06-1350/Class Notes for Thursday November 16: Difference between revisions

06-1350/Navigation Panel   # Week of... Links 1 Sep 11 About, Tue, Thu 2 Sep 18 Tue, Kurlin(P), Thu 3 Sep 25 Tue, Photo, Thu 4 Oct 2 HW1, Tue, Thu 5 Oct 9 Tue(P), Thu(P) 6 Oct 16 HW2, Tue(P), Thu(P) 7 Oct 23 Tue(P), Thu 8 Oct 30 HW3, Tue, Thu 9 Nov 6 Tue (${\displaystyle \nu }$), Thu 10 Nov 13 Tue, Thu 11 Nov 20 HW4(P), Thu 12 Nov 27 Thu 13 Dec 4 Syzygies in Asymptote, Final Jan 8 Grades Note. (P) means "contains a problem that Dror cares about". Add your name / see who's in! On to 07-1352

Today's Agenda

Formulas are a Chore (Bore?)

• Sweeping clean a tree and ${\displaystyle {\mathcal {A}}(\Gamma )\equiv {\mathcal {A}}(\uparrow _{b_{1}(\Gamma )})}$.

• ${\displaystyle {\mathcal {A}}(\uparrow _{n})}$ is a VS-algebra (see more at VS, TS and TG Algebras).

• In the coordinates above, write the ${\displaystyle TR\Phi B}$ relations in various algebraic notations.
  • R4: ${\displaystyle (1230)^{\star }B\cdot (1213)^{\star }B\cdot (1023)^{\star }\Phi =(1123)^{\star }\Phi \cdot (1233)^{\star }B}$ or ${\displaystyle (B_{1a}B_{2a}\Phi _{1a};B_{1b}B_{2b};B_{1c}B_{2a}\Phi _{1b};B_{2c}\Phi _{1c})=(\Phi _{2a}B_{3a};\Phi _{2a}B_{3b};\Phi _{2b}B_{3c};\Phi _{2c}B_{3c})}$.
  • R3: ${\displaystyle (1230)^{\star }B\cdot (1213)^{\star }B\cdot (1023)^{\star }B=(1123)^{\star }B\cdot (1203)^{\star }B\cdot (1231)^{\star }B}$ or ${\displaystyle (B_{1a}B_{2a}B_{3a};B_{1b}B_{2b};B_{1c}B_{2a}B_{3b};B_{2c}B_{3c})=(B_{4a}B_{5a}B_{6a};B_{4a}B_{5b}B_{6b};B_{4b}B_{6c};B_{4c}B_{5c}B_{6a})}$.
  • R2: ${\displaystyle (123)^{\star }B^{\pm }\cdot (132)^{\star }B^{\mp }=1_{3}}$ or ${\displaystyle (B_{1a}^{\pm }B_{2a}^{\mp };B_{2b}^{\pm }B_{3c}^{\mp };B_{1c}^{\pm }B_{2b}^{\mp })=(1;1;1)}$.
  • R1: ${\displaystyle (B_{a}^{\pm };B_{b}^{\pm }B_{c}^{\pm })=(1;T^{\pm 2})}$.
• But for now, skip the writing of the following relations:
  • Symmetry of ${\displaystyle \Phi }$ and of ${\displaystyle B^{\pm }}$.
  • ${\displaystyle u}$, ${\displaystyle d}$ and ${\displaystyle \#}$
  • Idempotence for ${\displaystyle T}$, ${\displaystyle R}$, ${\displaystyle \Phi }$ and ${\displaystyle B^{\pm }}$.
  • ${\displaystyle B^{\pm }}$ in terms of ${\displaystyle \Phi }$ and ${\displaystyle R}$ and ${\displaystyle R}$ in terms of ${\displaystyle T}$.

Exponentiation is a Miracle

• Description of the problem.
• Beads and strands.
• The perturbative approach, linearization.
• The syzygies: relations between the errors.
• The Hochschild complex and homology.