pages are stored in an index database for use in later queries. A query can be a single word. The purpose of an index is to allow information to be found as quickly as possible. Some search engines, such as Google, store all or part of the source page (referred to as a cache) as well as information about the web pages, whereas others, such as AltaVista, store every word of every page they find. This cached page always holds the actual search text since it is the one that was actually indexed, so it can be very useful when the content of the current page has been updated and the search terms are no longer in it. This problem might be considered to be a mild form of linkrot, and Google's handling of it increases usability by satisfying user expectations that the search terms will be on the returned webpage. This satisfies the principle of least astonishment since the user normally expects the search terms to be on the returned pages. Increased search relevance makes these cached pages very useful, even beyond the fact that they may contain data that may no longer be available elsewhere.

High-level architecture of a standard Web crawler

When a user enters a query into a search engine (typically by using keywords), the engine examines its index and provides a listing of best-matching web pages according to its criteria, usually with a short summary containing the document's title and sometimes parts of the text. The index is built from the information stored with the data and the method by which the information is indexed. Unfortunately, there are currently no known public search engines that allow documents to be searched by date. Most search engines support the use of the boolean operators AND, OR and NOT to further specify the search query. Boolean operators are for literal searches that allow the user to refine and extend the terms of the search. The engine looks for the words or phrases exactly as entered. Some search engines provide an advanced feature called proximity search which allows users to define the distance between keywords. There is also concept-based searching where the research involves using statistical analysis on pages containing the words or phrases you search for. As well, natural language queries allow the user to type a question in the same form one would ask it to a human. A site like this would be ask.com.

The usefulness of a search engine depends on the relevance of the result set it gives back. While there may be millions of web pages that include a particular word or phrase, some pages may be more relevant, popular, or authoritative than others. Most search engines employ methods to rank the results to provide the "best" results first. How a search engine decides which pages are the best matches, and what order the results should be shown in, varies widely from one engine to another. The methods also change over time as Internet usage changes and new techniques evolve. There are two main types of search engine that have evolved: one is a system of predefined and hierarchically ordered keywords that humans have programmed extensively. The other is a system that generates an "inverted index" by analyzing texts it locates. This second form relies much more heavily on the computer itself to do the bulk of the work.

Most Web search engines are commercial ventures supported by advertising revenue and, as a result, some employ the practice of allowing advertisers to pay money to have their listings ranked higher in search results. Those search engines which do not accept money for their search engine results make money by running search related ads alongside the regular search engine results. The search engines make money every time someone clicks on one of these ads.

Market share

Search engine	Market share in May 2011		Market share in December 2010[9]
Google	82.80%	82.8	84.65%	84.65
Yahoo!	6.42%	6.42	6.69%	6.69
Baidu	4.89%	4.89	3.39%	3.39
Bing	3.91%	3.91	3.29%	3.29
Yandex	1.7%	1.7	1.3%	1.3
Ask	0.52%	0.52	0.56%	0.56
AOL	0.3%	0.3	0.42%	0.42

Google's worldwide market share peaked at 86.3% in April 2010.^[10] Yahoo!, Bing and other search engines are more popular in the US than in Europe.

According to Hitwise, market share in the U.S. for October 2011 was Google 65.38%, Bing-powered (Bing and Yahoo!) 28.62%, and the remaining 66 search engines 6%. However, an Experian Hit wise report released in August 2011 gave the "success rate" of searches sampled in July. Over 80 percent of Yahoo! and Bing searches resulted in the users visiting a web site, while Google's rate was just under 68 percent.^[11][12]

In the People's Republic of China, Baidu held a 61.6% market share for web search in July 2009.^[13] In Russian Federation, Yandex holds around 60% of the market share as of April 2012.^[14]

Search engine bias

Although search engines are programmed to rank websites based on their popularity and relevancy, empirical studies indicate various political, economic, and social biases in the information they provide.^[15][16] These biases could be a direct result of economic and commercial processes (e.g., companies that advertise with a search engine can become also more popular in its organic search results), and political processes (e.g., the removal of search results in order to comply with local laws).^[17] Google Bombing is one example of an attempt to manipulate search results for political, social or commercial reasons.

