% Hyperbolic algebraic varieties and holomorphic differential equations
%
% expanded version of VIASM Lecture (Hanoi, August 25-26, 2012)
% Jean-Pierre Demailly 
%
% Universit\'e de Grenoble I, Institut Fourier
% Plain-TeX file

\def\ref#1{??#1??}

% page setting
\magnification=1200
\pretolerance=500 \tolerance=1000 \brokenpenalty=5000
\hsize=14cm \hoffset=-3mm \vsize=21cm \voffset=-3mm
\parskip3.5pt plus 1.5pt minus 1pt
\parindent=0.6cm

% new fonts definitions

\let\em=\it

\font\seventeenbf=ec-lmbx10 at 17.28pt
\font\fourteenbf=ec-lmbx10 at 14.4pt
\font\twelvebf=ec-lmbx10 at 12pt
\font\eightbf=ec-lmbx10
\font\sixbf=ec-lmbx10

\font\twelvei=cmmi10 at 12pt
\font\eighti=cmmi8
\font\sixi=cmmi6

\font\twelverm=ec-lmr10 at 12pt
\font\eightrm=ec-lmr10 at 8pt
\font\sixrm=ec-lmr10 at 6pt

\font\eightsy=cmsy8
\font\sixsy=cmsy6

\font\eightit=ec-lmri10 at 8pt
\font\eightsl=ec-lmro10 at 8pt
\font\eighttt=ec-lmtt10 at 8pt

\font\seventeenbsy=cmbsy10 at 17.28pt
\font\fourteenbsy=cmbsy10 at 14.4pt
\font\twelvebsy=cmbsy10 at 12pt
\font\tenbsy=cmbsy10
\font\eightbsy=cmbsy8
\font\sevenbsy=cmbsy7
\font\sixbsy=cmbsy6
\font\fivebsy=cmbsy5

\font\tenmsa=msam10
\font\eightmsa=msam8
\font\sevenmsa=msam7
\font\fivemsa=msam5
\newfam\msafam
  \textfont\msafam=\tenmsa
  \scriptfont\msafam=\sevenmsa
  \scriptscriptfont\msafam=\fivemsa
\def\msa{\fam\msafam\tenmsa}

\font\tenmsb=msbm10
\font\eightmsb=msbm8
\font\sevenmsb=msbm7
\font\fivemsb=msbm5
\newfam\msbfam
  \textfont\msbfam=\tenmsb
  \scriptfont\msbfam=\sevenmsb
  \scriptscriptfont\msbfam=\fivemsb
\def\Bbb{\fam\msbfam\tenmsb}

\font\tenbbo=bbold10 at 11pt
\font\sevenbbo=bbold10 at 8pt
\font\fivebbo=bbold10 at 6pt
\newfam\bbofam
  \textfont\bbofam=\tenbbo
  \scriptfont\bbofam=\sevenbbo
  \scriptscriptfont\bbofam=\fivebbo
\def\Bbo{\fam\bbofam\tenbbo}

\font\tenCal=eusm10
\font\sevenCal=eusm7
\font\fiveCal=eusm5
\newfam\Calfam
  \textfont\Calfam=\tenCal
  \scriptfont\Calfam=\sevenCal
  \scriptscriptfont\Calfam=\fiveCal
\def\Cal{\fam\Calfam\tenCal}

\font\teneuf=eusm10
\font\teneuf=eufm10
\font\seveneuf=eufm7
\font\fiveeuf=eufm5
\newfam\euffam
  \textfont\euffam=\teneuf
  \scriptfont\euffam=\seveneuf
  \scriptscriptfont\euffam=\fiveeuf
\def\euf{\fam\euffam\teneuf}
\let\goth=\euf

\font\seventeenbfit=cmmib10 at 17.28pt
\font\fourteenbfit=cmmib10 at 14.4pt
\font\twelvebfit=cmmib10 at 12pt
\font\tenbfit=cmmib10
\font\eightbfit=cmmib8
\font\sevenbfit=cmmib7
\font\sixbfit=cmmib6
\font\fivebfit=cmmib5
\newfam\bfitfam
  \textfont\bfitfam=\tenbfit
  \scriptfont\bfitfam=\sevenbfit
  \scriptscriptfont\bfitfam=\fivebfit
\def\bfit{\fam\bfitfam\tenbfit}

% changing font sizes

\catcode`\@=11
\def\eightpoint{%
  \textfont0=\eightrm \scriptfont0=\sixrm \scriptscriptfont0=\fiverm
  \def\rm{\fam\z@\eightrm}%
  \textfont1=\eighti \scriptfont1=\sixi \scriptscriptfont1=\fivei
  \def\oldstyle{\fam\@ne\eighti}%
  \textfont2=\eightsy \scriptfont2=\sixsy \scriptscriptfont2=\fivesy
  \textfont\itfam=\eightit
  \def\it{\fam\itfam\eightit}%
  \textfont\slfam=\eightsl
  \def\sl{\fam\slfam\eightsl}%
  \textfont\bffam=\eightbf \scriptfont\bffam=\sixbf
  \scriptscriptfont\bffam=\fivebf
  \def\bf{\fam\bffam\eightbf}%
  \textfont\ttfam=\eighttt
  \def\tt{\fam\ttfam\eighttt}%
  \textfont\msbfam=\eightmsb
  \def\Bbb{\fam\msbfam\eightmsb}%
  \abovedisplayskip=9pt plus 2pt minus 6pt
  \abovedisplayshortskip=0pt plus 2pt
  \belowdisplayskip=9pt plus 2pt minus 6pt
  \belowdisplayshortskip=5pt plus 2pt minus 3pt
  \smallskipamount=2pt plus 1pt minus 1pt
  \medskipamount=4pt plus 2pt minus 1pt
  \bigskipamount=9pt plus 3pt minus 3pt
  \normalbaselineskip=9pt
  \setbox\strutbox=\hbox{\vrule height7pt depth2pt width0pt}%
  \let\bigf@ntpc=\eightrm \let\smallf@ntpc=\sixrm
  \normalbaselines\rm}
\catcode`\@=12

\def\eightpointbf{%
 \textfont0=\eightbf   \scriptfont0=\sixbf   \scriptscriptfont0=\fivebf
 \textfont1=\eightbfit \scriptfont1=\sixbfit \scriptscriptfont1=\fivebfit
 \textfont2=\eightbsy  \scriptfont2=\sixbsy  \scriptscriptfont2=\fivebsy
 \eightbf
 \baselineskip=10pt}

\def\tenpointbf{%
 \textfont0=\tenbf   \scriptfont0=\sevenbf   \scriptscriptfont0=\fivebf
 \textfont1=\tenbfit \scriptfont1=\sevenbfit \scriptscriptfont1=\fivebfit
 \textfont2=\tenbsy  \scriptfont2=\sevenbsy  \scriptscriptfont2=\fivebsy
 \tenbf}
        
\def\twelvepointbf{%
 \textfont0=\twelvebf   \scriptfont0=\eightbf   \scriptscriptfont0=\sixbf
 \textfont1=\twelvebfit \scriptfont1=\eightbfit \scriptscriptfont1=\sixbfit
 \textfont2=\twelvebsy  \scriptfont2=\eightbsy  \scriptscriptfont2=\sixbsy
 \twelvebf
 \baselineskip=14.4pt}

\def\fourteenpointbf{%
 \textfont0=\fourteenbf   \scriptfont0=\tenbf   \scriptscriptfont0=\sevenbf
 \textfont1=\fourteenbfit \scriptfont1=\tenbfit \scriptscriptfont1=\sevenbfit
 \textfont2=\fourteenbsy  \scriptfont2=\tenbsy  \scriptscriptfont2=\sevenbsy
 \fourteenbf
 \baselineskip=17.28pt}

\def\seventeenpointbf{%
 \textfont0=\seventeenbf  \scriptfont0=\twelvebf  \scriptscriptfont0=\eightbf
 \textfont1=\seventeenbfit\scriptfont1=\twelvebfit\scriptscriptfont1=\eightbfit
 \textfont2=\seventeenbsy \scriptfont2=\twelvebsy \scriptscriptfont2=\eightbsy
 \seventeenbf
 \baselineskip=20.736pt}
 

% main item macros

\newdimen\srdim \srdim=\hsize
\newdimen\irdim \irdim=\hsize
\def\NOSECTREF#1{\noindent\hbox to \srdim{\null\dotfill ???(#1)}}
\def\SECTREF#1{\noindent\hbox to \srdim{\csname REF\romannumeral#1\endcsname}}
\def\INDREF#1{\noindent\hbox to \irdim{\csname IND\romannumeral#1\endcsname}}
\newlinechar=`\^^J
  
\def\openauxfile{
  \immediate\openin1\jobname.aux
  \ifeof1
  \message{^^JCAUTION\string: you MUST run TeX a second time^^J}
  \let\sectref=\NOSECTREF \let\indref=\NOSECTREF
  \else
  \input \jobname.aux
  \message{^^JCAUTION\string: if the file has just been modified you may 
    have to run TeX twice^^J}
  \let\sectref=\SECTREF \let\indref=\INDREF
  \fi
  \message{to get correct page numbers displayed in Contents or Index 
    Tables^^J}
  \immediate\openout1=\jobname.aux
  \let\END=\end \def\end{\immediate\closeout1\END}}
        
\newbox\titlebox   \setbox\titlebox\hbox{\hfil}
\newbox\sectionbox \setbox\sectionbox\hbox{\hfil}
\def\folio{\ifnum\pageno=1 \hfil \else \ifodd\pageno
           \hfil {\eightpoint\copy\sectionbox\kern8mm\number\pageno}\else
           {\eightpoint\number\pageno\kern8mm\copy\titlebox}\hfil \fi\fi}
\footline={\hfil}
\headline={\folio}           

\def\blankline{\phantom{}\hfil\vskip0pt}
\def\titlerunning#1{\setbox\titlebox\hbox{\eightpoint #1}}
\def\title#1{\noindent\hfil$\smash{\hbox{\seventeenpointbf #1}}$\hfil
             \titlerunning{#1}\medskip}
\def\titleleft#1{\noindent$\smash{\hbox{\seventeenpointbf #1}}$\hfil
                 \titlerunning{#1}\medskip}

\def\supersection#1{%
  \par\vskip0.5cm\penalty -100 
  \vbox{\baselineskip=17.28pt\noindent{{\fourteenpointbf #1}}}
  \vskip3pt
  \penalty 500
  \titlerunning{#1}}

\newcount\numbersection \numbersection=-1
\def\sectionrunning#1{\setbox\sectionbox\hbox{\eightpoint #1}
  \immediate\write1{\string\def \string\REF 
      \romannumeral\numbersection \string{%
      \noexpand#1 \string\dotfill \space \number\pageno \string}}}
\def\section#1{%
  \par\vskip0.5cm\penalty -100
  \vbox{\baselineskip=14.4pt\noindent{{\twelvepointbf #1}}}
  \vskip2pt
  \penalty 500
  \advance\numbersection by 1
  \sectionrunning{#1}}

\def\subsection#1|{%
  \par\vskip0.25cm\penalty -100
  \vbox{\noindent{{\tenpointbf #1}}}
  \vskip1pt
  \penalty 500}

\newcount\numberindex \numberindex=0  
\def\startindex#1\par{\message{#1}}
\def\index#1{#1
  \advance\numberindex by 1
  \immediate\write1{\string\def \string\IND 
     \romannumeral\numberindex \string{%
     \ifnum\pageno=\pageno \fi
     \noexpand#1 \string\dotfill \space \string\S \number\numbersection, 
     p.\string\ \space\number\pageno \string}}}

\newdimen\itemindent \itemindent=\parindent
\def\setitemindent#1{\setbox0=\hbox{#1~}\itemindent=\wd0}
\def\item#1{\par\noindent\hangindent\itemindent%
            \rlap{#1}\kern\itemindent\ignorespaces}
\def\itemitem#1{\par\noindent\hangindent2\itemindent%
            \kern\itemindent\rlap{#1}\kern\itemindent\ignorespaces}
\def\itemitemitem#1{\par\noindent\hangindent3\itemindent%
            \kern2\itemindent\rlap{#1}\kern\itemindent\ignorespaces}

\long\def\claim#1|#2\endclaim{\par\vskip 5pt\noindent 
{\tenpointbf #1.}\ {\em #2}\par\vskip 5pt}

\def\proof{\noindent{\em Proof}}

\def\bottomnote#1#2{\footnote{\hbox{#1}}{\eightpoint #2\vskip-2\parskip
\vskip-\baselineskip}}

\def\today{\ifcase\month\or
January\or February\or March\or April\or May\or June\or July\or August\or
September\or October\or November\or December\fi \space\number\day,
\number\year}

\catcode`\@=11
\newcount\@tempcnta \newcount\@tempcntb 
\def\timeofday{{%
\@tempcnta=\time \divide\@tempcnta by 60 \@tempcntb=\@tempcnta
\multiply\@tempcntb by -60 \advance\@tempcntb by \time
\ifnum\@tempcntb > 9 \number\@tempcnta:\number\@tempcntb
  \else\number\@tempcnta:0\number\@tempcntb\fi}}
\catcode`\@=12

\def\bibitem#1&#2&#3&#4&%
{\hangindent=1.85cm\hangafter=1
\noindent\rlap{\hbox{\eightpointbf #1}}\kern1.85cm{\rm #2}{\it #3}{\rm #4.}} 

% blackboard symbols
\def\bB{{\Bbb B}}
\def\bC{{\Bbb C}}
\def\bD{{\Bbb D}}
\def\bG{{\Bbb G}}
\def\bH{{\Bbb H}}
\def\bN{{\Bbb N}}
\def\bP{{\Bbb P}}
\def\bQ{{\Bbb Q}}
\def\bR{{\Bbb R}}
\def\bS{{\Bbb S}}
\def\bT{{\Bbb T}}
\def\bU{{\Bbb U}}
\def\bZ{{\Bbb Z}}
\def\bOne{{\mathchoice {\rm 1\mskip-4mu l} {\rm 1\mskip-4mu l}
    {\rm 1\mskip-4.5mu l} {\rm 1\mskip-5mu l}}}
\def\bDelta{{\Bbo\Delta}}
    
