module Math.QuantumAlgebra.OrientedTangle where
import Prelude hiding ( (*>) )
import Math.Algebra.Field.Base
import Math.Algebras.LaurentPoly
import Math.QuantumAlgebra.TensorCategory
import Math.Algebras.VectorSpace
import Math.Algebras.TensorProduct
import Math.Algebras.Structures
data Oriented = Plus | Minus deriving (Eq,Ord,Show)
data HorizDir = ToL | ToR deriving (Eq,Ord,Show)
data OrientedTangle
instance MCategory OrientedTangle where
data Ob OrientedTangle = OT [Oriented] deriving (Eq,Ord,Show)
data Ar OrientedTangle = IdT [Oriented]
| CapT HorizDir
| CupT HorizDir
| XPlus | XMinus
| SeqT [Ar OrientedTangle]
| ParT [Ar OrientedTangle]
deriving (Eq,Ord,Show)
id_ (OT os) = IdT os
source (IdT os) = OT os
source (CapT _) = OT []
source (CupT toR) = OT [Plus,Minus]
source (CupT toL) = OT [Minus,Plus]
source XPlus = OT [Plus,Plus]
source XMinus = OT [Plus,Plus]
source (ParT as) = OT $ concatMap ((\(OT os) -> os) . source) as
source (SeqT as) = source (head as)
target (IdT os) = OT os
target (CapT toR) = OT [Minus,Plus]
target (CapT toL) = OT [Plus,Minus]
target (CupT _) = OT []
target XPlus = OT [Plus,Plus]
target XMinus = OT [Plus,Plus]
target (ParT as) = OT $ concatMap ((\(OT os) -> os) . target) as
target (SeqT as) = target (last as)
a >>> b | target a == source b = SeqT [a,b]
instance Monoidal OrientedTangle where
tunit = OT []
tob (OT as) (OT bs) = OT (as++bs)
tar a b = ParT [a,b]
idV = id
idV' = id
evalV = \(E i, E j) -> if i + j == 0 then return () else zerov
evalV' = \(E i, E j) -> if i + j == 0 then return () else zerov
coevalV m = foldl (<+>) zerov [e i `te` e (i) | i <- [1..m] ]
coevalV' m = foldl (<+>) zerov [e (i) `te` e i | i <- [1..m] ]
lambda m = q' ^ m
c m (E i, E j) = case compare i j of
EQ -> (lambda m * q) *> return (E i, E i)
LT -> lambda m *> return (E j, E i)
GT -> lambda m *> (return (E j, E i) <+> (q q') *> return (E i, E j))
c' m (E i, E j) = case compare i j of
EQ -> (1/(lambda m * q)) *> return (E i, E i)
LT -> (1/lambda m) *> (return (E j, E i) <+> (q'q) *> return (E i, E j))
GT -> (1/lambda m) *> return (E j, E i)
testcc' m v = nf $ v >>= c m >>= c' m
mu m (E i) = (1 / (lambda m * q ^ (2*i1))) *> return (E i)
mu' m (E i) = (lambda m * q ^ (2*i1)) *> return (E i)
capRL m = coevalV m
capLR m = do
(i,j) <- coevalV' m
k <- mu' m j
return (i,k)
cupRL m = evalV
cupLR m (i,j) = do
k <- mu m i
evalV' (k,j)
xplus m = c m
xminus m = c' m
yplus m (p,q) = do
(r,s) <- capRL m
(t,u) <- xplus m (q,r)
cupRL m (p,t)
return (u,s)
yminus m (p,q) = do
(r,s) <- capRL m
(t,u) <- xminus m (q,r)
cupRL m (p,t)
return (u,s)
tplus m (p,q) = do
(r,s) <- capLR m
(t,u) <- xplus m (s,p)
cupLR m (u,q)
return (r,t)
tminus m (p,q) = do
(r,s) <- capLR m
(t,u) <- xminus m (s,p)
cupLR m (u,q)
return (r,t)
zplus m (p,q) = do
(r,u) <- capLR m
(s,t) <- capLR m
(v,w) <- xplus m (t,u)
cupLR m (v,q)
cupLR m (w,p)
return (r,s)
zminus m (p,q) = do
(r,u) <- capLR m
(s,t) <- capLR m
(v,w) <- xminus m (t,u)
cupLR m (v,q)
cupLR m (w,p)
return (r,s)
oloop m = nf $ do
(a,b) <- capLR m
cupRL m (a,b)
otrefoil m = nf $ do
(p,q) <- capLR m
(r,s) <- capLR m
(t,u) <- tminus m (q,r)
(v,w) <- zminus m (p,t)
(x,y) <- xminus m (u,s)
cupRL m (w,x)
cupRL m (v,y)
otrefoil' m = nf $ do
(p,q) <- capRL m
(r,s) <- capRL m
(t,u) <- yminus m (q,r)
(v,w) <- xminus m (p,t)
(x,y) <- zminus m (u,s)
cupLR m (w,x)
cupLR m (v,y)