Timeline: Difference between revisions

Nielsen: Is massively collaborative mathematics possible?

Gowers: A combinatorial approach to DHJ (1-199)

Gowers: Why this particular problem?

Tao: A massively collaborative mathematical project

Trevisan: A people's history of mathematics

Blank: Massively collaborative mathematics

Tao.4: Analytic proof of Sperner? Regularisation needed?

Hoang.4: Naive Varnavides for DHJ fails

Tao.4: Stationarity useful?

Tao.17: Should use [math]\displaystyle{ O(\sqrt{n}) }[/math] wildcards

Tao.18: Use rich slices?

Gowers.19: Collect obstructions to uniformity!

Kalai.29: Fourier-analytic proof of Sperner?

O'Donnell.32: Use uniform distribution on slices

Gowers.38: Can't fix # wildcards in advance

Tao.39: Can take # wildcards to be O(1)

Bukh.44: Obstructions to Kruskal-Katona?

Kalai.15: [math]\displaystyle{ c_n \gg 3^n/\sqrt{n} }[/math]

Tao.39: [math]\displaystyle{ c_n \geq 3^{n-O(\sqrt{\log n})} }[/math]

Tao.40: [math]\displaystyle{ c_3=18 }[/math]

Elsholtz.43: Moser(3)?

Gowers.70: Collection of obstructions to uniformity begins

Tao.86: Use Szemeredi's proof of Roth?

Tao.78: [math]\displaystyle{ c_4 \leq 54 }[/math]

Neylon.83: [math]\displaystyle{ 52 \leq c_4 \leq 54 }[/math], [math]\displaystyle{ 140 \leq c_5 \leq 162 }[/math]

Tao.118: Szemeredi's proof of Roth looks inapplicable

Bukh.132, O'Donnell.133, Solymosi.135: Proof of DHJ(2.5)

Tao.148: Obstructions to uniformity summarised

Gowers: The triangle removal approach (300-399)

Tao.206: Use [math]\displaystyle{ D_n }[/math]

Peake.217: [math]\displaystyle{ c_7 \geq 1308 }[/math], [math]\displaystyle{ c_8 \geq 3780 }[/math]

Peake.218: Lower bounds up to [math]\displaystyle{ c_{15} }[/math]

Ajtai-Szemeredi approach proposed

Tao.402: Standard obstruction to uniformity?

Gowers.403: Complexity 1 sets are more fundamental obstructions

Gowers.411: Are global complexity 1 sets the only obstructions?

Tao.225: Spreadsheet set up

Gowers.365: Equal slices measure introduced

Tao.419: Use low-influence instead of complexity 1?

Gowers.420: Need DHJ(0,2)

Tao.431: Use local obstructions rather than global obstructions?

Peake.243: [math]\displaystyle{ c_5 \leq 154 }[/math]

Tao.470: Proto-wiki created

Kalai.455: Hyper-optimistic conjecture

Tao: A reading seminar on DHJ (600-699)

Dyer.254: [math]\displaystyle{ \overline{c}^\mu_3 = 6 }[/math]

McCutcheon.480: Strong Roth theorem proposed

Jakobsen.258: [math]\displaystyle{ \overline{c}^\mu_5 = 12 }[/math]

Peake.262: Extremisers for [math]\displaystyle{ c_4 }[/math]

Tao.614: Carlson-Simpson not needed for stationarity

Tao.618: More randomness needed to invert maps

O'Donnell.622: [math]\displaystyle{ [3]^n }[/math] should already provide enough randomness

Tao.510: Finitary analogue of stationarity

Tao.514: DHJ(2.6) proposed

McCutcheon.518: Ramsey proof of DHJ(2.6)

Markström.706: Integer program, [math]\displaystyle{ c_5=150 }[/math]

Cantwell.708: [math]\displaystyle{ c_6=450 }[/math]

Tao.715: Genetic algorithm?

O'Donnell 529: Ramsey-free proof of DHJ(2.6)?

McCutcheon.533: Ramsey theory incompatible with symmetry

Tao.731: Human proof that [math]\displaystyle{ c_5 \leq 152 }[/math]; [math]\displaystyle{ c_7 \leq 1348 }[/math]

McCutcheon.541: "Cave-man" proof of DHJ(2.6)

Peake.738: Connection between Moser(3) and sphere packing

Gowers.545: Fourier computations on equal-slices measure begin

Peake.743: 43-point sets analysed

Cantwell.744: [math]\displaystyle{ c'_5 \leq 128 }[/math]

Tao.745: 50+ point line-free sets in [math]\displaystyle{ [3]^4 }[/math] listed

Peake.751: Human proof of [math]\displaystyle{ c_5 \leq 151 }[/math]

Gowers.581: Multidimensional Sperner

Gowers.582: Use Ajtai-Szemeredi argument to get density increment?

