发现的两个巨长的域名
http://www.mamashuojiusuannizhucedeyumingzaichanggoogledounengsousuochulai.cn/
妈妈说。。。

http://www.bandengkuanbiandanchangbandengyaobangzaibiandanshangbiandanpianbuyaobandengbangzaibiandanshang.com

板凳宽扁担长。。。

Popularity: 31%

Best Windows Error Ever! (ZZ)

Submitted by Kelso on Thu, 2006-09-14 14:45.I was doing Vista thing to play around with since in my job,
I’m going to have to start supporting this beast. Well, my first plan was to do a simple “upgrade”, which later
learned wasnt so simple. Its not that the process was difficult, the problem is that it breaks almost everything. I couldnt even goto the recycle bin, explorer would crash on about anything i tried to do. When this message popped up, i nearly shat myself.. Ironic?

Popularity: 48%

新浪科技讯 9月12日最新消息，IBM公司今天证实，曾经在网上闹得沸沸扬扬的“秘书门”事件的女主角瑞贝卡已被IBM聘用。
“秘书门”事件起因是，今年4月7日晚，原EMC中国区总裁陆纯初回办公室取东西，到门口才发现自己没带钥匙。此时他的私人秘书瑞贝卡已经下班。陆纯初试图联系后者未果。数小时后，陆纯初还是难抑怒火，于是在凌晨1时13分通过内部电子邮件系统给瑞贝卡发了一封措辞严厉且语气生硬的“谴责信”。陆纯初在发送这封邮件的时候，同时传给了公司几位高管。结果瑞贝卡以一封咄咄逼人的邮件进行回复，并让EMC中国公司的所有人都收到了这封邮件。
瑞贝卡的邮件在各大论坛转帖引发了广泛争议，她也因此被网友称为“史上最强女秘书”。根据新浪科技的一份调查，在7千多名参加调查的网友中，约72%对女秘书的做法表示支持。在“秘书门”事件发生不久后，瑞贝卡及陆纯初先后离职。（木木）

Popularity: 52%

The original PageRank algorithm was described by Lawrence Page
and Sergey Brin in several publications. It is given by

PR(A) = (1-d) + d (PR(T1)/C(T1) + … + PR(Tn)/C(Tn))

where

	PR(A) is the PageRank of page A,
	PR(Ti) is the PageRank of pages Ti which link to page A,
	C(Ti) is the number of outbound links on page Ti and
	d is a damping factor which can be set between 0 and 1.

So, first of all, we see that PageRank does not rank web sites
as a whole, but is determined for each page individually. Further,
the PageRank of page A is recursively defined by the PageRanks of
those pages which link to page A.

The PageRank of pages Ti which link to page A does not influence
the PageRank of page A uniformly. Within the PageRank algorithm,
the PageRank of a page T is always weighted by the number of
outbound links C(T) on page T. This means that the more outbound
links a page T has, the less will page A benefit from a link to it
on page T.

The weighted PageRank of pages Ti is then added up. The outcome
of this is that an additional inbound link for page A will always
increase page A’s PageRank.

Finally, the sum of the weighted PageRanks of all pages Ti is
multiplied with a damping factor d which can be set between 0 and
1. Thereby, the extend of PageRank benefit for a page by another
page linking to it is reduced.

The Random Surfer Model

In their publications, Lawrence Page and Sergey Brin give a very
simple intuitive justification for the PageRank algorithm. They
consider PageRank as a model of user behaviour, where a surfer
clicks on links at random with no regard towards content.

The random surfer visits a web page with a certain probability
which derives from the page’s PageRank. The probability that
the random surfer clicks on one link is solely given by the number
of links on that page. This is why one page’s PageRank is not
completely passed on to a page it links to, but is devided by the
number of links on the page.

So, the probability for the random surfer reaching one page is
the sum of probabilities for the random surfer following links to
this page. Now, this probability is reduced by the damping factor
d. The justification within the Random Surfer Model, therefore, is
that the surfer does not click on an infinite number of links, but
gets bored sometimes and jumps to another page at random.

