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'''Solve the following problems''' and submit them in class by October 29, 2009: |
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'''Solve the following problems''' and submit them in class by October 29, 2009: |
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'''Problem 1.''' Let <math>{\mathfrak g}_1</math> and <math>{\mathfrak g}_2</math> be finite dimensional metrized Lie algebras, let <math>{\mathfrak g}_1\oplus{\mathfrak g}_2</math> denote their direct sum with the obvious "orthogonal" bracket and metric, and let <math>m</math> be the canonical isomorphism <math>m:{\mathcal U}({\mathfrak g}_1)\otimes{\mathcal U}({\mathfrak g}_2)\to{\mathcal U}({\mathfrak g}_1\oplus{\mathfrak g}_2)</math>. Prove that |
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{{Equation*|<math>{\mathcal T}_{{\mathfrak g}_1\oplus{\mathfrak g}_2} = m\circ({\mathcal T}_{{\mathfrak g}_1}\otimes{\mathcal T}_{{\mathfrak g}_2})\circ\Box</math>,}} |
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where <math>\Box:{\mathcal A}(\uparrow)\to{\mathcal A}(\uparrow)\otimes{\mathcal A}(\uparrow)</math> is the co-product and <math>{\mathcal T}_{{\mathfrak g}}</math> denotes the <math>{\mathcal U}({\mathfrak g})</math>-valued "tensor map" on <math>{\mathcal A}</math>. Can you relate this with the first problem of [[AKT-09/HW1|HW1]]? |
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# Find a concise algorithm to compute the weight system <math>W_{so}</math> associated with the Lie algebra <math>so(N)</math> in its defining representation. |
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# Find a concise algorithm to compute the weight system <math>W_{so}</math> associated with the Lie algebra <math>so(N)</math> in its defining representation. |
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# Verify that your algorithm indeed satisfies the <math>4T</math> relation. |
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# Verify that your algorithm indeed satisfies the <math>4T</math> relation. |
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'''Problem 2.''' The ''Kauffman polynomial'' <math>F(K)(a,z)</math> (see {{ref|Kauffman}}) of a knot or link <math>K</math> is <math>a^{-w(K)}L(K)</math> where <math>w(L)</math> is the writhe of <math>K</math> and where <math>L(K)</math> is the regular isotopy invariant defined by the skein relations |
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'''Problem 3.''' The ''Kauffman polynomial'' <math>F(K)(a,z)</math> (see {{ref|Kauffman}}) of a knot or link <math>K</math> is <math>a^{-w(K)}L(K)</math> where <math>w(L)</math> is the writhe of <math>K</math> and where <math>L(K)</math> is the regular isotopy invariant defined by the skein relations |
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{{Equation*|<math>L(s_\pm)=a^{\pm 1}L(s))</math>}} |
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{{Equation*|<math>L(s_\pm)=a^{\pm 1}L(s))</math>}} |
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and by the initial condition <math>L(\bigcirc)=1</math>. State and prove the relationship between <math>F</math> and <math>W_{so}</math>. |
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and by the initial condition <math>L(\bigcirc)=1</math>. State and prove the relationship between <math>F</math> and <math>W_{so}</math>. |
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'''Problem 3.''' |
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'''Mandatory but unenforced.''' Find yourself in the class photo and identify yourself as explained in the [[AKT-09/Class Photo|photo page]]. |
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'''Mandatory but unenforced.''' Find yourself in the class photo and identify yourself as explained in the [[AKT-09/Class Photo|photo page]]. |
Revision as of 12:14, 19 October 2009
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Week of...
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Videos, Notes, and Links
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1
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Sep 7
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About This Class 090910-1: 3-colourings, Reidemeister's theorem, invariance, the Kauffman bracket. 090910-2: R23 invariance of the bracket, R1, the writhe, the Jones polynomial, programming the Jones polynomial. Tricolourability
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2
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Sep 14
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090915: More on Jones, some pathologies and more on Reidemeister, our overall agenda. 090917-1: The definition of finite type, weight systems, Jones is a finite type series. 090917-2: The skein relation for Jones; HOMFLY-PT and Conway; the weight system of Jones.