% calligraphic symbols
\def\cA{{\Cal A}}
\def\cB{{\Cal B}}
\def\cC{{\Cal C}}
\def\cD{{\Cal D}}
\def\cE{{\Cal E}}
\def\cF{{\Cal F}}
\def\cI{{\Cal I}}
\def\cJ{{\Cal J}}
\def\cK{{\Cal K}}
\def\cL{{\Cal L}}
\def\cM{{\Cal M}}
\def\cO{{\Cal O}}
\def\cR{{\Cal R}}
\def\cS{{\Cal S}}
\def\cU{{\Cal U}}
\def\cV{{\Cal V}}
\def\cW{{\Cal W}}
\def\cX{{\Cal X}}
\def\cY{{\Cal Y}}

% gothic symbols
\def\ggl{{\goth gl}}
\def\gpgl{{\goth pgl}}
\def\gsl{{\goth sl}}
\def\gm{{\goth m}}

% bf or bfit mathematical characters
\def\bfk{{\bf k}}
\def\bfe{{\bf e}}
\def\bfO{{\bf 0}}
\def\bfa{{\bfit a}}
\def\bfb{{\bfit b}}

% special symbols
%% \def\ii{{\rm i}\,}
\def\\{\hfil\break}
\def\ii{{\rm i}}
\def\ld{,\ldots,}
\def\bu{{\scriptstyle\bullet}}
\def\ort{\mathop{\hbox{\kern1pt\vrule width4pt height0.4pt depth0pt
      \vrule width0.4pt height7pt depth0pt\kern3pt}}}
\def\bigglp#1({\raise-#1\hbox{$\bigg($}}
\def\biggrp#1){\raise-#1\hbox{$\bigg)$}}

%\def\QED{{\hfill$\quad$QED}\medskip}
\def\square{\hbox{%
\vrule height 1.5ex  width 0.1ex  depth 0ex\kern-0.1ex
\vrule height 1.5ex  width 1.5ex  depth -1.4ex\kern-1.5ex
\vrule height 0.1ex  width 1.5ex  depth 0ex\kern-0.1ex
\vrule height 1.5ex  width 0.1ex  depth 0ex}}
\def\qed{\strut~\hfill\square\vskip6pt plus2pt minus1pt}

%\def\semidirect{\mathop{\kern2pt\vrule depth-0.3pt height4.3pt 
%\kern-2pt\times}\nolimits}
\def\hexnbr#1{\ifnum#1<10 \number#1\else
 \ifnum#1=10 A\else\ifnum#1=11 B\else\ifnum#1=12 C\else
 \ifnum#1=13 D\else\ifnum#1=14 E\else\ifnum#1=15 F\fi\fi\fi\fi\fi\fi\fi}
\def\msatype{\hexnbr\msafam}
\def\msbtype{\hexnbr\msbfam}
\mathchardef\restriction="3\msatype16   \let\restr\restriction
\mathchardef\compact="3\msatype62
\mathchardef\complement="0\msatype7B
\mathchardef\smallsetminus="2\msbtype72   \let\ssm\smallsetminus
\mathchardef\subsetneq="3\msbtype28
\mathchardef\supsetneq="3\msbtype29
\mathchardef\leqslant="3\msatype36   \let\le\leqslant
\mathchardef\geqslant="3\msatype3E   \let\ge\geqslant
\mathchardef\ltimes="2\msbtype6E
\mathchardef\rtimes="2\msbtype6F

% hats and tildes and over/underlines
\let\ol=\overline
\let\ul=\underline
\let\wt=\widetilde
\let\wh=\widehat
\def\swt#1|{\smash{\widetilde#1}}
\def\swh#1|{\smash{\widehat#1}}
\def\build#1|#2|#3|{\mathrel{\mathop{\null#1}\limits^{#2}_{#3}}}
\def\buildo#1^#2{\mathrel{\mathop{\null#1}\limits^{#2}}}
\def\buildu#1_#2{\mathrel{\mathop{\null#1}\limits_{#2}}}

% arrows
\let\lra=\longrightarrow
\def\lhra{\lhook\joinrel\longrightarrow}
\mathchardef\rsa"3\msatype20
\def\vlra#1|{\hbox to#1mm{\rightarrowfill}}
\def\vlhra#1|{\lhook\joinrel\hbox to#1mm{\rightarrowfill}}
\let\Llra=\Longleftrightarrow
\def\lraww{\mathrel{\rlap{$\longrightarrow$}\kern-1pt\longrightarrow}}
\def\hdashpiece{\hbox{\vrule height2.45pt depth-2.15pt width2.3pt\kern1.2pt}}
\def\dashto{\mathrel{\hdashpiece\hdashpiece\kern-0.5pt\hbox{\tenmsa K}}}
\def\dasharrow{\mathrel{\hdashpiece\hdashpiece\hdashpiece
    \kern-0.3pt\hbox{\tenmsa K}}}
\def\vdashpiece{\smash{\hbox{\vrule height2.3pt depth0pt width0.3pt}}}
\def\vdashto{\mathrel{\smash{\hbox{\vbox{
  \bgroup\baselineskip=3.5pt
  \vdashpiece\vdashpiece\smash{\raise2pt\hbox{\kern-3.1pt\tenex y}}
  \egroup}}}}}
\def\vdasharrow{\mathrel{\smash{\hbox{\vbox{
  \bgroup\baselineskip=3.5pt
  \vdashpiece\vdashpiece\vdashpiece
  \smash{\raise2pt\hbox{\kern-3.1pt\tenex y}}
  \egroup}}}}}
\catcode`\@=11
\newdimen\@rrowlength \@rrowlength=6ex
\def\ssrelbar{\vrule width\@rrowlength height0.64ex depth-0.56ex\kern-4pt}
\def\llra#1{\@rrowlength=#1\ssrelbar\rightarrow}
\catcode`\@=12

% mathematical operators
\def\lcm{\mathop{\rm lcm}\nolimits}
\def\card{\mathop{\rm card}\nolimits}
\def\Re{\mathop{\rm Re}\nolimits}
\def\Im{\mathop{\rm Im}\nolimits}
\def\Id{\mathop{\rm Id}\nolimits}
\def\Ker{\mathop{\rm Ker}\nolimits}
\def\End{\mathop{\rm End}\nolimits}
\def\Sol{\mathop{\rm Sol}\nolimits}
\def\Hom{\mathop{\rm Hom}\nolimits}
\def\Sym{\mathop{\rm Sym}\nolimits}
\def\SM{\mathop{\rm SM}\nolimits}
\def\Herm{\mathop{\rm Herm}\nolimits}
\def\Aut{\mathop{\rm Aut}\nolimits}
\def\Tr{\mathop{\rm Tr}\nolimits}
\def\GL{\mathop{\rm GL}\nolimits}
\def\PGL{\mathop{\rm PGL}\nolimits}
\def\Alb{\mathop{\rm Alb}\nolimits}
\def\Pic{\mathop{\rm Pic}\nolimits}
\def\Psh{\mathop{\rm Psh}\nolimits}
\def\Proj{\mathop{\rm Proj}\nolimits}
\def\Supp{\mathop{\rm Supp}\nolimits}
\def\Vol{\mathop{\rm Vol}\nolimits}
\def\Ricci{\mathop{\rm Ricci}\nolimits}
\def\Vect{\mathop{\rm Vect}\nolimits}
\def\Span{\mathop{\rm Span}\nolimits}
\def\codim{\mathop{\rm codim}\nolimits}
\def\rank{\mathop{\rm rank}\nolimits}
\def\div{\mathop{\rm div}\nolimits}
\def\ord{\mathop{\rm ord}\nolimits}
\def\mod{\mathop{\rm mod}\nolimits}
\def\pr{\mathop{\rm pr}\nolimits}
\def\Gr{\mathop{\rm Gr}\nolimits}
\def\Ch{\mathop{\rm Ch}\nolimits}
\def\Bs{\mathop{\rm Bs}\nolimits}
\def\dbar{{\overline\partial}}
\def\ddbar{{\partial\overline\partial}}

% subscript and superscript operands
\def\reg{{\rm reg}}
\def\sing{{\rm sing}}
\def\Sing{{\rm Sing}}
\def\orb{{\rm orb}}
\def\std{{\rm std}}
\def\FS{{\rm FS}}
\def\GG{{\rm GG}}
\def\DR{{\rm DR}}
\def\loc{{\rm loc}}
\def\dev{{\rm dev}}
\def\Zar{{\rm Zar}}
\def\Const{{\rm Const}}

% figures inserted as PostScript files

\special{header=/home/demailly/psinputs/mathdraw/mdrlib.ps}
\long\def\InsertFig#1 #2 #3 #4\EndFig{\par
\hbox{\hskip #1mm$\vbox to#2mm{\vfil\special{"
/rotmem where not {(/home/demailly/psinputs/mathdraw/mdrlib.ps) run} if
#3}}#4$}}
\long\def\LabelTeX#1 #2 #3\ELTX{\rlap{\kern#1mm\raise#2mm\hbox{#3}}}

% Main text

\openauxfile

\title{On the existence of logarithmic}
\title{and orbifold jet differentials}

\titlerunning{F.\ Campana, L.\ Darondeau, J.-P.~Demailly, E.\ Rousseau,
orbifold jet differentials}
\bigskip

\centerline{\twelvebf Frédéric Campana, Lionel Darondeau,}\medskip
\centerline{\twelvebf Jean-Pierre Demailly,  Erwan Rousseau}
\vskip50pt

\section{0. Introduction and main definitions}

The present research is concerned with the existence of logarithmic and
orbifold jet differentials on projective varieties. For the sake of generality,
and in view of potential applications to the case of foliations, we work
throughout this paper in the category of directed varieties, and generalize
them by introducing the concept of directed orbifold.

\claim 0.1. Definition|Let $X$ be a complex manifold or variety.
A directed structure $(X,V)$ on $X$ is defined to be a subsheaf
$V\subset\cO(T_X)$ such that
$\cO(T_X)/V$ is torsion free. A~morphism of directed varieties
$\Psi:(X,V)\to (Y,W)$ is a holomorphic map $\Psi:X\to Y$ such that
$d\Psi(V)\subset\Psi^*W$. We say that $(X,V)$ is non singular if
$X$ is non singular and $V$ is locally free, i.e., is a holomorphic
subbundle of $T_X$.
\endclaim

We refer to the {\it absolute case} as being the situation when $V=T_X$,
the {\it relative case} when $V=T_{X/S}$ for some fibration $X\to S$, and
the {\it foliated case} when $V$ is integrable, i.e.\ $[V,V]\subset V$,
that is, $V$ is the tangent sheaf to a holomorphic foliation. We now combine
these concepts with orbifold structures in the sense
of Campana [Cam04].

\claim 0.2. Definition|A directed orbifold is a triple $(X,V,\Delta)$
where $(X,V)$ is a directed variety and $\Delta=\sum(1-{1\over\rho_j})\Delta_j$
an effective real divisor, where $\Delta_j$ is an irreducible
hypersurface and $\rho_j\in{}]1,\infty]$ an associated ``ramification number''.
We denote by $\lceil\Delta\rceil=\sum\Delta_j$ the
corresponding reduced divisor, and by $|\Delta|=\bigcup \Delta_j$ its support.
\vskip2pt
\item{\rm(a)} We will say that $(X,V,\Delta)$ is non singular if
$(X,V)$ is non singular and
$\Delta$ is a simple normal crossing divisor such that $\Delta$ is transverse
to $V$. If $r=\rank(V)$, we mean by this that there are at most $r$ components
$\Delta_j$ meeting at any point $x\in X$, and that for any $p$-tuple
$(j_1,\ldots,j_p)$ of indices, $1\le p\le r$, we have
$\dim V_x\cap \bigcap_{j=1}^pT_{\Delta_{j_\ell},x}=r-p$ at
any point $x\in\bigcap_{j=1}^p\Delta_{j_\ell}$.
\vskip2pt
\item{\rm(b)} If $(X,V,\Delta)$ is non singular, the canonical divisor of
$(X,V,\Delta)$ is defined to be
$$
K_{V,\Delta}=K_V+\Delta
$$
$($in additive notation$)$, where $K_V=\det V^*$.
\vskip2pt
\item{\rm(c)} The so called logarithmic case corresponds to all multiplicities
$\rho_j=\infty$ being taken infi\-nite, so that $\Delta=
\sum\Delta_j=\lceil\Delta\rceil$.\vskip0pt
\endclaim

In case $V=T_X$, we recover the concept of orbifold introduced in
[Cam04], except possibly for the fact that we allow here $\rho_j\in\bR$,
$\rho_j>1$ (even though the case $\rho_j\in\bN^*$ is of greater
interest). It would certainly be interesting to investigate the case
when $(X,V,\Delta)$ is singular, by allowing singularities
in $V$ and tangencies between $V$ and $\Delta$, and to study whether the
results discussed in this paper can be extended in some way, e.g.\ by
introducing suitable multiplier ideal sheaves taking care of singularities,
as was done in [Dem15] for the study of directed varieties $(X,V)$.
For the sake of technical simplicity, we will refrain to do so here, and will
therefore leave for future work the study of singular directed orbifolds.

\claim 0.3. Definition|Let $(X,V,\Delta)$ be a singular directed orbifold.
We say that $f:\bC\to X$ is an orbifold entire curve if $f$ is a non
constant holomorphic map such that$\;:$\vskip2pt
\item{\rm(a)} $f$ is tangent to $V$
$($i.e.\ $f'(t)\in V_{f(t)}$ at every point,
or equivalently $f:(\bC,T_\bC)\to (X,V)$ is a morphism of directed
varieties$\,;$
\vskip2pt
\item{\rm(b)} $f(\bC)$ is not identically contained in $|\Delta|\,;$
\vskip2pt
\item{\rm(c)} at every point $t_0\in\bC$ such that $f(t_0)\in\Delta_j$,
  $f$ meets $\Delta_j$ with ramification number${}\ge\rho_j$, i.e., if
$\Delta_j=\{z_j=0\}$ near $f(t_0)$, then $z_j\circ f(t)$ vanishes with
multiplicity${}\ge\rho_j$ at $t_0$.
\vskip2pt\noindent
In the case of a logarithmic component $\Delta_j$
$(\rho_j=\infty)$, condition {\rm(c)} is to be replaced by the assumption
\vskip2pt
\item{$({\rm c}')$} $f(\bC)$ does not meet~$\Delta_j$.\vskip0pt
\endclaim

\noindent
One can now consider a category of directed orbifolds as follows.

