Progress on Dedekind's Problem

The note Dedekind's Problem defines the set of monotone Boolean (i.e., 
functions expressible using only AND and OR logical operations), and 
discusses the problem of enumerating all the monotone functions of n 
variables.  One approach is to consider M(n,k), which is the number of 
monotone Boolean functions of n variables with exactly k mincuts.  
The following is a table giving M(n,k) for the first several values 
of n:

         M(n,k), the number of distinct monotone Boolean 
            functions of n variables with k mincuts
         -----------------------------------------------
                            n
  k     0    1    2     3      4       5         6        7         8
 ---   ---  ---  ---  ----  -----   -----    ------   ------  --------
  0     1    1    1     1      1       1         1        1         1
  1     1    2    4     8     16      32        64      128       256
  2               1     9     55     285      1351     6069     26335
  3                     2     64    1090     14000   153762   1533504
  4                           25    2020     82115  2401910  58089465
  5                            6    2146    304752     :         :
  6                            1    1380    759457     :         :
  7                                  490   1308270
  8                                  115   1613250
  9                                   20   1484230
 10                                    2   1067771
 11                                         635044
 12                                         326990
 13                                         147440
 14                                          57675
 15                                          19238
 16                                           5325
 17                                           1170
 18                                            190
 19                                             20
 20                                              1
      ---  ---  ---   ---   ----   -----   ------- 
Tots   2     3    6    20    168    7581   7828354

In the previous note I gave the formulas for M(n,k) with k=0,1,2,3
as follows

   M(n,0) = 1  

   M(n,1) = 2^n

   M(n,2) = (2^n)(2^n - 1)/2  -  (3^n - 2^n)

   M(n,3) = (2^n)(2^n - 1)(2^n - 2)/6  -  (6^n - 5^n - 4^n + 3^n)

These formulas give the horizontal rows of the preceding table, 
including the leading zeros.  Its clear from these cases that, in 
general, M(n,k) must be expressible as a sum of the form

                      1   2^n
          M(n,k)  =  --- SUM   c_m  m^n
                      n!  m=2

for some integer coefficients c_m.  In the original version of this
note I asked if anyone knew the formulas for M(n,k) with k > 3.  This
was also Problem #7 on my Most Wanted List.

In September of 1999 I received an email from Vladeta Jovovic informing
me that he, G. Kilibarda, and Z. Maksimovic of the University of 
Belgrade are preparing a paper in which they give the expressions 
for M(n,k) for k = 4 to 10.  They were kind enough to send me these 
expressions, and they are fascinating.  As one would expect, they are 
of the form noted above, and consequently the summation for k=10 has 
roughly 2^10 =1024 terms, less the number of terms for which the 
coefficient c_m happens to be zero.

With k=4 we seek a formula M(n,4) that gives the values from the 4th 
row of the table above, i.e.,

   0   0   0   0   25   2020    82115   2401910    58089465  ...

for n = 0,1,2,...  The formula found by Jovovic, Kilibarda, Maksimovic
for k=4 is

            1   /  n        n        n     n       n      n       n
  M(n,4) = --- ( 16  - 12*12  + 24*10 + 4*9  - 18*8  + 6*7  - 36*6
            4!  \

                                     n       n       n      n \
                               + 36*5  + 11*4  - 22*3  + 6*2   )
                                                              /

There are some very interesting patterns in the coefficients c_m of 
these expressions.  Looking at the highest powers with non-zero
coefficients, we have

  k
 ---
  2      4^n  -   2 *  3^n  +    1 *   2^n
  3      8^n  -   6 *  6^n  +    6 *   5^n  +    3 *   4^n  + ...
  4     16^n  -  12 * 12^n  +   24 *  10^n  +    4 *   9^n  + ...
  5     32^n  -  20 * 24^n  +   60 *  20^n  +   20 *  18^n  + ...
  6     64^n  -  30 * 48^n  +  120 *  40^n  +   60 *  36^n  + ...
  7    128^n  -  42 * 96^n  +  210 *  80^n  +  140 *  72^n  + ...
  8    256^n  -  56 *192^n  +  336 * 160^n  +  280 * 144^n  + ...
  9    512^n  -  72 *384^n  +  504 * 320^n  +  504 * 288^n  + ...
 10   1024^n  -  90 *768^n  +  720 * 640^n  +  840 * 576^n  + ...