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3
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Sep 21
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090922: FI, 4T, HOMFLY and FI and 4T, statement of the Fundamental Theorem, framed knots. 090924-1: Some dimensions of , is a commutative algebra, . Class Photo 090924-2: is a co-commutative algebra, the relation with products of invariants, is a bi-algebra.
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4
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Sep 28
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Homework Assignment 1 Homework Assignment 1 Solutions 090929: The Milnor-Moore theorem, primitives, the map . 091001-1: Jacobi diagrams, AS, IHX, STU, and the equivalence of all that with 4T. 091001-2: The very basics on Lie algebras.
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5
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Oct 5
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091006: Lie algebraic weight systems, . 091008-1: More on , Lie algebras and the four colour theorem. 091008-2: The "abstract tenssor" approach to weight systems, and PBW, the map .
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6
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Oct 12
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091013: Algebraic properties of vs. algebraic properties of . Thursday's class canceled.
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7
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Oct 19
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091020: Universal finite type invariants, filtered and graded spaces, expansions. Homework Assignment 2 The Stonehenge Story 091022-1: The Stonehenge Story to IHX and STU. 091022-2: The Stonhenge Story: anomalies, framings, relation with physics.
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8
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Oct 26
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091027: Knotted trivalent graphs and their chord diagrams. 091029-1: Zsuzsi Dancso on the Kontsevich Integral (1). 091029-2: Zsuzsi Dancso on the Kontsevich Integral (2).
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9
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Nov 2
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091103: The details of . 091105-1: Three basic problems: genus, unknotting numbers, ribbon knots. 091105-2: The three basic problems and algebraic knot theory.
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10
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Nov 9
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091110: Tangles and planar algebras, shielding and the generators of KTG. Homework Assignment 3 No Thursday class.
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11
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Nov 16
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Local Khovanov Homology 091119-1: Local Khovanov homology, I. 091119-2: Local Khovanov homology, II.
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12
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Nov 23
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091124: Emulation of one structure inside another, deriving the pentagon. 091126-1: Peter Lee on braided monoidal categories, I. 091126-2: Peter Lee on braided monoidal categories, II.
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13
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Nov 30
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091201: The relations in KTG. 091203-1: The Existence of the Exponential Function. 091203-2: The Final Exam, Dror's failures.
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F
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Dec 7
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The Final Exam on Thu Dec 10, 9-11, Bahen 6183.
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Register of Good Deeds / To Do List
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Add your name / see who's in!
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In Preparation
The information below is preliminary and cannot be trusted! (v)
Solve the following problems and submit them in class by October 29, 2009:
Problem 1. Let and be finite dimensional metrized Lie algebras, let denote their direct sum with the obvious "orthogonal" bracket and metric, and let be the canonical isomorphism . Prove that
,
where is the co-product and denotes the -valued "tensor map" on . Can you relate this with the first problem of HW1?
Problem 2.
- Find a concise algorithm to compute the weight system associated with the Lie algebra in its defining representation.
- Verify that your algorithm indeed satisfies the relation.
Problem 3. The Kauffman polynomial (see [Kauffman]) of a knot or link is where is the writhe of and where is the regular isotopy invariant defined by the skein relations
(here is a strand and is the same strand with a kink added) and
Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle L(\backoverslash)+L(\slashoverback) = z\left(L(\smoothing)+L(\hsmoothing)\right)}
and by the initial condition . State and prove the relationship between and .
Mandatory but unenforced. Find yourself in the class photo and identify yourself as explained in the photo page.
[Kauffman] ^ L. H. Kauffman, An invariant of regular isotopy, Trans. Amer. Math. Soc. 312 (1990) 417-471.