\claim 0.4. Definition|Consider directed orbifolds
$(X,V,\Delta)$, $(Y,W,\Lambda)$ with
$$
\Delta=\sum\Big(1-{1\over\rho_{\Delta,i}}\Big)\Delta_i,\qquad
\Lambda=\sum\Big(1-{1\over\rho_{\Lambda,j}}\Big)\Lambda_j.
$$
A morphism $\Psi:(X,V,\Delta)\to(Y,W,\Lambda)$ is a morphism
$\Psi:(X,V)\to(Y,W)$ of directed varieties satisfying the
additional following  properties {\rm(a,b,c)}.
\vskip2pt
\item{\rm(a)} for every component $\Lambda_j$, $\Psi^{-1}(\Lambda_j)$
consists of a union of components $\Delta_i$, $i\in I(j)$,
eventually after adding a number of extra components $\Delta_i$
with $\rho_{\Delta,i}=1\;;$
\vskip2pt
\item{\rm(b)} in case $\rho_{\Lambda,j}<\infty$, for every $i\in I(j)$
and $z\in\Delta_i$, 
the derivatives $D^\alpha\Psi(z)$ of $\Psi$ at $z$, computed
in suitable local coordinates on $X$ and $Y$, vanish for all multi-indices
$\alpha\in\bN^n$ with $0<|\alpha|<\rho_{\Lambda,j}/\rho_{\Delta,i}\;;$
\vskip2pt
\item{\rm(c)} if $\Lambda_j$ is a logarithmic component
$(\rho_{\Lambda,j}=\infty)$, then $\Phi^{-1}(\Lambda_j)=
\bigcup_{i\in I(j)}\Delta_i$ where the $(\Delta_i)_{i\in I(j)}$
consist of logarithmic components $(\rho_{\Delta,i}=\infty)$.\vskip0pt
\vskip0pt
\endclaim

\noindent
It is easy to check that the composite of directed orbifold morphisms
is actually a directed orbifold morphism, and that the composition
of an orbifold entire curve $f:\bC\to(X,V,\Delta)$ with a
directed orbifold morphism $\Psi:(X,V,\Delta)\to(Y,W,\Lambda)$ 
produces an orbifold entire curve $\Psi\circ f:\bC\to(Y,W,\Lambda)$.
One of our main goals is to investigate the following generalized
Green-Griffiths conjecture

\claim 0.5. Conjecture|Let $(X,V,\Delta)$ be a non singular directed orbifold
of generated type, in the sense that the canonical divisor $K_V+\Delta$
is big. Then then should exist an algebraic subvariety $Y\subsetneq X$
containing all orbifold entire curves $f:\bC\to(X,V,\Delta)$.
\endclaim

\noindent
As in the absolute case ($V=T_X$, $\Delta=0$), the idea is to show, at least
as a first step towards the conjecture, that orbifold entire curves must satisfy
suitable algebraic differential equations. In section~1, we introduce graded
algebras
$$
\bigoplus_{m\in\bN}E_{k,m}V^*\langle\Delta\rangle\leqno(0.6)
$$
of sheaves of ``orbifold jet differentials''. These sheaves correspond to
algebraic differential operators $P(f;f',f'',\ldots,f^{(k)})$ acting on
germs of $k$-jets of curves that are tangent to $V$ and satisfy the
ramification conditions prescribed by~$\Delta$. The strategy relies on the
following standard vanishing theorem.

\claim 0.7. Proposition|Let $(X,V,\Delta)$ be a projective non singular
directed orbifold, and $A$ an ample divisor on $X$. Then, for every
orbifold entire curve $f:\bC\to(X,V,\Delta)$ and every global
jet differential operator $P\in H^0(X,E_{k,m}V^*\langle\Delta\rangle
\otimes\cO_X(-A))$, we have $P(f;f',f'',\ldots,f^{(k)})=0$.
\endclaim

\noindent
The next step consists precisely of finding sufficient conditions that ensure
the existence of many global sections
$P\in H^0(X,E_{k,m}V^*\langle\Delta\rangle\otimes\cO_X(-A))$. In this
direction, among other more general results, we prove

\claim 0.8. Theorem|Let $(X,V,\Delta)$ be a $n$-dimensional
projective non singular directed orbifold. We assume that
$\Delta=(1-{1\over\rho_1})\Delta_1$ has ramification index $\rho_1\ge n+1$,
with a single component $\Delta_1\in|d_1A|$ of degree $d_1$
with respect to a {\rm very ample} divisor $A$ on~$X$.
Then, for $\rho_1\ge n+1$, $\varepsilon\in\bQ_{>0}$ small and
$$
n-1+d_1>
n\,2^{2n-1}\Big(1+{1\over 2}+\cdots+{1\over n}\Big)^n
{\rho_1^n\over{\rho_1-1\choose n}},
$$
there exist many $($i.e.\ at least
$c\,m^{n+n^2-1}$, $c>0)$ orbifold jet differentials of order~$n$~in
$$
H^0(X,E_{n,m}T^*_X\langle\Delta\rangle\otimes\cO_X(-m\varepsilon A))
$$
for $m\gg 1$ sufficiently divisible.
\endclaim

\section{1. Logarithmic and orbifold jet differentials}

\subsection 1.A. Directed varieties and associated jet differentials|

Let $(X,V)$ be a non singular directed variety. We set $n=\dim_\bC X$,
$r=\rank_\bC V$, and following the exposition of [Dem97], we
denote by $\pi_k:J^kV\to X$ the bundle
of $k$-jets of holomorphic curves tangent to
$V$ at each point. The canonical bundle of $V$ is defined to be
$$
K_V=\det(V^*)=\Lambda^rV^*.\leqno(1.1)
$$
If $f:(\bC,0)\to X$, $t\mapsto f(t)$
is a germ of holomorphic curve tangent to $V$, we denote
by $f_{[k]}(0)$ its $k$-jet at ~$t=0$. For $x_0\in X$ given, we take a
coordinate system $(z_1,\ldots,z_n)$ centered at $x_0$ such that
$V_{x_0}=\Span({\partial\over\partial z_\mu})_{1\le \mu\le r}$.
Then there exists a neighborhood $U$ of $x_0$ such that
$V_{|U}$ admits a holomorphic frame $(e_\mu)_{1\le\mu\le r}$ of the form
$$
e_\mu(z)={\partial\over\partial z_\mu}+\sum_{r+1\le \lambda\le n}
a_{\lambda\mu}(z){\partial\over\partial z_\lambda},\quad
1\le\mu\le r,\leqno(1.2)
$$
with $a_{\lambda\mu}(0)=0$. Germs of curves $f:(\bC,0)\to X$ tangent to $V_{|U}$
are obtained by integrating the system of ordinary differential equations
$$
f'_\lambda(t)=\sum_{1\le\mu\le r}a_{\lambda\mu}(f(t))\,f'_\mu(t),\quad
r+1\le \lambda\le n,\leqno(1.3)
$$
when we write $f=(f_1,\ldots,f_n)$ in coordinates. Therefore any such germ of
curve $f$ is uniquely determined by its initial point $z=f(0)$ and its
projection $\tilde f=(f_1,\ldots,f_r)$ on the first $r$ coordinates. By
definition, every $k$-jet $f_{[k]}\in J^kV_z=\pi_k^{-1}(z)$ is
uniquely determined
by its initial point $f(0)=z\simeq(z_1,\ldots,z_n)$ and the Taylor expansion
of order $k$
$$
\tilde f(t)-\tilde f(0)=t\xi_1+{1\over 2!}t^2\xi_2+\cdots+{1\over k!}
t^k\xi_k+O(t^{k+1}),\quad t\in D(0,\varepsilon),~\xi_s\in\bC^r,~1\le s\le k.
\leqno(1.4)
$$
Alternatively, we can pick an arbitrary local holomorphic connection $\nabla$
on $V_{|U}$ and represent the $k$-jet $f_{[k]}(0)$ by
$(\xi_1,\ldots,\xi_k)$, where
$\xi_s=\nabla^sf(0)\in V_z$ is defined inductively 
by $\nabla^1 f=f'$ and $\nabla^sf=\nabla_{f'}(\nabla^{s-1}f)$. This
gives a local biholomorphic trivialization of $J^kV_{|U}$ of the form
$$
J_kV_{|U}\to V_{|U}^{\oplus k},\qquad
f_{[k]}(0)\mapsto(\xi_1,\ldots,\xi_k)=(\nabla f(0),\ldots,\nabla f^k(0))\,;
\leqno(1.5)
$$
the particular choice of the ``trivial connection'' $\nabla_0$ of $V_{|U}$
that turns $(e_\mu)_{1\le\mu\le r}$ into a parallel frame precisely yields the
components $\xi_s\in V_{|U}\simeq\bC^r$ appearing in (1.4). We could of
course also use a $C^\infty$ connection $\nabla=\nabla_0+\Gamma$ where
$\Gamma\in C^\infty(U,T^*_X\otimes\Hom(V,V))$, and
in this case, the corresponding trivialization (1.5) is just a
$C^\infty$ diffeomorphism; the advantage, though, is that we can always
produce such a global $C^\infty$ connection $\nabla$ by using a partition of
unity on~$X$, and then (1.5) becomes a global $C^\infty$ diffeomorphism.
Now, there is a global holomorphic $\bC^*$ action on $J^kV$ given at the level
of germs by $f\mapsto\alpha\cdot f$ where $\alpha\cdot f(t):=f(\alpha t)$,
$\alpha\in\bC^*$. With respect to our trivializations (1.5), this is
the weighted $\bC^*$ action defined by
$$
\alpha\cdot(\xi_1,\xi_2,\ldots,\xi_k)=(\alpha\xi_1,
\alpha^2\xi_2,\ldots,\alpha^k\xi_k),\quad \xi_s\in V.\leqno(1.6)
$$
We see that $J^kV\to X$ is an algebraic fiber bundle
with typical fiber $\bC^{rk}$, and that the projectivized $k$-jet bundle 
$$
X_k(V):=(J^kV\ssm\{0\})/\bC^*,\qquad \pi_k:\smash{X_k(V)}\to X
\leqno(1.7)
$$
is a $\bP(1^{[r]},2^{[r]},\ldots,k^{[r]})$ weighted projective 
bundle over $X$, of total dimension
$$
\dim X_k(V)=n+kr-1.
\leqno(1.8)
$$

\claim 1.9. Definition|We define $\cO_X(E_{k,m} V^*)$ to be the sheaf over
$X$ of holomorphic functions $P(z\,;\,\xi_1,\ldots,\xi_k)$ on $J^kV$ that are
weighted polynomials of degree $m$ in~$(\xi_1,\ldots,\xi_m)$.
\endclaim

\noindent In coordinates and in multi-index notation, we can write
$$
P(z\,;\,\xi_1,\ldots,\xi_k)=
\sum_{\scriptstyle\alpha_1,\ldots,\alpha_k\in\bN^r\atop
\scriptstyle|\alpha_1|+2|\alpha_2|+\cdots+k|\alpha_k|=m}
a_{\alpha_1\ldots\alpha_k}(z)\,\xi_1^{\alpha_1}\ldots\xi_k^{\alpha_k}
$$
where the $a_{\alpha_1\ldots\alpha_k}(z)$ are holomorphic functions
in $z=(z_1,\ldots,z_n)$ and $\xi_s^{\alpha_s}$ actually means
$$
\xi_s^{\alpha_s}=\xi_{s,1}^{\alpha_{s,1}}\ldots\,\xi_{s,r}^{\alpha_{s,r}}\quad
\hbox{for}~~
\xi_s=(\xi_{s,1},\ldots,\xi_{s,r})\in\bC^r,~~
\alpha_s=(\alpha_{s,1},\ldots,\alpha_{s,r})\in\bN^r,
$$
and $|\alpha_s|=\sum_{j=1}^r\alpha_{s,j}$. Such sections can be
interpreted as algebraic differential operators acting on holomorphic
curves $f:D(0,R)\to X$ tangent to $V$, by putting
$P(f):=u$ where
$$
u(t)=\sum_{\scriptstyle\alpha_1,\ldots,\alpha_k\in\bN^r\atop
\scriptstyle|\alpha_1|+2|\alpha_2|+\cdots+k|\alpha_k|=m}
a_{\alpha_1\ldots\alpha_k}(f(t))\;f'(t)^{\alpha_1}\ldots\,f^{(k)}(t)^{\alpha_k}.
\leqno(1.10)
$$
Here $f^{(s)}(t)^{\alpha_s}$ is actually to be expanded as
$$
f^{(s)}(t)^{\alpha_s}=f_1^{(s)}(t)^{\alpha_{s,1}}\ldots\,f_r^{(s)}(t)^{\alpha_{s,r}}
$$
with respect to the components $f_j^{(s)}$ defined in (1.4). We also
set $u=P(f\,;\,f',f'',\ldots,f^{(k)})$ when we want to make more explicit
the dependence of the expression in terms of the derivatives of~$f$.
We thus get a sheaf of graded algebras
$$
\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*).\leqno(1.11)
$$
Locally in coordinates, the algebra is isomorphic
to the weighted polynomial ring
$$
\cO_X\big[f_j^{(s)}\big]_{1\le j\le r,\,1\le s\le k},\quad
\deg f_j^{(s)}=s\leqno(1.12)
$$
over $\cO_X$. An immediate consequence of these definitions is~:

\claim 1.13. proposition|The projectivized bundle $\pi_k:X_k(V)\to X$ can be
identified with 
$$
\Proj\Bigg(\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*)\Bigg)\to X,
\leqno{\rm(a)}
$$
and, if $\cO_{X_k(V)}(m)$ denote the associated tautological sheaves,
we have the direct image formula
$$
(\pi_k)_*\smash{\cO_{X_k(V)}(m)}=\cO_X(E_{k,m} V^*).
\leqno{\rm(b)}
$$
\endclaim