Customized results and filter bubbles

Many search engines such as Google and Bing provide customized results based on the user's activity history. This leads to an effect that has been called a filter bubble. The term describes a phenomenon in which websites use algorithms to selectively guess what information a user would like to see, based on information about the user (such as location, past click behaviour and search history). As a result, websites tend to show only information which agrees with the user's past viewpoint, effectively isolating the user in a bubble that tends to exclude contrary information. Prime examples are Google's personalized search results and Facebook's personalized news stream. According to Eli Pariser, who coined the term, users get less exposure to conflicting viewpoints and are isolated intellectually in their own informational bubble. Pariser related an example in which one user searched Google for "BP" and got investment news about British Petroleum while another searcher got information about the Deepwater Horizon oil spill and that the two search results pages were "strikingly different."^[18][19][20] The bubble effect may have negative implications for civic discourse, according to Pariser, but there are contrasting views suggesting the effect is minimal and addressable.^[21]

Since this problem has been identified, competing search engines have emerged that seek to avoid this problem by not tracking^[22] or "bubbling"^[23] users. One example is DuckDuckGo.

See also

• Comparison of web search engines
• List of search engines
• Answer engine (question answering)
  • Quora
  • True Knowledge
  • Wolfram Alpha
• Collaborative search engine
• Enterprise search
• Google effect
• Internet Search Engines and Libraries
• Metasearch engine
• Natural language search engine
• OpenSearch
• Search directory
• Search engine marketing
• Search engine optimization
• Search oriented architecture
• Selection-based search
• Semantic Web
• Social search
• Spell checker
• Web indexing
• Web search query
• Website Parse Template

References

1. "World-Wide Web Servers". W3.org. Retrieved 2012-05-14.
2. "What's New! February 1994". Home.mcom.com. Retrieved 2012-05-14.
3. "Internet History - Search Engines" (from Search Engine Watch), Universiteit Leiden, Netherlands, September 2001, web: LeidenU-Archie.
4. Oscar Nierstrasz (2 September 1993). "Searchable Catalog of WWW Resources (experimental)".
5. "Archive of NCSA what's new in December 1993 page". Web.archive.org. 2001-06-20. Retrieved 2012-05-14.
6. "Yahoo! And Netscape Ink International Distribution Deal" (PDF)Template:Inconsistent citations
7. "Browser Deals Push Netscape Stock Up 7.8%" (Document). Los Angeles Times. 1 April 1996Template:Inconsistent citations {{cite document}}: Unknown parameter |url= ignored (help)
8. Gandal, Neil (2001). "The dynamics of competition in the internet search engine market". International Journal of Industrial Organization. 19 (7): 1103–1117. doi:10.1016/S0167-7187(01)00065-0. {{cite journal}}: Cite has empty unknown parameter: |coauthors= (help)
9. "Net Marketshare - World". Marketshare.hitslink.com. Retrieved 2012-05-14.
10. "Net Market share - Google". Marketshare.hitslink.com. Retrieved 2012-05-14.
11. "Google Remains Ahead of Bing, But Relevance Drops". August 12, 2011.
12. Experian Hitwise reports Bing-powered share of searches at 29 percent in October 2011, Experian Hitwise, November 16, 2011
13. "Search Engine Market Share July 2009 | Rise to the Top Blog". Risetothetop.techwyse.com. 2009-08-04. Retrieved 2012-05-14.
14. Pavliva, Halia (2012-04-02). "Yandex Internet Search Share Gains, Google Steady: Liveinternet". Bloomberg.com. Retrieved 2012-05-14.
15. Segev, Elad (2010). Google and the Digital Divide: The Biases of Online Knowledge, Oxford: Chandos Publishing.
16. Vaughan, L. & Thelwall, M. (2004). Search engine coverage bias: evidence and possible causes, Information Processing & Management, 40(4), 693-707.
17. Berkman Center for Internet & Society (2002), “Replacement of Google with Alternative Search Systems in China: Documentation and Screen Shots”, Harvard Law School.
18. Parramore, Lynn (10 October 2010). "The Filter Bubble". The Atlantic. Retrieved 2011-04-20. Since Dec. 4, 2009, Google has been personalized for everyone. So when I had two friends this spring Google "BP," one of them got a set of links that was about investment opportunities in BP. The other one got information about the oil spill....
19. Weisberg, Jacob (10 June 2011). "Bubble Trouble: Is Web personalization turning us into solipsistic twits?". Slate. Retrieved 2011-08-15.
20. Gross, Doug (May 19, 2011). "What the Internet is hiding from you". CNN. Retrieved 2011-08-15. I had friends Google BP when the oil spill was happening. These are two women who were quite similar in a lot of ways. One got a lot of results about the environmental consequences of what was happening and the spill. The other one just got investment information and nothing about the spill at all. {{cite news}}: Italic or bold markup not allowed in: |publisher= (help)
21. Zhang, Yuan Cao; Séaghdha, Diarmuid Ó; Quercia, Daniele; Jambor, Tamas (2012). "Auralist: Introducing Serendipity into Music Recommendation" (PDF). ACM WSDM. {{cite journal}}: Unknown parameter |month= ignored (help)
22. "donttrack.us". Retrieved 2012-04-29. {{cite web}}: Cite has empty unknown parameter: |coauthors= (help)
23. "dontbubble.us". Retrieved 2012-04-29. {{cite web}}: Cite has empty unknown parameter: |coauthors= (help)

