PageRank

• ${\displaystyle P}$: set of hyperlinked webpages
  
• ${\displaystyle u,v}$: webpages in P
  
• ${\displaystyle N^{-}(u)}$: set of webpages pointing to u
  
• ${\displaystyle N^{+}(v)}$: set of webpages that v points to
  
• the PageRank is: ${\displaystyle R(u)=cE(u)+c\sum _{v\in N^{-}(u)}\frac{R(v)}{|N^{+}(v)|}}$ (1.)
• ${\displaystyle c}$ is chosen such that ${\displaystyle \sum _{u\in P}R(u)=1}$
  
• ${\displaystyle E}$ is a vector over ${\displaystyle P}$ corresponding to a source of rank and is chosen such that ${\displaystyle \sum _{u\in P}E(u)=0.15}$
  
• first term of function (1.) ${\displaystyle cE(u)}$ gives rank value based on initial rank
  
• second term of (1.) ${\displaystyle c\sum _{v\in N^{-}(u)}\frac{R(v)}{|N^{+}(v)|}}$ gives rank value as a function of hyperlinks pointing at ${\displaystyle u}$
  

Beta

Reputation Function
Let ${\displaystyle r_T^X}$ and ${\displaystyle s_T^X}$ represent the collective amount of positive and negative feedback about a Target T provided by an agent (or collection of agents) denoted by X, then the function ${\displaystyle \phi (p|r_T^X,s_T^X)}$ defined by
${\displaystyle \phi (p|r_T^X,s_T^X)=\frac{\mathrm{\Gamma }(r_T^X+s_T^X+2)}{\mathrm{\Gamma }(r_T^X+1)\mathrm{\Gamma }(s_T^X+1)}{p}^{r_T^X}(1-p{)}^{s_T^X},where0\le p\le 1,0\le r_T^X,0\le s_T^X}$
is called T's reputation function by X. The tuple ${\displaystyle (r_T^X,s_T^X)}$ will be called T's reputation parameters by X.
For simplicity ${\displaystyle {\phi }_T^X=\phi (p|r_T^X,s_T^X)}$.

The probability expectation value of the reputation function can be expressed as:
${\displaystyle E(\phi (p|r_T^X,s_T^X))=\frac{r_T^X+1}{r_T^X+s_T^X+2}}$

Reputation Rating
For human users is a more simple representation than the reputation function needed.
Let ${\displaystyle r_T^X}$ and ${\displaystyle s_T^X}$ represent the collective amount of positive and negative feedback about a Target T provided by an agent (or collection of agents) denoted by X, then the function ${\displaystyle Rep(r_T^X,s_T^X)}$ defined by
${\displaystyle Rep(r_T^X,s_T^X)=(E(\phi (p|r_T^X,s_T^X))-0.5)\cdot 2=\frac{r_T^X-s_T^X}{r_T^X+s_T^X+2}}$
is called T's reputation rating by X. For simplicity ${\displaystyle Re{p}_T^X=Rep(r_T^X,s_T^X)}$

Combining Feedback
Let ${\displaystyle \phi (p|r_T^X,s_T^X)}$ an ${\displaystyle \phi (p|r_T^Y,s_T^Y)}$ be two different reputation functions on T resulting from X and Y's feedback respectively. The reputation function ${\displaystyle \phi (p|r_T^{X,Y},s_T^{X,Y})}$ defined by:
1. ${\displaystyle r_T^{X,Y}=r_T^X+r_T^Y}$
2. ${\displaystyle s_T^{X,Y}=s_T^X+s_T^Y}$
is then called T's combined reputation function by X and Y. By using '${\displaystyle \otimes }$' to designate this operator, we get ${\displaystyle \phi (p|r_T^{X,Y},s_T^{X,Y})=\phi (p|r_T^X,s_T^X)\otimes \phi (p|r_T^Y,s_T^Y)}$.

Belief Discounting
This model uses a metric called opinion to describe beliefs about the truth of statements. An opinion is a tuple ${\displaystyle {\omega }_x^A=(b,d,u)}$, where b, d and u represent belief, disbelief and uncertainty. These parameters satisfy ${\displaystyle b+d+u=1}$ where ${\displaystyle b,d,u\in [0,1]}$.
Let X and Y be two agents where ${\displaystyle {\omega }_Y^X=(b_Y^X,d_Y^X,u_Y^X)}$ is X's opinion about Y's advice, and let T be the Target agent where ${\displaystyle {\omega }_T^Y=(b_T^Y,d_T^Y,u_T^Y)}$ is Y's opinion about T expressed in an advice to X. Let ${\displaystyle {\omega }_T^{X:Y}=(b_T^{X:Y},d_T^{X:Y},u_T^{X:Y})}$ be the opinion such that:
1. ${\displaystyle b_T^{X:Y}=b_Y^X{b}_T^Y}$,
2. ${\displaystyle d_T^{X:Y}=b_Y^X{d}_T^Y}$,
3. ${\displaystyle u_T^{X:Y}=d_Y^X+u_Y^X+b_Y^X{u}_T^Y}$,
then ${\displaystyle {\omega }_T^{X:Y}}$ is called the discounting of ${\displaystyle {\omega }_T^Y}$ by ${\displaystyle {\omega }_Y^X}$ expressing X's opinion about T as a result of Y's advice to X. By using '${\displaystyle \otimes }$' to designate this operator, we can write ${\displaystyle {\omega }_T^{X:Y}={\omega }_Y^X\otimes {\omega }_T^Y}$.
The author of BETA provides a mapping between the opinion metric and the beta function defined by:
${\displaystyle b=\frac{r}{r+s+2}}$,
${\displaystyle d=\frac{s}{r+s+2}}$,
${\displaystyle u=\frac{2}{r+s+2}}$,
By using this we obtain the following definition of the discounting operator for reputation functions.

Reputation Discounting
Let X, Y and T be three agents where ${\displaystyle \phi (p|r_Y^X,s_Y^X)}$ is Y's reputation function by X, and ${\displaystyle \phi (p|r_T^Y,s_T^Y)}$ is T's reputation function by Y. Let ${\displaystyle \phi (p|r_T^{X:Y},s_T^{X:Y})}$ be the reputation function such that:
1. ${\displaystyle r_T^{X:Y}=\frac{2r_Y^X{r}_T^Y}{(s_Y^X+2)(r_T^Y+s_T^Y+2)+2r_T^x}}$,
2. ${\displaystyle s_T^{X:Y}=\frac{2r_Y^X{s}_T^Y}{(s_Y^X+2)(r_T^Y+s_T^Y+2)+2r_T^x}}$,
then it is called T's discounted reputation function by X through Y. By using the symbol '${\displaystyle \otimes }$' to designate this operator, we can write ${\displaystyle \phi (p|r_T^{X:Y},s_T^{X:Y})=\phi (p|r_Y^X,s_Y^X)\otimes \phi (p|r_T^Y,s_T^Y)}$. In the short notation this can be written as: ${\displaystyle {\phi }_T^{X:Y}={\phi }_Y^X\otimes {\phi }_T^Y}$.

Forgetting