\claim 1.14. Remark|{\rm These
objects where denoted $X_k^\GG$ and $E_{k,m}^\GG V^*$ in our previous
paper [Dem97], as a reference to the work of Green-Griffiths [GG79],
but we will avoid here the superscript GG to
simplify the notation.}
\endclaim

\noindent
Thanks to the Fa\`a di Bruno formula, a change of coordinates $w=\psi(z)$ on
$X$ leads to a transformation rule
$$
(\psi\circ f)^{(k)}=\psi'\circ f\cdot f^{(k)}+Q_\psi(f',\ldots,f^{(k-1})
$$
where $Q_\psi$ is a polynomial of weighted degree $k$ in the lower order
derivatives. This shows that the transformation rule of the top derivative
is linear and, as a consequence, the partial degree in $f^{(k)}$ of
the polynomial $P(f\,;\,f',\ldots,f^{k)})$ is intrinsically defined.
By taking the corresponding filtration and factorizing the monomials
$(f^{(k)})^{\alpha_k}$ with polynomials in $f',f'',\ldots,f^{(k-1)}$,
we get graded pieces
$$
G^\bullet(E_{k,m}V^*)=\bigoplus_{\ell_k\in\bN}
E_{k-1,m-k\ell_k}V^*\otimes S^{\ell_k}V^*.
$$
By considering successively the partial degrees with respect to
$f^{(k)}$, $f^{(k-1)}$, $\ldots\,$, $f'',f'$ and merging inductively
the resulting filtrations, we get a multi-filtration
such that
$$
G^\bullet(E_{k,m}V^*)=\bigoplus_{\ell_1,\ldots,\ell_k\in\bN,\,
\ell_1+2\ell_2+\cdots+k\ell_k=m}S^{\ell_1}V^*\otimes S^{\ell_2}V^*\otimes\cdots
\otimes S^{\ell_k}V^*.\leqno(1.15)
$$

\subsection 1.B. Logarithmic directed varieties|

We now turn ourselves to the logarithmic case. Let $(X,V,\Delta)$ be a
non singular logarithmic variety, where $\Delta=\sum\Delta_j$ is a simple
normal crossing divisor. Fix a point $x_0\in X$. By the assumption that
$\Delta$ is transverse to $V$, we can then select holomorphic coordinates
$(z_1,\ldots,z_n)$ centered at $x_0$ such that
$V_{x_0}=\Span({\partial\over\partial z_j})_{1\le j\le r}$
and $\Delta_j=\{z_j=0\}$, $1\le j\le p$, are the components of $\Delta$
that contain $x_0$ (here $p\le r$ and we can have $p=0$
if $x_0\notin|\Delta|$). What we want is to introduce an algebra of
differential operators, defined locally near $x_0$ as the weighted
polynomial ring
$$
\cO_X\big[(\log f_j)^{(s)}_{1\le j\le p}\,,(f_j^{(s)})_{p+1\le j\le r}
\big]_{1\le s\le k},\quad \deg f_j^{(s)}=\deg(\log f_j)^{(s)}=s,\leqno(1.16)
$$
or equivalently
$$
\cO_X\big[(f_j^{-1}f_j^{(s)})_{1\le j\le p}\,,(f_j^{(s)})_{p+1\le j\le r}
\big]_{1\le s\le k},\quad \deg f_j^{(s)}=s,~\deg f_j^{-1}=0.\leqno(1.16')
$$
For this we notice that
$$
\eqalign{
(\log f_1)''&=(f_1^{-1}f_1')'=f_1^{-1}f_1''-(f_1^{-1}f_1')^2,\cr
\noalign{\vskip4pt}
(\log f_1)'''&=f_1^{-1}f_1'''-3(f_1^{-1}f_1')(f_1^{-1}f_1'')+2
(f_1^{-1}f_1')^3,\ldots\,.\cr}
$$
A similar argument easily shows that the above graded rings do not depend on
the particular choice of coordinates made, as soon as they satisty
$\Delta_j=\{z_j=0\}$.

Now (as is well known in the absolute case $V=T_X$), we have a
corresponding logarithmic directed structure
$V\langle\Delta\rangle$ and its dual $V^*\langle\Delta\rangle$.
If the coordinates $(z_1,\ldots,z_n)$ are
chosen so that $V_{x_0}=\{dz_{r+1}=\ldots=dz_n=0\}$, then
the fiber $V\langle\Delta\rangle_{x_0}$ is spanned by the derivations
$$
z_1{\partial\over\partial z_1},\ldots,z_p{\partial\over\partial z_p},~
{\partial\over\partial z_{p+1}},\ldots,{\partial\over\partial z_r}.
$$
The dual sheaf $\cO_X(V^*\langle\Delta\rangle)$ is the
locally free sheaf generated by
$$
{dz_1\over z_1},\ldots,{dz_p\over z_p},~dz_{p+1},\ldots,dz_r
$$
[where the $1$-forms are considered in restriction to
$\cO_X(V\langle\Delta\rangle)\subset\cO_X(V)\,$]. It follows from this
that $\cO_X(V\langle\Delta\rangle)$ and
$\cO_X(V^*\langle\Delta\rangle)$ are locally free sheaves of rank~$r$.
By taking $\det(V^*\langle\Delta\rangle)$ and using the above generators,
we find
$$
\det(V^*\langle\Delta\rangle)=\det(V^*)\otimes\cO_X(\Delta)=K_V+\Delta
\leqno(1.17)
$$
in additive notation. Quite similarly to 1.13 and 1.15, we have~:

\claim 1.18. Proposition|Let $\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*
\langle\Delta\rangle)$ be the graded algebra defined in coordinates by
$(1.16)$ or $(1.16')$. We define the logarithmic $k$-jet bundle to be
$$
X_k(V\langle\Delta\rangle):=
\Proj\Bigg(\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*\langle\Delta\rangle)\Bigg)\to X.
\leqno{\rm(a)}
$$
If $\cO_{X_k(V\langle\Delta\rangle)}(m)$ denote the
associated tautological sheaves, we get the direct image formula
$$
(\pi_k)_*\smash{\cO_{X_k(V\langle\Delta\rangle)}(m)}=\cO_X(E_{k,m} V^*
\langle\Delta\rangle).\leqno{\rm(b)}
$$
Moreover, the mult-filtration by the partial degrees in the derivatives
$f_j^{(s)}$ has graded pieces
$$
G^\bullet\big(E_{k,m}V^*\langle\Delta\rangle\big)=
\bigoplus_{\ell_1,\ldots,\ell_k\in\bN,\, \ell_1+2\ell_2+\cdots+k\ell_k=m}
S^{\ell_1}V^*\langle\Delta\rangle\otimes
S^{\ell_2}V^*\langle\Delta\rangle\otimes\cdots\otimes
S^{\ell_k}V^*\langle\Delta\rangle.
\leqno{\rm(c)}
$$
\endclaim

\subsection 1.C. Orbifold directed varieties|

We finally consider a non singular directed orbifold $(X,V,\Delta)$,
where $\Delta=\sum(1-{1\over\rho_j})\Delta_j$ is a simple normal crossing
divisor transverse to~$V$. Let $\lceil\Delta\rceil=\sum\Delta_j$ be
the corresponding reduced divisor. By \S$\,$1.B, we have associated
logarithmic sheaves $\cO_X(E_{k,m}V^*\langle\lceil\Delta\rceil\rangle)$.
We want to introduce a graded subalgebra
$$
\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*\langle\Delta\rangle)~~\subset~~
\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*\langle\lceil\Delta\rceil\rangle)
\leqno(1.19)
$$
in such a way that for every germ $P\in \cO_X(E_{k,m}V^*\langle\Delta\rangle)$
and every germ of orbifold curve $f:(\bC,0)\to(X,V,\Delta)$ the germ of
meromorphic function $P(f)(t)$ is bounded at $t=0$ (hence holomorphic).
Assume that $\Delta_1=\{z_1=0\}$ and that $f$ has multiplicity $q\ge \rho_1>1$
along~$\Delta_1$ at $t=0$. Then $f_1^{(s)}$ still vanishes
at order${}\ge(q-s)_+$, thus $(f_1)^{-\beta}f_1^{(s)}$ is bounded as soon
as $\beta q\le(q-s)_+$, i.e.\ $\beta\le(1-{s\over q})_+$. Thus,
it is sufficient to ask that $\beta\le(1-{s\over \rho_1})_+$. At a point
$x_0\in |\Delta_1|\cap\ldots\cap|\Delta_p|$, a sufficient condition
for a monomial of the form
$$
f_1^{-\beta_1}\ldots\,f_p^{-\beta_p}\prod_{s=1}^k\prod_{j=1}^r
(f_j^{(s)})^{\alpha_{s,j}},
\quad
\alpha_s=(\alpha_{s,j})\in\bN^r,~\beta_1,\ldots,\beta_p\in\bN
\leqno(1.20)
$$
to be bounded is to require that the multiplicities of poles satisfy
$$
\beta_j\le\sum_{s=1}^k\alpha_{s,j}\Big(1-{s\over \rho_j}\Big)_+,\quad
1\le j\le p.
\leqno(1.20')
$$
\claim 1.21. Definition|The subalgebra
$\bigoplus_{m\in\bN}\cO_X(E_{k,m}V^*\langle\Delta\rangle)$ is taken to be the
graded ring generated by monomials
$(1.20)$ of degree $\sum s|\alpha_s|=m$, satisfying the pole multiplicity
conditions $(1.20')$. These conditions do not depend on the choice of
coordinates, hence we get a globally and intrinsically defined sheaf
of algebras on~$X$. 
\endclaim

\proof. We only have to prove the last assertion. Consider a change of
variables $w=\psi(z)$ such that $\Delta_j$ can still be expressed as
$\Delta_j=\{w_j=0\}$. Then, for $j=1,\ldots,p$, we can write
$w_j=z_ju_j(z)$ with an invertible holomorphic factor~$u_j$. We need to check
that the monomials~(1.20) computed with $g=\psi\circ f$ are holomorphic
combinations of those associated with $f$. However, we have $g_j=f_ju_j(f)$,
hence $g_j^{(s)}=\sum_{0\le\ell\le s}{s\choose\ell}
f_j^{(\ell)}(u_j(f))^{(s-\ell)}$ by the Leibniz formula, and we see that
$$
g_1^{-\beta_1}\ldots\,g_p^{-\beta_p}\prod_{s=1}^k\prod_{j=1}^r
(g_j^{(s)})^{\alpha_{s,j}}
$$
expands as a linear combination of monomials
$$
f_1^{-\beta_1}\ldots\,f_p^{-\beta_p}\prod_{s=1}^k\prod_{j=1}^r
\prod_{m=1}^{\alpha_{s,j}}f_j^{(\ell_{s,j,m})},\quad \ell_{s,j,m}\le s,
$$
multiplied by holomorphic factors of the form
$$
\prod_{j=1}^pu_j(f)^{-\beta_j}\times
\prod_{s=1}^k\prod_{j=1}^r\prod_{m=1}^{\alpha_{s,j}}(u_j(f))^{(s−\ell_{j,s,m})}.
$$
However, we have
$$
\beta_j\le\sum_{s=1}^k\alpha_{s,j}\Big(1-{s\over \rho_j}\Big)_+
\le\sum_{s=1}^k\sum_{m=1}^{\alpha_{s,j}}
\Big(1-{\ell_{s,j,m}\over \rho_j}\Big)_+,\quad
$$
so the $f$-monomials satisfy again the required multiplicity conditions
for the poles~$f_j^{-\beta_j}$.\qed

\noindent
The above conditions $(1.20')$ suggest to introduce a sequence of
``differentiated'' orbifold divisors
$$
\Delta^{(s)}=\sum_j\bigg(1-{s\over\rho_j}\bigg)_{\kern-3pt+}\Delta_j.
\leqno(1.22)
$$
We say that $\Delta^{(s)}$ is the order $s$ orbifold divisor associated
to~$\Delta\,$; its ramification numbers are $\rho_j^{(s)}=\max(\rho_j/s,1)$.
By definition, the logarithmic components ($\rho_j=\infty$) of
$\Delta$ remain logarithmic in $\Delta^{(s)}$, while all others eventually
disappear when $s$ is large.

Now, we introduce (in a purely formal way) a sheaf of rings
$\smash{\wt\cO}_X=\cO_X[z_j^\bullet]$ by adjoining
all positive real powers of coordinates $z_j$ such that
\hbox{$\Delta_j=\{z_j=0\}$} is locally a component of~$\Delta$.
Locally over~$X$, this can be done by taking the universal cover $Y$ of
a punctured polydisk
$$
D^*(0,r):=\prod_{1\le j\le p}D^*(0,r_j)\times
\prod_{p+1\le j\le n}D(0,r_j)~~\subset~~
D(0,r):=\prod_{1\le j\le n}D(0,r_j)
$$
in the local coordinates $z_j$ on $X$. If $\gamma:Y\to D^*(0,r)
\hookrightarrow X$ is the covering map and $U\subset D(0,r)$ is an open
subset, we can then consider the functions
of~$\smash{\wt\cO}_X(U)$ as being defined on
$\gamma^{-1}(U\cap D^*(0,r))$. In case $X$ is projective,
one can even achieve such a construction globally by taking $Y$ to be
the universal cover of a complement $X\ssm(|\Delta|\cup|\Delta'|)$, where
$\Delta'=\sum\Delta'_\ell$ is a sum of very ample divisors such that
$\Delta+\Delta'$ has simple normal crossings, and $\Delta_j\sim
\Delta'_{\ell_1(j,m)}-\Delta'_{\ell_2(j,m)}$ with $\bigcup_mX\ssm
(\Delta'_{\ell_1(j,m)}\cup\Delta'_{\ell_2(j,m)})=X$ for each $j$.

