# Singular

### A.4.1 Milnor and Tjurina number

The Milnor number, resp. the Tjurina number, of a power series f in is

respectively

wherejacob(f) is the ideal generated by the partials of f. tjurina(f) is finite, if and only if f has an isolated singularity. The same holds for milnor(f) if K has characteristic 0. SINGULAR displays -1 if the dimension is infinite.

SINGULAR cannot compute with infinite power series. But it can work in ,the localization of at the maximal ideal .To do this, one has to define a ring with a local monomial ordering such as ds, Ds, ls, ws, Ws (the second letter 's' referring to power 's'eries), or an appropriate matrix ordering. See Monomial orderings for a menu of possible orderings.

For theoretical reasons, the vector space dimension computed over the localization ring coincides with the Milnor (resp. Tjurina) number as defined above (in the power series ring).

We show in the example below the following:

• set option prot to have a short protocol during standard basis computation
• define the ring r1 of characteristic 32003 with variables x,y,z, monomial ordering ds, series ring (i.e., K[x,y,z] localized at (x,y,z))
• list the information about r1 by typing its name
• define the integers a,b,c,t
• define a polynomial f (depending on a,b,c,t) and display it
• define the jacobian ideal i of f
• compute a standard basis of i
• compute the Milnor number (=250) with vdim and create and display a string in order to comment the result (text between quotes " "; is a 'string')
• compute a standard basis of i+(f)
• compute the Tjurina number (=195) with vdim
• then compute the Milnor number (=248) and the Tjurina number (=195) for t=1
• reset the option to noprot
See also sing_lib for the library commands for the computation of the Milnor and Tjurina number.

  option(prot); ring r1 = 32003,(x,y,z),ds; r1; ==> // characteristic : 32003 ==> // number of vars : 3 ==> // block 1 : ordering ds ==> // : names x y z ==> // block 2 : ordering C int a,b,c,t=11,5,3,0; poly f = x^a+y^b+z^(3*c)+x^(c+2)*y^(c-1)+x^(c-1)*y^(c-1)*z3+ x^(c-2)*y^c*(y^2+t*x)^2; f; ==> y5+x5y2+x2y2z3+xy7+z9+x11 ideal i=jacob(f); i; ==> i[1]=5x4y2+2xy2z3+y7+11x10 ==> i[2]=5y4+2x5y+2x2yz3+7xy6 ==> i[3]=3x2y2z2+9z8 ideal j=std(i); ==> [1023:2]7(2)s8s10s11s12s(3)s13(4)s(5)s14(6)s(7)15--.s(6)-16.-.s(5)17.s(7)\ s--s18(6).--19-..sH(24)20(3)...21....22....23.--24- ==> product criterion:10 chain criterion:69 "The Milnor number of f(11,5,3) for t=0 is", vdim(j); ==> The Milnor number of f(11,5,3) for t=0 is 250 j=i+f; // override j j=std(j); ==> [1023:2]7(3)s8(2)s10s11(3)ss12(4)s(5)s13(6)s(8)s14(9).s(10).15--sH(23)(8)\ ...16......17.......sH(21)(9)sH(20)16(10).17...........18.......19..----.\ .sH(19) ==> product criterion:10 chain criterion:53 vdim(j); // compute the Tjurina number for t=0 ==> 195 t=1; f=x^a+y^b+z^(3*c)+x^(c+2)*y^(c-1)+x^(c-1)*y^(c-1)*z3 +x^(c-2)*y^c*(y^2+t*x)^2; ideal i1=jacob(f); ideal j1=std(i1); ==> [1023:2]7(2)s8s10s11s12s13(3)ss(4)s14(5)s(6)s15(7).....s(8)16.s...s(9)..1\ 7............s18(10).....s(11)..-.19.......sH(24)(10).....20...........21\ ..........22.............................23..............................\ .24.----------.25.26 ==> product criterion:11 chain criterion:83 "The Milnor number of f(11,5,3) for t=1:",vdim(j1); ==> The Milnor number of f(11,5,3) for t=1: 248 vdim(std(j1+f)); // compute the Tjurina number for t=1 ==> [1023:2]7(16)s8(15)s10s11ss(16)-12.s-s13s(17)s(18)s(19)-s(18).-14-s(17)-s\ (16)ss(17)s15(18)..-s...--.16....-.......s(16).sH(23)s(18)...17..........\ 18.........sH(20)17(17)....................18..........19..---....-.-....\ .....20.-----...s17(9).........18..............19..-.......20.-......21..\ .......sH(19)16(5).....18......19.----- ==> product criterion:15 chain criterion:174 ==> 195 option(noprot);