• GBMW: Reports of 30-day punishment, re: Car maker BMW had its German website bmw.de delisted from Google, such as: Slashdot-BMW (05-Feb-2006).
• INSIZ: Maximum size of webpages indexed by MSN/Google/Yahoo! ("100-kb limit"): Max Page-size (28-Apr-2006).

Further reading

• For a more detailed history of early search engines, see Search Engine Birthdays (from Search Engine Watch), Chris Sherman, September 2003.
• Steve Lawrence; C. Lee Giles (1999). "Accessibility of information on the web". Nature. 400 (6740): 107. doi:10.1038/21987. PMID 10428673. {{cite journal}}: Cite has empty unknown parameter: |quotes= (help); More than one of |pages= and |page= specified (help)
• Bing Liu (2007), Web Data Mining: Exploring Hyperlinks, Contents and Usage Data. Springer, ISBN 3-540-37881-2
• Bar-Ilan, J. (2004). The use of Web search engines in information science research. ARIST, 38, 231-288.
• Levene, Mark (2005). An Introduction to Search Engines and Web Navigation. Pearson.
• Hock, Randolph (2007). The Extreme Searcher's Handbook. ISBN 978-0-910965-76-7
• Javed Mostafa (2005). "Seeking Better Web Searches". Scientific American Magazine. {{cite journal}}: Cite has empty unknown parameter: |quotes= (help); Unknown parameter |month= ignored (help)^{[dead link]}
• Ross, Nancy (2000). "End user searching on the Internet: An analysis of term pair topics submitted to the Excite search engine". Journal of the American Society for Information Science. 51 (10): 949–958. doi:10.1002/1097-4571(2000)51:10<949::AID-ASI70>3.0.CO;2-5. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
• Xie, M.; et al. (1998). "Quality dimensions of Internet search engines". Journal of Information Science. 24 (5): 365–372. doi:10.1177/016555159802400509.
• Information Retrieval: Implementing and Evaluating Search Engines. MIT Press. 2010.

External links

• Search Engines at Curlie