In this setting,
the subalgebra $\bigoplus_m\cO_X(E_{k,m}V^*\langle\Delta\rangle)$ still has a
multi-filtration induced
by the one on $\bigoplus_m\cO_X(E_{k,m}V^*\langle\lceil\Delta\rceil\rangle)$,
and by extending the structure sheaf $\cO_X$ into $\smash{\wt\cO}_X$, we get
an inclusion
$$
\wt\cO_X(G^\bullet E_{k,m}V^*\langle\Delta\rangle)\subset
\bigoplus_{\ell_1+2\ell_2+\cdots+k\ell_k=m}
\wt\cO_X(S^{\ell_1}V^*\langle\Delta^{(1)})\rangle\otimes \cdots
\otimes\wt\cO_X(S^{\ell_k}V^*\langle\Delta^{(k)}\rangle),
\leqno(1.23)
$$
$\wt\cO_X(V^*\langle\Delta^{(s)}\rangle)$ is the ``$s$-th orbifold
(dual) directed structure'', generated by the order
$s$ differentials
$$
z_j^{-(1-s/\rho_j)_+}d^{(s)}z_j,~~1\le j\le p,~~~d^{(s)}z_j,~~p+1\le j\le r.
\leqno(1.24)
$$
By construction, we have
$$
\det(\wt\cO_X(V^*\langle\Delta^{(s)}\rangle))=\wt\cO_X(K_V+\Delta^{(s)}).
\leqno(1.25)
$$

\claim 1.26. Remark|{\rm When $\rho_j=a_j/b_j\in\bQ_+$, one can 
find a finite ramified Galois cover \hbox{$g:Y\to X$} from a smooth
projective variety $Y$ onto~$X$, such that the compositions
$(z_j\circ g)^{1/a_j}$ become single-valued functions $w_j$ on $Y$.
In this way, the pull-back
$\cO_Y(g^*V^*\langle\Delta^{(s)}\rangle)$ is actually a
locally free $\cO_Y$-module. On can also introduce a sheaf
of algebras which we will denote by
$\bigoplus\cO_Y(E_{k,m}\widetilde V^*\langle\Delta\rangle)$,
generated, according to the notation of \S1.B, by the elements
$g^*(z_j^{(1-s/\rho_j)_+}d^{(s)}z_j)$, $1\le j\le p$, and
$g^*(d^{(s)}z_j)$, $p+1\le j\le r$. Then there is indeed a
multifiltration on $\cO_Y(E_{k,m}\widetilde V^*\langle\Delta\rangle)$
whose graded pieces are
$$
\cO_Y(G^\bu E_{k,m}\widetilde V^*\langle\Delta\rangle)=
\bigoplus_{\ell_1+2\ell_2+\cdots+k\ell_k=m}
\cO_Y(S^{\ell_1}\wt V^*\langle\Delta^{(1)}\rangle)\otimes \cdots
\otimes\cO_Y(S^{\ell_k}\wt V^*\langle\Delta^{(k)}\rangle).
\leqno(1.27)
$$
However, we will adopt here an alternative viewpoint that avoids the
introduction of finite or infinite covers, and suits better our
approach. Using the general philosophy of [Laz??], the idea is
to consider a ``jet orbifold directed
structure'' $X_k(V\langle\Delta\rangle)$ as the underlying
``jet logarithmic directed structure''
$X_k(V\langle\lceil\Delta\rceil\rangle)$, equipped additionally
with a submultiplicative sequence of ideal sheaves
$\cJ_m\langle\Delta\rangle\subset \cO_{X_k(V\langle\lceil\Delta\rceil\rangle)}$.
These are precisely defined as
the base loci ideals of the local sections defined by $(1.20)$ and $(1.20')$,
when these are seen as sections of the logarithmic tautological sheaves
$\cO_{X_k(V\langle\lceil\Delta\rceil\rangle)}(m)$. The corresponding analytic
viewpoint is to consider ad hoc singular
hermitian metrics on $\cO_{X_k(V\langle\lceil\Delta\rceil\rangle)}(1)$ whose
singularities are asymptotically described by the limit of the formal
$m$-th root of $\cJ_m\langle\Delta\rangle$, see \S3.B. It then becomes
possible to deal
without trouble with real coefficients $\rho_j\in{}]1,\infty]$, and
since we no longer have to worry about the existence of Galois covers,
the projectivity assumption on $X$ can be dropped as well.}
\endclaim

\section{2. Preliminaries on holomorphic Morse inequalities}

\subsection 2.A. Basic results|

We first recall the basic results concerning holomorphic Morse inequalities
for smooth hermitian line bundles, first proved in [Dem85].

\claim 2.1. Theorem|Let $X$
be a compact complex  manifolds, $E\to X$ a holomorphic vector bundle of
rank $r$, and $(L,h)$ a hermitian line bundle. We denote by
$\Theta_{L,h}={\ii\over 2\pi}D_h^2=-{\ii\over2\pi}\ddbar\log h$ the curvature
form of $(L,h)$ and introduce the open subsets of $X$
$$
\cases{
X(L,h,q)=\big\{x\in X\,;\;\Theta_{L,h}(x)~\hbox{has signature $(n-q,q)$}\big\},
\cr
\noalign{\vskip5pt}
\displaystyle
X(L,h,S)=\bigcup_{q\in S} X(L,h,q),\quad \forall S\subset\{0,1,\ldots,n\}.\cr}
\leqno(*)
$$
Then, for all $q=0,1,\ldots,n$, the
dimensions $h^q(X,E\otimes L^m)$ of cohomology groups of the tensor powers 
$E\otimes L^m$ satisfy the following ``Strong Morse inequalities''
as $m\to +\infty\,:$
$$\sum_{0\le j\le q} (-1)^{q-j}h^j(X,E\otimes L^m) \le r {m^n\over n!}
\int_{X(L,h,\le q)}(-1)^q\Theta_{L,h}^n+o(m^n),
\leqno\SM(q):$$
with equality
$\chi(X,E\otimes L^m)= r{m^n\over n!}\int_X \Theta_{L,h}^n + o(m^n)$
for the Euler characteristic $(q=n)$.
\endclaim

\noindent
As a consequence, one gets upper and lower bounds for all cohomology
groups, and especially a very useful criterion for the existence of
sections of large multiples of $L$.
\vskip2mm

\claim 2.2. Corollary|Under the above hypotheses, we have
\vskip2pt
\item{\rm(a)} Upper bound for $h^q$ $($Weak Morse inequalities$)\,:$
$$h^q(X,E\otimes L^m)\le r {m^n\over n!}\int_{X(L,h,q)} (-1)^q \Theta_{L,h}^n + o(m^n)~.$$
\vskip2pt
\item{\rm(b)} Lower bound for $h^0\,:$
$$
h^0(X,E\otimes L^m)\ge h^0-h^1\ge
 r{m^n\over n!}\int_{X(L,h,\le 1)}\Theta_{L,h}^n -o(m^n)~.$$
Especially $L$ is big as soon as $\int_{X(L,h,\le 1)}\Theta_{L,h}^n>0$
for some hermitian metric $h$ on~$L$.
\vskip2pt
\item{\rm(c)} Lower bound for $h^q\,:$
$$
h^q(X,E\otimes L^m)\ge h^q-h^{q-1}-h^{q+1}\ge
r{m^n\over n!}\int_{X(L,h,\{q,q\pm 1\})}
(-1)^q \Theta_{L,h}^n + o(m^n)~.$$
\endclaim

\proof. (a) is obtained by taking $\SM(q)+\SM(q\,{-}\,1)$, (b) is equivalent to
$-\SM(1)$ and (c) is equivalent to $-(\SM(q\,{+}\,1)+\SM(q\,{-}\,2))$.\qed

\noindent
The following simple lemma is the key to derive algebraic Morse
inequalities from their analytic form (cf.\ [Dem94], Theorem~12.3).

\claim 2.3.~Lemma|Let $\eta=\alpha-\beta$ be a difference of semipositive 
$(1,1)$-forms on an $n$-dimensional complex manifold~$X$, 
and let $\bOne_{\eta,\le q}$ be the characteristic function of the
open set where $\eta$ is non degenerate with a number of negative eigenvalues 
at most equal to~$q$.
Then
$$
(-1)^q\bOne_{\eta,\le q}~\eta^n\le \sum_{0\le j\le q}(-1)^{q-j}
{n\choose j}\alpha^{n-j}\wedge\beta^j,
$$
in particular
$$
\bOne_{\eta,\le 1}~\eta^n\ge \alpha^n-n\alpha^{n-1}\wedge \beta\qquad\hbox{for $q=1$.}
$$
\endclaim

\proof. Without loss of generality, we can assume $\alpha>0$ positive definite, so that
$\alpha$ can be taken as the base hermitian metric on~$X$. Let us denote by
$$
\lambda_1\ge\lambda_2\ge\ldots\ge\lambda_n\ge 0
$$
the eigenvalues of $\beta$ with respect to $\alpha$. The eigenvalues of $\eta=\alpha-\beta$
are then given by 
$$
1-\lambda_1\le\ldots\le 1-\lambda_q\le 1-\lambda_{q+1}\le\ldots\le 1-\lambda_n,
$$
hence the open set $\{\lambda_{q+1}<1\}$ coincides with the support of 
$\bOne_{\eta,\le q}$, except that it may also contain a part of 
the degeneration set $\eta^n=0$. On the other hand we have
$${n\choose j}\alpha^{n-j}\wedge\beta^j=\sigma_n^j(\lambda)\,\alpha^n,$$
where $\sigma_n^j(\lambda)$ is the $j$-th elementary symmetric function in the $\lambda_j$'s.
Thus, to prove the lemma, we only have to check that
$$\sum_{0\le j\le q}(-1)^{q-j}\sigma_n^j(\lambda)-
\bOne_{\{\lambda_{q+1}<1\}}(-1)^q\prod_{1\le j\le n}(1-\lambda_j)\ge 0.$$
This is easily done by induction on~$n$ (just split apart the parameter
$\lambda_n$ and write $\sigma_n^j(\lambda)=
\sigma_{n-1}^j(\lambda)+\sigma_{n-1}^{j-1}(\lambda)\,\lambda_n$).\qed

\claim 2.4.~Corollary|Assume that $\eta=\Theta_{L,h}$ can be expressed as
a difference $\eta=\alpha-\beta$ of smooth $(1,1)$-forms $\alpha,\beta\ge 0$.
Then we have
$$\sum_{0\le j\le q} (-1)^{q-j}h^j(X,E\otimes L^m) \le r {m^n\over n!}
\int_X\sum_{0\le j\le q}(-1)^{q-j}{n\choose j}\alpha^{n-j}\wedge\beta^j+o(m^n),
\leqno\SM(q):$$
and in particular, for $q=1$,
$$h^0(X,E\otimes L^m)\ge h^0-h^1\ge
r{m^n\over n!}\int_X\alpha^n-n\alpha^{n-1}\wedge\beta+o(m^n).
$$
\endclaim

\claim 2.5. Remark|{\rm These estimates are consequences of Theorem~2.1
and Lemma 2.3, by taking the integral over $X$. The estimate for $h^0$
was stated and studied by Trapani [Tra93]. In the special case
$\alpha=\Theta_{A,h_A}>0$, $\beta=\Theta_{B,h_B}>0$ where $A,B$ are ample
line bundles, a direct proof can be obtained by purely algebraic means,
via the Riemann-Roch formula. However, we will later have to use
Corollary 2.4 in case $\alpha$ and $\beta$ are not closed, a situation in
which no algebraic proof seems to exist.}
\endclaim

\subsection 2.B. Singular holomorphic Morse inequalities|

The case of singular hermitian metrics has been considered
in Bonavero's PhD thesis {\rm [Bon93]} and will be important for~us.
We assume that $L$ is equipped with a singular hermitian metric
$h=h_\infty e^{-\varphi}$ with analytic singularities, i.e.,
$h_\infty$ is a smooth metric, and on an neighborhood
$V\ni x_0$ of an arbitrary point $x_0\in X$, the weight $\varphi$
is of the form $$
\varphi(z)=c\log\sum_{1\le j\le N}|g_j|^2+u(z)
\leqno(2.6)
$$
where $g_j\in\cO_X(V)$ and $u\in C^\infty(V)$. We then have
$\Theta_{L,h}=\alpha+{\ii\over 2\pi}\ddbar\varphi$ where
$\alpha=\Theta_{L,h_\infty}$ is a smooth closed $(1,1)$-form on~$X$.
In this situation, the multiplier ideal sheaves 
$$
\cI(h^m)=\cI(k\varphi)=\big\{f\in\cO_{X,x},\;\;\exists V\ni x,~
\int_V|f(z)|^2e^{-m\varphi(z)}d\lambda(z)<+\infty\big\}\leqno(2.7)
$$
play an important role. We define the singularity set of $h$ by
$\Sing(h)=\Sing(\varphi)=\varphi^{-1}(-\infty)$ which,
by definition, is an analytic subset of $X$. The associated $q$-index sets are
$$
X(L,h,q)=\big\{x\in X\ssm\Sing(h)\,;\;
\Theta_{L,h}(x)~\hbox{has signature $(n-q,q)$}\big\}.
\leqno(2.8)
$$
We can then state:

\claim 2.9. Theorem {\rm([Bon93])}|Morse inequalities still hold in
the context of singular hermitian metric with analytic singularities,
provided the cohomology groups under consideration are twisted by
the appropriate multiplier ideal sheaves, i.e.\ replaced by
$H^q(X,E\otimes L^m\otimes\cI(h^m))$.
\endclaim