The probability for the random surfer not stopping to click on
links is given by the damping factor d, which is, depending on the
degree of probability therefore, set between 0 and 1. The higher d
is, the more likely will the random surfer keep clicking links.
Since the surfer jumps to another page at random after he stopped
clicking links, the probability therefore is implemented as a
constant (1-d) into the algorithm. Regardless of inbound links, the
probability for the random surfer jumping to a page is always
(1-d), so a page has always a minimum PageRank.

A Different Notation of the PageRank Algorithm

Lawrence Page and Sergey Brin have published two different
versions of their PageRank algorithm in different papers. In the
second version of the algorithm, the PageRank of page A is given
as

PR(A) = (1-d) / N + d (PR(T1)/C(T1) + … + PR(Tn)/C(Tn))

where N is the total number of all pages on the web. The second
version of the algorithm, indeed, does not differ fundamentally
from the first one. Regarding the Random Surfer Model, the second
version’s PageRank of a page is the actual probability for a
surfer reaching that page after clicking on many links. The
PageRanks then form a probability distribution over web pages, so
the sum of all pages’ PageRanks will be one.

Contrary, in the first version of the algorithm the probability
for the random surfer reaching a page is weighted by the total
number of web pages. So, in this version PageRank is an expected
value for the random surfer visiting a page, when he restarts this
procedure as often as the web has pages. If the web had 100 pages
and a page had a PageRank value of 2, the random surfer would reach
that page in an average twice if he restarts 100 times.

As mentioned above, the two versions of the algorithm do not
differ fundamentally from each other. A PageRank which has been
calculated by using the second version of the algorithm has to be
multiplied by the total number of web pages to get the according
PageRank that would have been caculated by using the first version.
Even Page and Brin mixed up the two algorithm versions in their
most popular paper “The Anatomy of a Large-Scale Hypertextual
Web Search Engine”, where they claim the first version of the
algorithm to form a probability distribution over web pages with
the sum of all pages’ PageRanks being one.

In the following, we will use the first version of the
algorithm. The reason is that PageRank calculations by means of
this algorithm are easier to compute, because we can disregard the
total number of web pages.

The Characteristics of PageRank

The characteristics of PageRank shall be illustrated by a small
example.

We regard a small web consisting of three pages A, B and C,
whereby page A links to the pages B and C, page B links to page C
and page C links to page A. According to Page and Brin, the damping
factor d is usually set to 0.85, but to keep the calculation simple
we set it to 0.5. The exact value of the damping factor d
admittedly has effects on PageRank, but it does not influence the
fundamental principles of PageRank. So, we get the following
equations for the PageRank calculation:

PR(A) = 0.5 + 0.5 PR(C)
PR(B) = 0.5 + 0.5 (PR(A) / 2)
PR(C) = 0.5 + 0.5 (PR(A) / 2 + PR(B))

These equations can easily be solved. We get the following
PageRank values for the single pages:

PR(A) = 14/13 = 1.07692308
PR(B) = 10/13 = 0.76923077
PR(C) = 15/13 = 1.15384615

It is obvious that the sum of all pages’ PageRanks is 3 and
thus equals the total number of web pages. As shown above this is
not a specific result for our simple example.

For our simple three-page example it is easy to solve the
according equation system to determine PageRank values. In
practice, the web consists of billions of documents and it is not
possible to find a solution by inspection.

The Iterative Computation of PageRank

Because of the size of the actual web, the Google search engine
uses an approximative, iterative computation of PageRank values.
This means that each page is assigned an initial starting value and
the PageRanks of all pages are then calculated in several
computation circles based on the equations determined by the
PageRank algorithm. The iterative calculation shall again be
illustrated by our three-page example, whereby each page is
assigned a starting PageRank value of 1.

We see that we get a good approximation of the real PageRank
values after only a few iterations. According to publications of
Lawrence Page and Sergey Brin, about 100 iterations are necessary
to get a good approximation of the PageRank values of the whole
web.

Also, by means of the iterative calculation, the sum of all
pages’ PageRanks still converges to the total number of web
pages. So the average PageRank of a web page is 1. The minimum
PageRank of a page is given by (1-d). Therefore, there is a maximum
PageRank for a page which is given by dN+(1-d), where N is total
number of web pages. This maximum can theoretically occur, if all
web pages solely link to one page, and this page also solely links
to itself.

Popularity: 29%