Clearly the bases tend to double at each level, once the pattern is
initiated.  Also, the coefficients fall into easily recognizable
sequences.

We can also examine the coefficients of the lowest powers in each
expression.  It appears that these are closely related to the Stirling
numbers of the first kind.  If we denote the absolute values of the
Stirling numbers by S{m,n}, indexed as shown below

                                n
           1     2     3     4     5     6     7     8
     m   ----- ----- ----- ----- ----- ----- ----- -----
    ---
     1      1     0     0     0     0     0     0     0
     2      1     1     0     0     0     0     0     0
     3      2     3     1     0     0     0     0     0
     4      6    11     6     1     0     0     0     0
     5     24    50    35    10     1     0     0     0
     6    120   274   225    85    15     1     0     0
     7    720  1764  1624   735   175    21     1     0
     8   5040 13068 13132  6769  1960   322    28     1


then the non-zero coefficients of the lowest powers are as summarized 
below

     Term             Coefficient
     -----   -----------------------------------
      2^n     1 S{k,1}
      3^n    -2 S{k,2}
      4^n     1 S{k,2}
      5^n     6 S{k,3}
      6^n    -6 S{k,3}
      7^n     6 S{k,4}
      8^n     1 S{k,3} -  24 S{k,4}
      9^n     4 S{k,4}
     10^n    24 S{k,4}
     11^n    20 S{k,5}
     12^n   -12 S{k,4} - 120 S{k,5}
     13^n   120 S{k,5}
     14^n   150 S{k,5}
     15^n  -120 S{k,5} -  20 S{k,6}
     16^n     1 S{k,4} - 120 S{k,5} + 180 S{k,6}
     17^n    10 S{k,5} - 360 S{k,6}
     18^n    20 S{k,5} - 240 S{k,6}
     19^n   750 S{k,6}
     20^n    60 S{k,5} + 480 S{k,6}
     21^n  -540 S{k,6}
     22^n  -240 S{k,6}
     23^n  -720 S{k,6} +  70 S{k,7}
     24^n   -20 S{k,5} - 180 S{k,6} - 840 S{k,7}
     25^n    36 S{k,6} +2520 S{k,7}

and so on.  Placing the coefficients of the Stirling numbers into a 
table, we have

        Multiplier of Stirling Number S{k,j} in Coefficient of Term
 Term    1    2    3     4     5      6     7      8      9    10
 ----   ---  ---  ---  ----  ----   ----  -----  -----  ----  -----
  2^n    1                                                          
  3^n        -2                                                    
  4^n         1                                                    
  5^n              6                                                
  6^n             -6                                               
  7^n                    6                                          
  8^n              1   -24                                          
  9^n                    4                                           
 10^n                   24                                           
 11^n                          20                                    
 12^n                  -12   -120                                    
 13^n                         120                                    
 14^n                         150                                    
 15^n                        -120    -20                            
 16^n                    1   -120    180                            
 17^n                          10   -360                            
 18^n                          20   -240                             
 19^n                                750                             
 20^n                          60    480                             
 21^n                               -540                             
 22^n                               -240                             
 23^n                               -720     70                      
 24^n                         -20   -180   -840                      
 25^n                                360   2520                      
 26^n                                480    420                     
 27^n                                120  -7560                       
 28^n                                810  -2520                     
 29^n                                     13860                      
 30^n                               -720   6580                      
 31^n                                     -8400     70                
 32^n                           1   -360  -2520  -1120           -1
       ---  ---  ---   ---     ---
  Sum    1   -1   1    -1       1


Is there a simple way of determining these coefficients for arbitrary
terms?  The "roundness" of these numbers, and the fact that each 
column sums to +-1, suggests that there might be a useful combinatorial 
interpretation.

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