`SequenceLimit` became `NumericalMath``NSequenceLimit`. In the past, that change broke some of the examples on `NLimit` that used `SequenceLimit`. I reported the breakage, and the examples were fixed to use the same syntax but not actually call the now-non-existent function. The only remaining reference in the documentation that I can find to the use of `SequenceLimit` ***as if it were still a function*** is on the last bullet point of `NLimit`'s [detailed description][1] for its `Method` option: "uses `SequenceLimit` on constructed sequence".

Recently, I started investigating the behavior of `NumericalMath``NSequenceLimit` because I need it in my engineering work. I feel `NumericalMath``NSequenceLimit` has some quite confusing shortcomings in regard to the approximation it returns vs. the number of terms supplied, so I wrote my own version [from][2] [some][3] [references][4].

A comparison appears below showing the convergence of partial sums of series approximations to `Pi` and `E`. Afterward, I use symbolic lists to document several parts of `NumericalMath``NSequenceLimit` that seem... possibly wrong... to me.

    sPi@n_:=Sum[4(-1)^nn/(2nn+1),{nn,0,n}];
    Table[sPi@n,{n,0,4-1}]//N
    (*{4.,2.66667,3.46667,2.89524}*)

    NumericalMath`NSequenceLimit@%
    (*3.16667*)

    sequenceLimit@%%
    (*3.13333*)    
    (*my answer is closer to Pi~=3.141, for good reason as shown
      below in the general case with 4 terms {a,b,c,d}*)

    sE@n_:=Piecewise[{{(1+1/n)^n ,n!=0}},1] 
    Table[sE@n,{n,0,4-1}]//N
    (*{1.,2.,2.25,2.37037}*)

    NumericalMath`NSequenceLimit@%
    (*2.33333*)

    sequenceLimit@%%
    (*2.48214*)    
    (*my answer is closer to E~=2.71828, for good reason as shown
      below in the general case with 4 terms {a,b,c,d}*)

Below, I illustrate the difference between the behavior of the built-in `NumericalMath``NSequenceLimit` function vs. my `sequenceLimit` function for symbolic lists, like `{a,b,c,d}`.

    Quiet@NumericalMath`NSequenceLimit[{a,b,c}]
    (*NumericalMath`NSequenceLimit[{a,b,c}]*)
    (*yes, unevaluated with 3 inputs*)

    sequenceLimit[{a,b,c}]//Simplify (*my function*)
    (*(-b^2+a*c)/(a-2*b+c)*)
    (*same as Mathematica's next result with 4 inputs*)

    NumericalMath`NSequenceLimit[{a,b,c,d}]
    (*(-b^2+a*c)/(a-2*b+c)*)
    (*yes, only references a, b, & c not the later, more converged, d*)

    sequenceLimit[{a,b,c,d}]//Simplify (*my function*)
    (-c^2+b*d)/(b-2*c+d)
    (*note use of d, which explains why my approximations
      for Pi and E above are better*)

    Quiet@NumericalMath`NSequenceLimit[{a,b,c,d,e}]//Simplify
    (*(-b^2+a*c)/(a-2*b+c)*) 
    (*yes, same result as with 4 terms, no d or e in output*)

    sequenceLimit[{a,b,c,d,e}]//Simplify (*my function*)
    (*(c^3+a*d^2+b^2*e-c*(2*b*d+a*e))/
      (b^2+3*c^2-2*c*d+d^2-2*b*(c+d-e)-c*e-a*(c-2*d+e))*)
    (*note use of d and e*)


I also document some error messages that seem spurious.

    NumericalMath`NSequenceLimit[{a}]
    (*NumericalMath`NSequenceLimit::seqw Sequence of length 1
      is too short for use with Degree -> 1*)
    (*NumericalMath`NSequenceLimit::bdmtd WynnEpsilon is not
      a valid specification of a sequence limit extrapolation
      algorithm.*)
    (*NumericalMath`NSequenceLimit[{a}]*)

    NumericalMath`NSequenceLimit[{a},Degree->1]; (*Nulled output*)
    (*NumericalMath`NSequenceLimit:optx Unknown option ° in 
      NumericalMath`NSequenceLimit[{a}]*)

    NumericalMath`NSequenceLimit[{a},"Degree"->1]; (*Note quotes*)
    (*NumericalMath`NSequenceLimit::optx Unknown option "Degree"
      in NumericalMath`NSequenceLimit[{a}]*)

    sequenceLimit[{a}] (*sequence limit is my function*)
    (*a*)
    
    Quiet@NumericalMath`NSequenceLimit[{a,b}]
    (*NumericalMath`NSequenceLimit[{a,b}]*)

    sequenceLimit[{a,b}] (*my function*)
    (*b*)

Everything above is from the current version of Mathematica Online.

    $Version
    11.3.0 for Linux x86 (64-bit) (March 7, 2018)

Here is the definition of my function

    wynnE[-2,_,_]:=0
    wynnE[-1,n_,s_]:=s@n
    wynnE[rkp1_,n_,s_]:=(*wynnE[rkp1,n,s]=*)(*optional caching*)
     wynnE[rkp1-2,n+1,s]+1/(wynnE[rkp1-1,n+1,s]-wynnE[rkp1-1,n,s]) 

    sequenceLimit[list_?VectorQ]:=
     With[{len=Length@list},
      With[{off=Boole@EvenQ@len},
       wynnE[len-2-off,off,list[[#+1]]&]
      ]/;len>0
     ]


  [1]: http://reference.wolfram.com/language/NumericalCalculus/ref/NLimit.html
  [2]: http://mathworld.wolfram.com/WynnsEpsilonMethod.html
  [3]: http://www.adamponting.com/wynns-epsilon-method/
  [4]: http://www.dtic.mil/dtic/tr/fulltext/u2/a109445.pdf