--- title: Counterexample Search Notes --- # Goal Try to find a counterexample to the rainbow-base-cover conjecture: > If a rank-$r$ matroid on $2r$ elements decomposes into two disjoint bases, and the elements are colored by $r$ colors each used twice, then three rainbow bases cover the ground set. I also tracked the stronger special case of the double-cover conjecture in the partition-matroid setting: > For the rainbow bases, are there always four of them covering each element exactly twice? # Search Design ## Encoding Fix a pairing of the $2r$ elements into color classes. A rainbow basis chooses exactly one element from each pair, so for fixed coloring there are at most $2^r$ rainbow candidates. For a matroid $M$, I tested: 1. whether $M$ has two disjoint bases; 2. for each pairing, which of the $2^r$ transversals are actual bases; 3. whether some $3$ rainbow bases cover all $2r$ elements; 4. whether some 4 rainbow bases cover every element exactly twice. This was implemented in [search_rainbow_counterexample.py](/Users/congyu/rainbow_base_cover/search_rainbow_counterexample.py). ## Exhaustive part Sage's $AllMatroids(2r, r)$ is available up to $r = 4$, so I checked all unlabeled rank-$r$ matroids on $2r$ elements for $r = 1,2,3,4$, and all pairings of the ground set: - $r = 1$: $1$ pairing - $r = 2$: $3$ pairings - $r = 3$: $15$ pairings - $r = 4$: $105$ pairings ## Additional rank-5 probes Since Sage does not exhaust all rank-5 matroids on 10 elements, I also sampled random linear matroids over small fields, and exhaustively checked some graphic families: - random rank-$5$ linear matroids over $GF(2), GF(3), GF(4), GF(5)$; - all simple graphic matroids coming from 8-edge graphs on 5 vertices. # Results ## Exhaustive search for $r \le 4$ No counterexample appeared. | rank $r$ | matroids checked | qualifying matroids | max observed minimum cover | any 3-cover failure? | any 4-double-cover failure? | |---|---:|---:|---:|---|---| | 1 | 2 | 1 | 2 | no | no | | 2 | 7 | 3 | 2 | no | no | | 3 | 38 | 17 | 3 | no | no | | 4 | 940 | 730 | 3 | no | no | So: - the rainbow-cover conjecture holds for every matroid in Sage's complete database with $2r \le 8$; - in the same range, the stronger partition-matroid double-cover statement also holds. ## Explicit rank-4 witness requiring 3 bases The first rank-$4$ example I found with minimum cover number exactly $3$ is - matroid: all_n08_r04_#493 - pairing: $\bigl((0,5),(1,4),(2,3),(6,7)\bigr)$ For this pairing there are exactly $8$ rainbow bases: $(0,1,3,6)$, $(0,1,3,7)$, $(0,2,4,6)$, $(0,2,4,7)$, $(1,2,5,6)$, $(1,2,5,7)$, $(3,4,5,6)$, $(3,4,5,7)$. This instance still has: - minimum rainbow cover size $= 3$; - a 4-rainbow exact double cover. So the search really is reaching the sharp bound $3$, not just easy cases with cover number $2$. ## Graphic search The known lower-bound example $K_4$ is reproduced computationally: - all simple graphs on $4$ vertices with $6$ edges: $1$ graph checked; - maximum minimum cover number: $3$; - no 3-cover failure; - no 4-double-cover failure. I also checked all simple 8-edge graphs on 5 vertices: - graphs checked: $45$; - connected graphs: $45$; - qualifying graphic matroids: $45$; - maximum minimum cover number: $3$; - no 3-cover failure; - no 4-double-cover failure. One concrete simple graphic rank-$4$ witness with minimum cover $3$ is the graph with edge set $\bigl((0,1),(0,2),(0,3),(0,4),(1,2),(1,3),(1,4),(2,3)\bigr)$ and pairing $\bigl((0,3),(1,5),(2,4),(6,7)\bigr)$. ## Random rank-5 linear search No sampled rank-$5$ linear matroid produced a counterexample. Finished runs: | field | samples | distinct matroids checked | qualifying matroids | max observed minimum cover | any 3-cover failure? | any 4-double-cover failure? | |---|---:|---:|---:|---:|---|---| | $GF(2)$ | 200 | 200 | 92 | 3 | no | no | | $GF(2)$ | 500 | 500 | 245 | 3 | no | no | | $GF(3)$ | 200 | 200 | 180 | 3 | no | no | | $GF(4)$ | 200 | 200 | 99 | 3 | no | no | | $GF(5)$ | 200 | 200 | 200 | 2 | no | no | # Observations ## Small-rank evidence is strong Up through rank 4, the search is exhaustive, not heuristic. In that range I found no obstruction even to the stronger four-basis exact double-cover property. ## Rank 4 already has nontrivial tight examples The bound $3$ is still best possible in rank $4$: there are pairings where $2$ rainbow bases do not suffice, but $3$ do. ## The partition-matroid special case looks robust At least computationally, the partition-matroid case of the double-cover conjecture behaves better than expected: - exhaustive success for all matroids on 8 elements of rank 4; - no failures in the rank-5 linear samples over four small fields; - no failures in the checked graphic families. # What I would try next ## More targeted rank-5 search The next most plausible places to look are: 1. exhaustive or semi-exhaustive graphic search on 10 edges and 6 vertices; 2. sparse paving matroids of rank 5 on 10 elements; 3. biased random linear constructions, especially sparse or highly structured matrices rather than dense uniform random ones; 4. direct search for the stronger four-basis exact double-cover failure, since that might break before the three-cover statement does. ## Structural reformulation For a fixed pairing, the rainbow bases form a subset $F \subseteq \{0,1\}^r$. Then: - $3$-cover means there exist $x,y,z \in F$ such that in every coordinate, not all of $x_i,y_i,z_i$ are equal; - exact $4$-double-cover means there exist $x_1,x_2,x_3,x_4 \in F$ such that every coordinate has exactly two $0$s and two $1$s. This reformulation may be a better starting point for a structural attack than thinking directly in matroid language. # Current Status I did not find a counterexample. The strongest completed evidence from this turn is: - exhaustive verification for all rank-$r$ matroids on $2r$ elements with $r \le 4$; - exhaustive verification for simple graphic rank-4 instances on 8 edges; - no sampled failure among several hundred rank-$5$ linear matroids over $GF(2), GF(3), GF(4), GF(5)$.