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: ${\displaystyle R(u)=cE(u)+c\sum _{v\in N^{-}(u)}{R(v) \over {|N^{+}(v)|}}}$ (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.) ${\displaystyle c\sum _{v\in N^{-}(u)}{R(v) \over {|N^{+}(v)|}}}$ 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 ${\displaystyle \varphi (p|r_{T}^{X},s_{T}^{X})}$ defined by
${\displaystyle \varphi (p|r_{T}^{X},s_{T}^{X})={\frac {\Gamma (r_{T}^{X}+s_{T}^{X}+2)}{\Gamma (r_{T}^{X}+1)\Gamma (s_{T}^{X}+1)}}p^{r_{T}^{X}}(1-p)^{s_{T}^{X}},\qquad where\ 0\leq p\leq 1,\ 0\leq r_{T}^{X},\ 0\leq s_{T}^{X}}$
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 ${\displaystyle \varphi _{T}^{X}=\varphi (p|r_{T}^{X},s_{T}^{X})}$.

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

Reputation Rating
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
${\displaystyle Rep(r_{T}^{X},s_{T}^{X})=(E(\varphi (p|r_{T}^{X},s_{T}^{X}))-0.5)\cdot 2={\frac {r_{T}^{X}-s_{T}^{X}}{r_{T}^{X}+s_{T}^{X}+2}}}$
is called T's reputation rating by X. For simplicity ${\displaystyle Rep_{T}^{X}=Rep(r_{T}^{X},s_{T}^{X})}$

Combining Feedback
Let ${\displaystyle \varphi (p|r_{T}^{X},s_{T}^{X})}$ an ${\displaystyle \varphi (p|r_{T}^{Y},s_{T}^{Y})}$ be two different reputation functions on T resulting from X and Y's feedback respectively. The reputation function ${\displaystyle \varphi (p|r_{T}^{X,Y},s_{T}^{X,Y})}$ 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 '${\displaystyle \oplus }$' to designate this operator, we get ${\displaystyle \varphi (p|r_{T}^{X,Y},s_{T}^{X,Y})=\varphi (p|r_{T}^{X},s_{T}^{X})\oplus \varphi (p|r_{T}^{Y},s_{T}^{Y})}$.

Belief Discounting
Reputation Discounting
Forgetting