\claim 2.10. Remark|{\rm The assumption (2.6) guarantees that the measure
$\bOne_{X\ssm\Sing(h)}(\Theta_{L,h})^n$ is locally integrable on~$X$,
as is easily seen by using the Hironaka desingularization theorem and by
taking a log resolution $\mu:\wt X\to X$ such that $\mu^*(g_j)=(\gamma)\subset
\cO_{\smash{\wt X}}$ becomes a
principal ideal associated with a simple normal crossing divisor
$E=\div(\gamma)$. Then $\mu^*\Theta_{L,h}=
c[E]+\beta$ where $\beta$ is a smooth closed $(1,1)$-form on $\wt X$, hence
$$
\mu^*(\bOne_{X\ssm\Sing(h)}\Theta_{L,h}^n)=\beta^n~~\Rightarrow~~
\int_{X\ssm\Sing(h)}\Theta_{L,h}^n=\int_{\wt X}\beta^n.
$$
It should be observed that the multiplier ideal sheaves $\cI(h^m)$ and the
integral $\int_{X\ssm\Sing(h)}\Theta_{L,h}^n$ only depend on the equivalence
class of singularities of $h\,$: if we have two metrics with analytic
singularities $h_j=h_\infty e^{-\varphi_j}$, $j=1,2$, such that
$\psi=\varphi_2-\varphi_1$ is bounded, then, with the above notation,
we have $\mu^*\Theta_{L,h_j}=c[E]+\beta_j$ and
$\beta_2=\beta_1+{\ii\over 2\pi}\ddbar\psi$, therefore
$\int_{\wt X}\beta_2^n=\int_{\wt X}\beta_1^n$ by Stokes theorem. By using
Monge-Ampère operators in the sense of Bedford-Taylor [BT76], it is in
fact enough to assume $u\in L^\infty_\loc(X)$ in (2.6), and
$\psi\in L^\infty(X)$ here. In general,
however, the Morse integrals $\int_{X(L,h_j,q)}(-1)^q\Theta_{L,h_j}^n$,
$j=1,2$, will~differ.}
\endclaim

\subsection 2.C. Morse inequalities and semi-continuity|
Let $\cX\to S$ be a proper and flat morphism of reduced complex spaces,
and let $(X_t)_{t\in S}$ be the fibers. 
Given a sheaf $\cE$ over $\cX$ of locally free $\cO_\cX$-modules of rank $r$,
inducing on the fibres a family of sheaves $(E_t\to X_t)_{t\in S}$,
the following semicontinuity property holds ([CRAS]):

\claim 2.11. Proposition|For every $q\ge 0$,
the alternate sum 
$$
t\mapsto h^q (X_t,E_t)-h^{ q-1} (X_t,E_t)+. . .+(-1)^q h^0 (X_t,E_t)
$$
is upper semicontinuous with respect to the (analytic) Zariski topology
on~$S$.
\endclaim

Now, if  $\cL\to\cX$ is an invertible sheaf equipped with a smooth
hermitian metric $h$, and if $(h_t)$ are the fiberwise metrics on the
family $(L_t\to X_t)_{t\in S}$, we get
$$
\sum_{j=0}^q(-1)^{q-j}h^j(X_t,E_t\otimes L_t^{\otimes m})
\le
r{m^n\over n!}\int_{X(L_0,h_0,\le q)}
(-1)^q\Theta_{L_0,h_0}^n + \delta(t)m^n,
\leqno(2.12)
$$
where $\delta(t)\to 0$ as $t\to 0$.
In fact, the proof of holomorphic Morse inequalities shows that the
inequality holds uniformly on every relatively compact $S'\compact S$, with
$$
I(t)=\int_{X(L_t,h_t,\le q)}(-1)^q\Theta_{L_t,h_t}^n=
\int_X (-1)^q\bOne_{X(L_t,h_t,\le q)}\Theta_{L_t,h_t}^n
$$
in the right hand side, and $t\mapsto I(t)$ is clearly continuous with
respect to the ordinary topology. In other words, the Morse integral
computed on the central fibers
provides uniform upper bounds for cohomology groups of $E_t\otimes
L_t^{\otimes m}$ when $t$ is close to $0$ in ordinary topology
(and also, as a consequence, for $t$ in a complement
$S\ssm \bigcup S_m$ of at most countably many analytic strata
$S_m\subsetneq S$).

\claim 2.13. Remark|{\rm Similar results would hold when $h$ is a singular
hermitian metric with analytic singularities on $\cL\to\cX$, under
the restriction that the families of multiplier ideal sheaves
$(\cI(h_t^m))_{t\in S}$ ``never jump''.}
\endclaim

\subsection 2.D. Case of filtered bundles|

Let $E\to X$ be a vector bundle over a variety, equipped with a filtration
(or multifiltration) $F^p(E)$, and let $G=\bigoplus G^p(E)\to X$
be the graded bundle associated to this filtration.

\claim 2.14. Lemma|In the above setting, one has for every $q\ge 0$
$$
\sum_{j=0}^q(-1)^{q-j}h^j(X,E)\le\sum_{j=0}^q(-1)^{q-j}h^j(X,G).
$$
\endclaim

\proof. One possible argument is to use the well known fact that
there is a family of filtered bundles $(E_t\to X)_{t\in \bC}$
(with the same graded pieces $G^p(E_t)=G^p(E)$), such
that $E_t\simeq E$ for all $t\neq 0$ and $E_0\simeq G$. The result is then
an immediate consequence of the semi-continuity result~2.11. A more
direct very elementary argument can be given as follows: by transitivity
of inequalities, it is sufficient to prove the result for simple filtrations;
then, by induction on the length of filtrations, it is sufficient to
prove the result for exact sequences $0\to S\to E\to Q\to 0$ of vector
bundles on $X$. Consider the associated (truncated) long exact sequence
in cohomology:
$$
\eqalign{  
0\to H^0(S)\to H^0(E)\to H^0(Q)&\build\to|\delta_1||\cdots\cr
&\build\to|\delta_{q-1}|| H^q(S)\to H^q(E)\to H^q(Q)\build\to|\delta_q||
\Im(\delta_q)\to 0.\cr}
$$
By the rank theorem of linear algebra,
$$
0\le\rank(\delta_q) = (-1)^q\sum_{j=0}^q(-1)^j(h^j(X,Q)- h^j(X,E)+ h^j(X,S)).
$$
The result follows, since here $h^j(X,G)=h^j(X,Q)+h^j(X,S)$.
\qed


\subsection 2.E. Rees deformation construction (after Cadorel)|

In this short paragraph, we outline a nice algebraic interpretation by
Beno\^it Cadorel of certain semi-continuity arguments for cohomology
group dimensions that underline the analytic approach of [Dem11, Lemma~2.12
and Prop.~2.13] and [Dem12, Prop.~9.28] (we will anyway explain again
its essential points in \S3, since we have to deal here with a more
general situation). Recall after [Cad17, Prop.~4.2, Prop.~4.5], that
the Rees deformation construction allows one to construct natural 
deformations of Green-Griffiths jets spaces to weighted projectivized bundles.

Let $(X,V,\Delta)$ be a non singular directed orbifold, and let
$g:Y\to(X,\Delta)$ be an adapted Galois cover, as briefly
described in remark~1.26, see also [CDR18, \S2.1] for more details. We
then get a Green-Griffiths jet bundle of graded algebras
$E_{k,\bullet }\wt V^\star\langle\Delta \rangle\to Y$ which admits a
multifiltration of associated graded algebra
$$
G^\bu E_{k,\bu}\widetilde V^*\langle\Delta\rangle=\bigoplus_{m\in\bN}
\bigoplus_{\ell_1+2\ell_2+\cdots+k\ell_k=m}
S^{\ell_1}\wt V^*\langle\Delta^{(1)}\rangle\otimes \cdots
\otimes S^{\ell_k}\wt V^*\langle\Delta^{(k)}\rangle.
$$
where the tilde means taking  pull-backs by $g^*$.
Applying the Proj functor, one gets a weighted projective bundle:
$$
\bP_{(1,\cdots,k)}\left(
\wt V^*\langle\Delta^{(1)})\rangle\oplus \cdots \oplus
\wt V^*\langle\Delta^{(k)}\rangle \right) =
\Proj\left(G^\bu E_{k,\bu}\widetilde V^*\langle\Delta\rangle\right)
\build\to|\rho_k|| Y,
$$
Then, following mutadis mutandus the arguments of Cadorel, one constructs 
a family $Y\build\leftarrow|p_k||\cY_k\to \bC$ parametrized by $\bC$, with a canonical line bundle $\cO_{\cY_k}(1)$ such that:

\item{$\bu$}
  the central fiber $\cY_{k,0}$ is $\bP_{(1,\cdots,k)}
  \left(
\wt V^*\langle\Delta^{(1)})\rangle\oplus \cdots \oplus
\wt V^*\langle\Delta^{(k)}\rangle \right) $
and the restriction of $\cO_{\cY_k}(1)$ coincide with the canonical
line bundle of this weighted projective bundle.
Hence $(\pi_k)_*\cO_{\cY_{k,0}}(m)= G^\bu E_{k,m}\wt V^*\langle\Delta\rangle$.

\item{$\bu$} the other fibers $\cY_{k,t}$ are isomorphic to the
singular quotient $J^k(Y,\wt V,\Delta)/\bC^*$ for the natural
$\bC^*$-action by homotheties, where $J^k(Y,\wt V,\Delta)$ is the
affine algebraic bundle associated with the sheaf of algebras,
and $(\pi_k)_*\cO_{\cY_{k,t}}(m)\simeq E_{k,m}\wt V^*\langle\Delta\rangle$.
\medskip

\noindent
Applying the semicontinuity result of [Dem95], and working with
holomorphic inequalities, we obtain a control about dimensions of
cohomology spaces of $E_{k,m}\wt V^*\langle\Delta\rangle$ in terms
of dimensions of cohomology spaces of the a priori simpler
graded pieces $G^\bu E_{k,m}\wt V^*\langle\Delta\rangle$.
This reduces the study of higher order jet differentials to
sections of the tautological sheaves on the weighted
projective space associated with a direct sum combination of
symmetric differentials. In particular, we have

\claim 2.15. Lemma|For every $q\in\bN$
$$
\sum_{j=0}^q(-1)^{q-j}h^j(Y,E_{k,m}\wt V^*\langle\Delta\rangle)
\ge
\sum_{j=0}^q(-1)^{q-j}h^j(Y,G^\bu E_{k,m}\wt V^*\langle\Delta\rangle).
$$
Especially, for $q=1$, we get
$$
\eqalign{
h^0(Y,E_{k,m}\wt V^*\langle\Delta\rangle)
&\ge
h^0(Y,E_{k,m}\wt V^*\langle\Delta\rangle)-
h^1(Y,E_{k,m}\wt V^*\langle\Delta\rangle)\cr
&\ge
h^0(Y,G^\bu E_{k,m}\wt V^*\langle\Delta\rangle)-
h^1(Y,G^\bu E_{k,m}\wt V^*\langle\Delta\rangle).\cr}
$$
\endclaim

\section{3. Construction of jet metrics and orbifold jet metrics}

\subsection 3.A. Jet metrics and curvature tensor of jet bundles|

Let $(X,V)$ be a non singular directed variety and $h$ a hermitian metric
on $V$. We assume that $h$ is smooth at this point (but will later relax
a little bit this assumption and allow certain singularities).
Near any given point $z_0\in X$, we can choose local coordinates
$z=(z_1,\ldots,z_n)$ centered at $z_0$ and a local holomorphic coordinate frame
$(e_\lambda(z))_{1\le\lambda\le r}$ of $V$ on an open set $U\ni z_0$, 
such that
$$
\langle e_\lambda(z),e_\mu(z)\rangle_{h(z)} =\delta_{\lambda\mu}+
\sum_{1\le i,j\le n,\,1\le\lambda,\mu\le r}c_{ij\lambda\mu}z_i\overline z_j+
O(|z|^3)\leqno(3.1)
$$
for suitable complex coefficients $(c_{ij\lambda\mu})$. It is a standard fact
that such a normalized coordinate system always exists, and that the 
Chern curvature tensor ${\ii\over 2\pi}\nabla^2_{V,h}$ of $(V,h)$ at $z_0$ 
is given by
$$
\Theta_{V,h}(z_0)=-{\ii\over 2\pi}
\sum_{i,j,\lambda,\mu}
c_{ij\lambda\mu}\,dz_i\wedge d\overline z_j\otimes e_\lambda^*\otimes e_\mu.
\leqno(3.2)
$$
Therefore, $(c_{ij\lambda\mu})$ are the components of $-\Theta_{V,h}$. 
Up to taking the transposed tensor with respect to $\lambda,\mu$, these
coefficients are also the components of the curvature tensor
$\Theta_{V^*,h^*}=-{}^t\Theta_{V,h}$ of the dual bundle $(V^*,h^*)$.
By (1.5), the connection $\nabla=\nabla_h$ yields a $C^\infty$
isomorphism $J_kV\to V^{\oplus k}$. Let us fix an integer $b\in\bN^*$ that 
is a multiple of $\lcm(1,2,\ldots,k)$, and positive numbers
$1=\varepsilon_1\gg\varepsilon_2\gg\cdots\gg \varepsilon_k>0$.
Following [Dem11], we define a global weighted Finsler metric
on $J^kV$ by putting for any $k$-jet $f\in J^kV_z$
$$
\Psi_{h,b,\varepsilon}(f):=\Bigg(
\sum_{1\le s\le k}\varepsilon_s^{2b}\Vert\nabla^s f(0)
\Vert_{h(z)}^{2b/s}\Bigg)^{1/b},
\leqno(3.3)
$$
where $\Vert~~\Vert_{h(z)}$ is the hermitian metric $h$ of $V$ evaluated
on the fiber $V_z$, $z=f(0)$. The function $\Psi_{h,b,\varepsilon}$ satisfies
the fundamental homogeneity property 
$$
\Psi_{h,b,\varepsilon}(\alpha\cdot f)=|\alpha|^2\,\Psi_{h,b,\varepsilon}(f)
\leqno(3.4)
$$
with respect to the $\bC^*$ action on $J^kV$, in other words, it induces
a hermitian metric on the dual $L_k^*$ of the tautological $\bQ$-line bundle
$L_k=\cO_{X_k(V)}(1)$ over $X_k(V)$. The curvature of $L_k$ is given by
$$
\pi_k^*\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}={\ii\over 2\pi}\ddbar
\log\Psi_{h,b,\varepsilon}
\leqno(3.5)
$$
Our next goal is to compute precisely the curvature and to apply
holomorphic Morse inequalities to $L\to X_k(V)$ with the above metric.
This might look a priori like an untractable problem, since the definition of
$\Psi_{h,b,\varepsilon}$ is a rather complicated one, involving the hermitian
metric in an intricate manner. However, the ``miracle''
is that the asymptotic behavior of $\Psi_{h,b,\varepsilon}$ as
$\varepsilon_s/\varepsilon_{s-1}\to 0$ is in some sense uniquely defined,
and ``splits'' according to the natural multifiltration on jet differentials
(as already hinted in \S2.E). This leads to a computable asymptotic
formula, which is moreover simple enough to produce useful results.