Tao.578: Finitary ergodic proof of DHJ(2) proposed

Tao.632: Special cases of DHJ(3) translated

Tao.753: Sequences submitted to OEIS

O'Donnell.596: Fourier-analytic proof of DHJ(2)

Gowers: Brief review of polymath1 (800-849)

O'Donnell.800: Fourier-analytic + density increment proof of DHJ(2)

Tao.464: [math]\displaystyle{ c'_5 \leq 127 }[/math]

Chua.766: 3D Moser sets with 222 have [math]\displaystyle{ \leq 13 }[/math] points

Tao.767: 4D Moser sets with 2222 have [math]\displaystyle{ \leq 39 }[/math] points

Gowers.812: Fourier vs physical positivity

O'Donnell.814: [math]\displaystyle{ \ell_1 }[/math], [math]\displaystyle{ \ell_2 }[/math] equivalence

O'Donnell.821: Simplified Fourier proof of DHJ(2) structure theorem

Peake.771: Exotic 43-point Moser sets described

Gowers.828: Does correlation with 1-set imply density increment?

Tao.828.4: Energy increment proof for Gowers Q?

Cantwell.776: [math]\displaystyle{ c'_5 \leq 126 }[/math]

Gowers.835: Pullbacks don't work

O'Donnell 839: Increment-free Fourier proof of DHJ(2)

Tao.853 Mass increment; connection with Hahn decomposition

Gowers.854 Higher-D Ajtai-Szemeredi?

Cantwell.787 125-sets have at most 41 points in middle slices

Marc.791: [math]\displaystyle{ \overline{c}^\mu_{10} \geq 29 }[/math]

Tao.793: "score" introduced

Tao: DHJ3 (900-999) Density Hales-Jewett type numbers

Tao.901: 125-sets have D=0

Dyer.902: [math]\displaystyle{ \overline{c}^\mu_6 \lt 17 }[/math]

Carr.903: Genetic algorithm implemented

Tao.908 Find Pareto-optimal and extremal statistics?

Dyer.909 Wildcard variants of Moser

Cantwell.912 125-sets have at most 40 points in middle slices

Cantwell.913 125-sets have D=0 (alternate proof)

Peake.914 Pareto-optimal 3D statistics

Cantwell.920 [math]\displaystyle{ c'_6 \leq 373 }[/math]

Cantwell.921 125-sets have C=78 or 79

Markstrom.923 [math]\displaystyle{ \overline{c}^\mu_n = 6,9,12,15,18,22,26,31,35,40 }[/math] for [math]\displaystyle{ n=3,\ldots,12 }[/math]

Guest.930 GA without crossover?

Cantwell.932 125-sets have a middle slice of at most 39 points

Cantwell.933 125-sets have A=6,7,8

Cantwell.934 If C=78 then A=7,8

Tao.935 125-sets have stats (6,40,79,0,0,0), (7,40,78,0,0) or (8,39,78,0,0)

Gowers.882 New proof of Ajtai-Szemeredi

O'Donnell.884 Multidimensional Sperner written up

Carr.940 [math]\displaystyle{ c'_6 \geq 353; c'_7 \geq 978 }[/math]

Tao.941 Seeding GA?

Cantwell.942 (6,40,79,0,0) eliminated

Tao.943 Linear programming proof of [math]\displaystyle{ c'_4 =43 }[/math]

Tao.944 [math]\displaystyle{ c'_6 \leq 364 }[/math]

Gowers.886 DHJ(4)?

Gowers.897 Writing of DHJ(k) begins

Cantwell.949 (8,39,87,0,0) eliminated: [math]\displaystyle{ c'_5 = 124 }[/math]

Tao.950 [math]\displaystyle{ \overline{c}^\mu_n }[/math] submitted to OEIS

Carr.954 [math]\displaystyle{ c'_7 \geq 988 }[/math]

OU Math club: Problem solved (probably)

Gowers.1005.1 Tower-type bounds

Solymosi.1011 Shelah-type argument?

Elsholtz.962 Analysis of GA solutions

Tao.969 Integer programming for Behrend sphere statistics

Tao.970 [math]\displaystyle{ c'_7 \leq 1086 }[/math]

Gowers.1020 No apparent obstacles to proving DHJ(k)

O'Donnell.1025 Work exclusively with equal (non-degenerate) slices measure?

Tao.974: [math]\displaystyle{ c'_6 \leq 361 }[/math], [math]\displaystyle{ c'_7 \leq 1078 }[/math]

Cantwell.976: Partial recovery of 4D stats by hand

Galdino: Links seminais

Flaxman: Gowers' polymath experiment: problem probably solved

Peake.982: xxyyzz inequalities

O'Bryant.984, O'Bryant.993: [math]\displaystyle{ c_n \gg 3^{n - 4\sqrt{\log 2}\sqrt{\log n}+\frac 12 \log \log n} }[/math]

Cantwell.985: Human proof of [math]\displaystyle{ c^\mu_3=6 }[/math] begins

Peake.989: xxyyz inequalities

Tao.990: [math]\displaystyle{ c'_7 \leq 1071 }[/math]

Peake.991: xxxyz, xxxxyz, xxxyyz inequalities

Seva.994: Kakeya in [3]^n?

Nielsen: How changing the technology of collaboration can change the nature of collaboration

Vipulnaik: Concluding notes on the polymath project - and a challenge

Dyer: A gentle introduction to the Polymath project