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200 lines
6.6 KiB
200 lines
6.6 KiB
5 months ago
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from .cartan_type import CartanType
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from sympy.core.basic import Atom
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class RootSystem(Atom):
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"""Represent the root system of a simple Lie algebra
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Every simple Lie algebra has a unique root system. To find the root
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system, we first consider the Cartan subalgebra of g, which is the maximal
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abelian subalgebra, and consider the adjoint action of g on this
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subalgebra. There is a root system associated with this action. Now, a
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root system over a vector space V is a set of finite vectors Phi (called
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roots), which satisfy:
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1. The roots span V
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2. The only scalar multiples of x in Phi are x and -x
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3. For every x in Phi, the set Phi is closed under reflection
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through the hyperplane perpendicular to x.
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4. If x and y are roots in Phi, then the projection of y onto
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the line through x is a half-integral multiple of x.
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Now, there is a subset of Phi, which we will call Delta, such that:
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1. Delta is a basis of V
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2. Each root x in Phi can be written x = sum k_y y for y in Delta
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The elements of Delta are called the simple roots.
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Therefore, we see that the simple roots span the root space of a given
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simple Lie algebra.
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References
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==========
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.. [1] https://en.wikipedia.org/wiki/Root_system
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.. [2] Lie Algebras and Representation Theory - Humphreys
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"""
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def __new__(cls, cartantype):
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"""Create a new RootSystem object
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This method assigns an attribute called cartan_type to each instance of
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a RootSystem object. When an instance of RootSystem is called, it
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needs an argument, which should be an instance of a simple Lie algebra.
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We then take the CartanType of this argument and set it as the
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cartan_type attribute of the RootSystem instance.
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"""
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obj = Atom.__new__(cls)
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obj.cartan_type = CartanType(cartantype)
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return obj
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def simple_roots(self):
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"""Generate the simple roots of the Lie algebra
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The rank of the Lie algebra determines the number of simple roots that
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it has. This method obtains the rank of the Lie algebra, and then uses
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the simple_root method from the Lie algebra classes to generate all the
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simple roots.
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Examples
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========
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>>> from sympy.liealgebras.root_system import RootSystem
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>>> c = RootSystem("A3")
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>>> roots = c.simple_roots()
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>>> roots
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{1: [1, -1, 0, 0], 2: [0, 1, -1, 0], 3: [0, 0, 1, -1]}
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"""
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n = self.cartan_type.rank()
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roots = {}
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for i in range(1, n+1):
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root = self.cartan_type.simple_root(i)
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roots[i] = root
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return roots
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def all_roots(self):
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"""Generate all the roots of a given root system
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The result is a dictionary where the keys are integer numbers. It
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generates the roots by getting the dictionary of all positive roots
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from the bases classes, and then taking each root, and multiplying it
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by -1 and adding it to the dictionary. In this way all the negative
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roots are generated.
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"""
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alpha = self.cartan_type.positive_roots()
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keys = list(alpha.keys())
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k = max(keys)
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for val in keys:
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k += 1
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root = alpha[val]
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newroot = [-x for x in root]
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alpha[k] = newroot
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return alpha
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def root_space(self):
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"""Return the span of the simple roots
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The root space is the vector space spanned by the simple roots, i.e. it
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is a vector space with a distinguished basis, the simple roots. This
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method returns a string that represents the root space as the span of
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the simple roots, alpha[1],...., alpha[n].
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Examples
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========
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>>> from sympy.liealgebras.root_system import RootSystem
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>>> c = RootSystem("A3")
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>>> c.root_space()
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'alpha[1] + alpha[2] + alpha[3]'
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"""
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n = self.cartan_type.rank()
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rs = " + ".join("alpha["+str(i) +"]" for i in range(1, n+1))
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return rs
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def add_simple_roots(self, root1, root2):
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"""Add two simple roots together
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The function takes as input two integers, root1 and root2. It then
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uses these integers as keys in the dictionary of simple roots, and gets
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the corresponding simple roots, and then adds them together.
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Examples
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========
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>>> from sympy.liealgebras.root_system import RootSystem
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>>> c = RootSystem("A3")
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>>> newroot = c.add_simple_roots(1, 2)
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>>> newroot
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[1, 0, -1, 0]
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"""
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alpha = self.simple_roots()
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if root1 > len(alpha) or root2 > len(alpha):
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raise ValueError("You've used a root that doesn't exist!")
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a1 = alpha[root1]
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a2 = alpha[root2]
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newroot = [_a1 + _a2 for _a1, _a2 in zip(a1, a2)]
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return newroot
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def add_as_roots(self, root1, root2):
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"""Add two roots together if and only if their sum is also a root
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It takes as input two vectors which should be roots. It then computes
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their sum and checks if it is in the list of all possible roots. If it
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is, it returns the sum. Otherwise it returns a string saying that the
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sum is not a root.
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Examples
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========
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>>> from sympy.liealgebras.root_system import RootSystem
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>>> c = RootSystem("A3")
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>>> c.add_as_roots([1, 0, -1, 0], [0, 0, 1, -1])
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[1, 0, 0, -1]
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>>> c.add_as_roots([1, -1, 0, 0], [0, 0, -1, 1])
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'The sum of these two roots is not a root'
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"""
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alpha = self.all_roots()
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newroot = [r1 + r2 for r1, r2 in zip(root1, root2)]
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if newroot in alpha.values():
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return newroot
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else:
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return "The sum of these two roots is not a root"
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def cartan_matrix(self):
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"""Cartan matrix of Lie algebra associated with this root system
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Examples
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========
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>>> from sympy.liealgebras.root_system import RootSystem
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>>> c = RootSystem("A3")
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>>> c.cartan_matrix()
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Matrix([
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[ 2, -1, 0],
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[-1, 2, -1],
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[ 0, -1, 2]])
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"""
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return self.cartan_type.cartan_matrix()
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def dynkin_diagram(self):
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"""Dynkin diagram of the Lie algebra associated with this root system
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Examples
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========
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>>> from sympy.liealgebras.root_system import RootSystem
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>>> c = RootSystem("A3")
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>>> print(c.dynkin_diagram())
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0---0---0
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1 2 3
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"""
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return self.cartan_type.dynkin_diagram()
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