\claim 3.6. Lemma|Let us consider the global $C^\infty$ bundle isomorphism
$J^kV\to V^{\oplus k}$ associated with an arbitrary global $C^\infty$ connection
$\nabla$ on $V\to X$, and let us introduce the rescaling transformation 
$$\rho_{\nabla,\varepsilon}(\xi_1,\xi_2,\ldots,\xi_k)=
(\varepsilon_1^1\xi_1,\varepsilon_2^2\xi_2,\ldots,
\varepsilon_k^k\xi_k)\quad
\hbox{on fibers $J^kV_z$, $z\in X$}.
$$
Such a rescaling commutes with the $\bC^*$-action. Moreover, if $p$ is 
a multiple of $\lcm(1,2,\ldots,k)$ and the ratios
$\varepsilon_s/\varepsilon_{s-1}$ tend to~$0$ for all $s=2,\ldots,k$, the
rescaled Finsler metric
\hbox{$\Psi_{h,b,\varepsilon}\circ\rho_{\nabla,\varepsilon}^{-1}
(\xi_1,\ldots,\xi_k)$} converges towards the limit
$$
\bigg(\sum_{1\le s\le k}\Vert \xi_s\Vert^{2b/s}_h\bigg)^{1/b}
$$
on every compact subset of $V^{\oplus k}\ssm\{0\}$,
uniformly in $C^\infty$ topology, and the limit is independent
of the connection~$\nabla$. The error is measured by a multiplicative factor
$1\pm O(\max_{2\le s\le k}(\varepsilon_s/\varepsilon_{s-1})^s)$.
\endclaim

\proof. Let us pick another $C^\infty$ connection $\wt\nabla=
\nabla+\Gamma$ where $\Gamma\in C^\infty(U,T^*_X\otimes
\Hom(V,V))$. Then $\wt\nabla^2f=\nabla^2f+\Gamma(f)(f')\cdot f'$, and
inductively we get
$$
\wt\nabla^sf=\nabla^sf+P_s(f\,;\,\nabla^1f,\ldots,\nabla^{s-1}f)
$$
where $P(z\,;\,\xi_1,\ldots,\xi_{s-1})$ is a polynomial with $C^\infty$
coefficients in $z\in U$, which is of weighted homogeneous degree
$s$ in $(\xi_1,\ldots,\xi_{s-1})$. In other words, the corresponding 
isomorphisms  $J^kV\simeq V^{\oplus k}$ correspond to each other
by a $\bC^*$-homogeneous transformation $(\xi_1,\ldots,\xi_k)\mapsto
(\wt\xi_1,\ldots,\wt\xi_k)$ such that
$$
\wt\xi_s=\xi_s+P_s(z\,;\,\xi_1,\ldots,\xi_{s-1}).
$$
Let us introduce the corresponding rescaled components
$$
(\xi_{1,\varepsilon},\ldots,\xi_{k,\varepsilon})=
(\varepsilon_1^1\xi_1,\ldots,\varepsilon_k^k\xi_k),\qquad
(\wt\xi_{1,\varepsilon},\ldots,\wt\xi_{k,\varepsilon})=
(\varepsilon_1^1\wt\xi_1,\ldots,\varepsilon_k^k\wt\xi_k).
$$
Then
$$
\eqalign{
\wt\xi_{s,\varepsilon}
&=\xi_{s,\varepsilon}+
\varepsilon_s^s\,P_s(x\,;\,\varepsilon_1^{-1}\xi_{1,\varepsilon},\ldots,
\varepsilon_{s-1}^{-(s-1)}\xi_{s-1,\varepsilon})\cr
&=\xi_{s,\varepsilon}+O(\varepsilon_s/\varepsilon_{s-1})^s\,
O(\Vert\xi_{1,\varepsilon}\Vert+\cdots+\Vert\xi_{s-1,\varepsilon}
\Vert^{1/(s-1)})^s\cr}
$$
and it is easily seen, as a simple consequence of the mean value inequality
$|\Vert x\Vert^\gamma-\Vert y\Vert^\gamma|\le\gamma\sup_{z\in[x,y]}
\Vert z\Vert^{\gamma-1}\Vert x-y\Vert$, that
the ``error term'' in the difference
$\Vert\wt\xi_{s,\varepsilon}\Vert^{2b/s}-\Vert\xi_{s,\varepsilon}\Vert^{2b/s}$
is bounded by
$$
(\varepsilon_s/\varepsilon_{s-1})^s\,
\big(\Vert\xi_{1,\varepsilon}\Vert+\cdots+
\Vert\xi_{s-1,\varepsilon}\Vert^{1/(s-1)}+
\Vert\xi_{s,\varepsilon}\Vert^{1/s}\big)^{2b}.
$$
When $b/s$ is an integer, similar bounds hold for all
derivatives $D_{z,\xi}^\beta(\Vert\wt\xi_{s,\varepsilon}\Vert^{2b/s}-
\Vert\xi_{s,\varepsilon}\Vert^{2b/s})$ and the lemma follows.\qed

Now, we fix a point $z_0\in X$, a local holomorphic frame 
$(e_\lambda(z))_{1\le\lambda\le r}$ satisfying (3.1) on a neighborhood $U$ 
of~$z_0$, and the {\it holomorphic} connection $\nabla$ on $V_{|U}$ such that
$\nabla e_\lambda=0$. Since the uniform estimates of Lemma~3.6 also apply
locally (provided they are applied on a relatively compact open
subset $U'\compact U$), we can use the corresponding holomorphic
trivialization $J^kV_{|U}\simeq V_{|U}^{\oplus k}\simeq U\times(\bC^r)^{\oplus k}$
to make our calculations. We do this in terms of the rescaled components 
$\xi_s=\varepsilon_s^s\nabla^sf(0)$. Then, uniformly on compact subsets
of $J^kV_{|U}\ssm\{0\}$, we have
$$
\Psi_{h,b,\varepsilon}\circ\rho_{\nabla,\varepsilon}^{-1}(z\,;\,\xi_1,\ldots,\xi_k)
=\bigg(\sum_{1\le s\le k}\Vert\xi_s\Vert^{2b/s}_{h(z)}\bigg)^{1/b}
+O(\max((\varepsilon_s/\varepsilon_{s-1})^{1/b}),
$$
and the error term remains of the same magnitude when we take
any derivative $D_{z,\xi}^\beta$. By (3.1) we find
$$
\Vert \xi_s\Vert_{h(z)}^2=
\sum_\lambda|\xi_{s,\lambda}|^2+
\sum_{i,j,\lambda,\mu}c_{ij\lambda\mu}\,z_i\overline z_j
\,\xi_{s,\lambda}\overline \xi_{s,\mu}+O(|z|^3|\xi|^2).
$$
The question is thus reduced to evaluating the curvature of the weighted
Finsler metric on $V^{\oplus k}$ defined by
$$
\eqalign{
\Psi(z\,;\,\xi_1,\ldots,\xi_k)
&=\bigg(\sum_{1\le s\le k}\Vert\xi_s\Vert^{2b/s}_{h(z)}\bigg)^{1/b}\cr
&=\bigg(\sum_{1\le s\le k}\Big(\sum_\lambda|\xi_{s,\lambda}|^2+
\sum_{i,j,\lambda,\mu}c_{ij\lambda\mu}\,z_i\overline z_j\,
\xi_{s,\lambda}\overline\xi_{s,\mu}\Big)^{b/s}\bigg)^{1/b}+O(|z|^3).\cr}
$$
We set $|\xi_s|^2=\sum_\lambda|\xi_{s,\lambda}|^2$. A straightforward 
calculation yields the Taylor expansion
$$
\eqalign{
&\log\Psi(z\,;\,\xi_1,\ldots,\xi_k)\cr
&~~{}={1\over b}\log\sum_{1\le s\le k}|\xi_s|^{2b/s}+
\sum_{1\le s\le k}{1\over s}\,{|\xi_s|^{2b/s}\over \sum_t|\xi_t|^{2b/t}}
\sum_{i,j,\lambda,\mu}c_{ij\lambda\mu}z_i\overline z_j
{\xi_{s,\lambda}\overline\xi_{s,\mu}\over|\xi_s|^2}+O(|z|^3).\cr}
$$
By (3.5), the curvature form of $L_k=\cO_{X_k(V)}(1)$ 
is given at the central point $z_0$ by the formula
$$
\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}(z_0,[\xi])\simeq
\omega_{r,k,b}(\xi)+{\ii\over 2\pi}
\sum_{1\le s\le k}{1\over s}\,{|\xi_s|^{2b/s}\over \sum_t|\xi_t|^{2b/t}}
\sum_{i,j,\lambda,\mu}c_{ij\lambda\mu}
{\xi_{s,\lambda}\overline\xi_{s,\mu}\over|\xi_s|^2}\,dz_i\wedge d\overline z_j
\leqno(3.7)
$$
where $[\xi]=[\xi_1,\ldots,\xi_k ]\in\bP(1^{[r]},2^{[r]},\ldots,k^{[r]})$ and
$\omega_{r,k,b}(\xi)={\ii\over 2\pi}\ddbar({1\over b}\log\sum_{1\le s\le k}
|\xi_s|^{2b/s})$. The fibers $\bP(1^{[r]},2^{[r]},\ldots,k^{[r]})$ of
$X_k(V)\to X$ can be represented as a quotient of the
``weighted ellipsoid'' $\sum_{s=1}^k|\xi_s|^{2b/s}=1$ by the $\bS^1$-action
induced by the weighted $\bC^*$-action. This suggests to make use of
polar coordinates and to set
$$
\leqalignno{
  &x_s=|\xi_s|^{2b/s},\quad x=(x_1,\ldots,x_k)\in\bR^k,&(3.8)\cr
  &u_s={\xi_s\over |\xi_s|}\in \bS^{2r-1}\subset\bC^r,\quad
  u=(u_1,\ldots,u_k)\in(\bS^{2r-1})^k,&(3.8')\cr }
$$
so that
$$
\sum_{s=1}^kx_s=1\quad\hbox{and}\quad \xi_s=x_s^{s/2b}u_s.\kern102pt
\leqno(3.8'')
$$
The Morse integrals will then have to be computed for
$(x,u)\in\bDelta^{k−1}\times(\bS^{2r−1})^k$, where
$\bDelta^{k−1}\subset\bR^k$ is the $(k−1)$-dimensional simplex.

\claim 3.9. Proposition| With respect to the rescaled components
$\xi_s=\varepsilon_s^s\nabla^sf(0)$ at $z=f(0)\in X$ and the above
choice of coordinates $(3.8^*)$, we have an approximate expression
$$
\leqno\displaystyle{\rm(a)}\quad
\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}(z,[\xi])=
\omega_{r,k,b}(\xi)+g_{V,k}(z,x,u)+\hbox{\rm(error terms)},
$$
where $(x,u)\in\bDelta^{k−1}\times (\bS^{2r−1})^k$, $\xi_s=x_s^{s/2b}u_s\in\bC^r$,
$$
\leqno\displaystyle{\rm (b)}\quad
\omega_{r,k,b}(\xi)={\ii\over 2\pi}\ddbar\bigg(
{1\over b}\sum_{1\le s\le k}|\xi_s|^{2b/s}\bigg)
$$
is a $($slightly degenerate$)$ Fubini-Study K\"ahler type metric on
$\bP(1^{[r]},2^{[r]},\ldots,k^{[r]})$, associated with the canonical
$\bC^*$ action on $J^kV$ of weight $a=(1^{[r]},2^{[r]},\ldots,k^{[r]})$, and
$$
\leqno\displaystyle{\rm (c)}\quad
g_{V,k}(z,x,u)={\ii\over 2\pi}\sum_{1\le s\le k}{x_s\over s}
\sum_{i,j,\lambda,\mu}c_{ij\lambda\mu}(z)\,
u_{s,\lambda}\overline u_{s,\mu}\,dz_i\wedge d\overline z_j.
$$
Here $(c_{ij\lambda\mu})$ are the coefficients of $-\Theta_{V,h}$, and 
the error terms admit an upper bound
$$
\leqno\displaystyle{\rm (d)}\quad
\hbox{\rm(error terms)}\le
O\Big(\max_{2\le s\le k}(\varepsilon_s/\varepsilon_{s-1})^s\Big)\quad
\hbox{uniformly on the compact variety~$X_k(V)$}.
$$
\endclaim

\proof. The error terms on $\Theta_{L_k}$ come from the differentiation of
the error terms on the Finsler metric, found in Lemma 3.6. They can indeed
be differentiated if $b$ is a multiple of $\lcm(1,2,\ldots,k)$, since
$2b/s$ is then an even integer.\qed

\noindent
For the calculation of Morse integrals, it is useful to find the expression
of the volume form $\omega_{r,k,b}^{kr−1}$ on
$\bP(1^{[r]},2^{[r]},\ldots,k^{[r]}) = (\bDelta^{k−1}\times (\bS^{2r−1})^k)/\bS^1$
in terms of the coordinates $(x,u)$. We refer to [Dem11, Prop.~1.13]
for the proof.

\claim 3.10. Proposition|
\item{\rm(a)} The volume form $\omega_{r,k,b}^{kr−1}$ is the quotient of the
measure ${1\over(k!)^r}\nu_{k,r}\otimes\mu$ on $\bDelta^{k−1}\times
(\bS^{2r−1})^k$,
where  
$$
d\nu_{k,r}(x)=(kr-1)!{(x_1\ldots\,x_k) ^{r-1}\over (r-1)!\,{}^k}
dx_1\wedge\ldots\wedge dx_{k-1},\quad
d\mu(u)=d\mu_1(u_1)\ldots d\mu_k(u_k)
$$
are probability measures on $\bDelta^{k-1}$ and $(\bS^{2r-1})^k$ respectively
$(\mu$ being the rotation invariant one$)$.
\vskip2pt
\item{\rm(b)} We have the equality~
$\displaystyle
\int_{\bP(1^{[r]},2^{[r]},\ldots,k^{[r]})}\omega_{r,k,b}^{kr-1}={1\over (k!)^r}$~
$($independent of~$b)$.
\endclaim

%% By elementary integrations by parts and induction on 
%% $k,\,r_1,\ldots,r_k$, it can be checked that
%% $$
%% \int_{x\in\bDelta^{k-1}}
%% \prod_{1\le s\le k}x_s^{r_s-1}dx_1\ldots dx_{k-1}
%% ={1\over (|r|-1)!}\prod_{1\le s\le k}(r_s-1)!~.
%% \leqno(1.20)
%% $$
%% This implies that $(|r|-1)!\prod_{1\le s\le k}
%% {x_s^{r_s-1}\over(r_s-1)!}\,dx$ is a probability measure on $\bDelta^{k-1}$.

\subsection \S3.B. Logarithmic and orbifold jet metrics|

Consider now an arbifold directed structure $(X,V,\Delta)$, where
$V\subset T_X$ is a subbundle, $r=\rank(V)$, and
$\Delta=\sum(1-{1\over \rho_j})\Delta_j$ is
a normal crossing divisor that is assumed to intersect $V$ transversally
everywhere. One then performs very similar calculations to what we did in
\S3.A, but with adapted Finsler metrics.
Fix a point $z_0$ at which $p$ components $\Delta_j$ meet, and use coordinates
$(z_1,\ldots,z_n)$ such that $V_{z_0}$ is spanned by
$({\partial\over\partial z_1},\ldots,{\partial\over\partial z_r})$
and $\Delta_j$ is defined by $z_j=0$, $1\le j\le p\le r$.
In the logarithmic case $\rho_j=\infty$, the logarithmic dual bundle
$\cO(V^*\langle\Delta\rangle)$ is spanned by
$$
{dz_1\over z_1},\ldots,{dz_p\over z_p},~dz_{p+1},\ldots,dz_n.
$$
The logarithmic jet differentials are just polynomials in
$$
{d^sz_1\over z_1},\ldots,{d^sz_p\over z_p},~d^sz_{p+1},\ldots,d^sz_n,\quad
1\le s\le k,
$$
and the corresponding $(\varepsilon_1,\ldots,\varepsilon_k)$-rescaled
Finsler metric is
$$
\Bigg(\sum_{s=1}^k\varepsilon_s^{2b}\bigg(\sum_{j=1}^p
|f_j|^{-2}|f_j^{(s)}|^2+\sum_{j=p+1}^r|f_j^{(s)}|^2\bigg)^{2b/s}\Bigg)^{1/b}.
\leqno(3.11)
$$
Alternatively, we could replace $|f_j|^{-2}|f_j^{(s)}|^2$ by
$|(\log f_j)^{(s)}|^2$ which has the same leading term and differs by
a weighted degree $s$ polynomial in the $f_j^{-1}f_j^{(\ell)}$,
$\ell<s\,$; an argument very similar to the one used in the
proof of Lemma 3.6 then shows that the difference is negligible
when $\varepsilon_1\gg \varepsilon_2\gg \cdots\gg\varepsilon_k$.
However (3.11) is just the case of the model metric, in fact we get
$r$-tuples $\xi_s=(\xi_{s,j})_{1\le j\le r}$ of components produced
by the trivialization of the logarithmic bundle
$\cO(V\langle\Delta\rangle)$, such that
$$
\xi_{s,j}=f_j^{-1}f_j^{(s)}\quad\hbox{for $1\le s\le p$ and}\quad
\xi_{s,j}=f_j^{(s)}\quad\hbox{for $p+1\le s\le r$}.\leqno(3.12)
$$
In general, we are led
to consider Finsler metrics of the form
$$
\Bigg(\sum_{s=1}^k\varepsilon_s^{2b}\Vert\xi_s\Vert_{h(z)}^{2b/s}\Bigg)^{1/b},
\quad\xi_s=(\xi_{s,j})_{1\le j\le r},
\leqno(3.13)
$$
where $h(z)$ is a variable hermitian metric on the logarithmic bundle
$V\langle\Delta\rangle$.
In the orbifold case, the appropriate ``model'' Finsler metric is
$$
\Bigg(\sum_{s=1}^k\varepsilon_s^{2b}\bigg(\sum_{j=1}^p
|f_j|^{-2(1-s/\rho_j)_+}|f_j^{(s)}|^2+\sum_{j=p+1}^r|f_j^{(s)}|^2\bigg)^{2b/s}\Bigg)^{1/b}.
\leqno(3.14)
$$
As a consequence of Remark~2.10, we would get a metric with equivalent
singularities on the dual $L_k^*$ of the tautological sheaf
$L_k=\cO_{X_k(V\langle\Delta\rangle)}(1)$ by replacing
$\sum_{j=p+1}^r|f_j^{(s)}|^2$ with $\sum_{j=1}^r|f_j^{(s)}|^2$ (or by
any smooth hermitian norm $h$ on $V$), since the extra terms
$\sum_{j=1}^p|f_j^{(s)}|^2$ are anyway controlled by the ``orbifold part''
of the summation. Of course, we need to find a suitable Finsler metric
that is globally defined on $X$. This can be done by taking smooth
metrics $h_{V,s}$ on $V$ and $h_j$ on $\cO_X(\Delta_j)$ respectively, as
well as smooth connections $\nabla$ and $\nabla_j$. One can then
consider the globally defined metric
$$
\Bigg(\sum_{s=1}^k\varepsilon_s^{2b}\bigg(\sum_j
\Vert\sigma_j(f)\Vert_{h_j}^{-2(1-s/\rho_j)_+}
\Vert\nabla_j^{(s)}(\sigma_j\circ f)\Vert_{h_j}^2
+\Vert\nabla^{(s)}f\Vert_{h_{V,s}}^2\bigg)^{2b/s}\Bigg)^{1/b}
\leqno(3.15)
$$
where $\Delta=\sum(1-{1\over\rho_j})\Delta_j$ and
$\sigma_j\in H^0(X,\cO_X(\Delta_j))$ are the tautological sections; here,
we want the flexibility of not necessarily taking the same hermitian metrics
on $V$ to evaluate the various norms $\Vert\nabla^{(s)}f\Vert_{h_{V,s}}$.
We obtain Finsler metrics with equivalent singularities by just changing the
$h_{V,s}$ and $h_j$ (and keeping $\nabla$, $\nabla_j$ unchanged). If
we also change the connections, then an argument very similar to the
one used in the proof of Lemma~3.6 shows that the ratio of the
corresponding metrics is
$1\pm O(\max(\varepsilon_s/\varepsilon_{s-1}))$, and therefore
arbitrary close to $1$ whenever
$\varepsilon_1\gg\varepsilon_2\gg \cdots\gg\varepsilon_k$; in~any
case, we get metrics with equivalent singularities. Fix $z_0\in X$ and
use coordinates $(z_1,\ldots,z_n)$ as described at the beginning of
\S3.B, so that $\sigma_j(z)=z_j$, $1\le j\le p$, in a suitable
trivialization of $\cO_X(\Delta_j)$. Let $f$ be a $k$-jet of curve
such that $f(0)=z\in X\ssm|\Delta|$ is in a sufficiently small
neighborhood of $z_0$. By employing the trivial connections
associated with the above coordinates, the derivative $f^{(s)}$
is described by components
$$
\xi_{s,j}=f_j^{(s)},~~1\le j\le r,\quad
\xi^{\log}_{s,j}=f_j^{-1}f_j^{(s)},\quad
\xi^\orb_{s,j}=f_j^{-(1-s/\rho_j)_+}f_j^{(s)},\quad 1\le j\le p,
$$
and $\xi^\orb_{s,j}=\xi^{\log}_{s,j}=\xi_{s,j}$ for $p+1\le j\le r$.
Here $\xi^\orb_{s,j}$ are to be thought of as the components of $f^{(s)}$
in the ``virtual'' vector bundle $V\langle\Delta^{(s)}\rangle$, and the fact
that the argument of these complex numbers is not uniquely defined is
irrelevant, because the only thing we need to compute the norms
is~$|\xi^\orb_{s,j}|$. Accordingly, for
$v\in V_z$, $v\simeq(v_j)_{1\le j\le r}\in\bC^r$, we
put
$$
v^{\log}_j=z_j^{-1}v_j=\sigma_j(z)^{-1}d\sigma_j(v)\quad\hbox{and}\quad
v^\orb_j=z_j^{-(1-s/\rho_j)_+}v_j,~~1\le j\le p,
$$
and define the orbifold hermitian norm on $V\langle\Delta^{(s)}\rangle$
associated with $h_j$ and $h_{V,s}$ by
$$
\leqalignno{
\Vert v^\orb\Vert_{\wt h_s}{\kern-3pt}^2&=\sum_{j=1}^p
\Vert\sigma_j(z)\Vert_{h_j}^{-2(1-s/\rho_j)_+)}
\Vert d\sigma_j(v)\Vert_{h_j}^2+\Vert v\Vert_{h_{V,s}}^2&(3.16)\cr
&=\sum_{j=1}^p
\Vert\sigma_j(z)\Vert_{h_j}^{2(1-(1-s/\rho_j)_+)}|v_j^{\log}|^2
+\Vert v\Vert_{h_{V,s}}^2
&(3.16')\cr
&=\sum_{j=1}^p\Vert v_j^\orb\Vert_{h_j^{1-(1-s/\rho_j)_+}}^2
+\Vert v\Vert_{h_{V,s}}^2.
&(3.16'')
\cr}
$$
With this notation, the orbifold Finsler metric (3.15) on $k$-jets
is reduced to an expression
$$
\Vert\xi^\orb\Vert_{\Psi_{h,b,\varepsilon}}^{\,2\phantom{\big|}}=
\Bigg(\sum_{s=1}^k\varepsilon_s^{2b}\Vert\xi_s^\orb
\Vert_{\wt h_s}^{2b/s}\Bigg)^{1/b},
\quad\xi_s^\orb=(\xi_{s,j}^\orb)_{1\le j\le r}\,,~~
\xi^\orb=(\xi_s^\orb)_{1\le s\le k}\,,
\leqno(3.17)
$$
formally identical to what we had in the compact or logarithmic cases. If
$v$ is a local holomorphic section of $\cO_X(V)$, formula (3.16) shows that
the norm
$\Vert v^\orb\Vert_{\wt h_s}$ can take infinite values when $z\in|\Delta|$,
while, by $(3.16')$, the norm is always bounded (but slightly degenerate along
$|\Delta|$) if $v$ is a section of the logarithmic sheaf
$\cO_X(V\langle\lceil\Delta\rceil\rangle)$; we think intuitively of the
orbifold total space $V\langle\Delta^{(s)}\rangle$ as the subspace of $V$
in which the tubular neighborhoods of the zero section are
defined by $\Vert v^\orb\Vert_{\wt h_s}<\varepsilon$ for $\varepsilon>0$.

\claim 3.18. Remark|{\rm When $\rho_j\in\bQ$, we can take an adapted
Galois cover $g:Y\to X$ such that $(z_j\circ g)^{1-(1-s/\rho_j)_+}$
is univalent on $Y$ for all components $\Delta_j$ involved, and
we then get a well defined locally free
sheaf $\cO_Y\big(g^*V\langle\Delta^{(s)})$ such that
$$
g^*\big(\cO_X(V\langle\lceil\Delta\rceil\rangle)\big)\subset
\cO_Y\big(g^*V\langle\Delta^{(s)}\rangle\big)\subset 
g^*\big(\cO_X(V)\big).
$$
However, as already stressed in Remark 1.26, this viewpoint is
not needed in our analytic approach.}
\endclaim

\subsection 3.C. Orbifold tautological sheaves and their curvature|

In this context, we define the orbifold tautological sheaves
$$
\cO_{X_k(V\langle\Delta\rangle)}(m):=
\cO_{X_k(V\langle\lceil\Delta\rceil\rangle)}(m)\otimes
\cI((\Psi_{k,b,\varepsilon}^*)^m)
\leqno(3.19)
$$
to be the logarithmic tautological sheaves
$\cO_{X_k(V\langle\lceil\Delta\rceil\rangle)}(m)$ 
twisted by the multiplier ideal sheaves associated
with the dual metric $\Psi_{k,b,\varepsilon}^*$ (cf.\ (3.17)),
when these are viewed
as singular hermitian metrics over the logarithmic $k$-jet bundle
$X_k(V\langle\lceil\Delta\rceil\rangle)$. In accordance
with this viewpoint, we simply define the orbifold $k$-jet bundle to be
$X_k(V\langle\Delta\rangle)=X_k(V\langle\lceil\Delta\rceil\rangle)$.
The calculation of the curvature tensor is formally the same as in
the case $\Delta=0$, and we obtain~:

\claim 3.20. Proposition| With respect to the $($rescaled$\,)$
orbifold $k$-jet components
$$
\xi_{s,\lambda}=\varepsilon_s^sf_\lambda^{(1-(1-\rho_\lambda/s)_+)}
f_\lambda^{(s)}(0),~~1\le\lambda\le p,\quad\hbox{and}\quad
\xi_{s,\lambda}=\varepsilon_s^sf_\lambda^{(s)}(0),~~
p+1\le\lambda\le r,
$$
and of the dual metric $\Psi^*_{h,b,\varepsilon}$, the curvature form of the
tautological sheaf $L_k=\cO_{X_k(V\langle\Delta\rangle)}(1)$ admits
at any point $(z,[\xi])\in X_k(V\langle\Delta\rangle)$
an approximate expression
$$
\leqno\displaystyle{\rm(a)}\quad
\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}(z,[\xi])\simeq
\omega_{r,k,b}(\xi)+g_{V,\Delta,k}(z,x,u),
$$
where $x_s=|\xi_s|^{2b/s}$, $u_s={\xi_s\over|\xi_s|}\in \bS^{2r-1}$ are polar
coordinates associated with $\xi_s=(\xi_{s,\lambda})_{1\le\lambda\le k}$
in~$\bC^r$, $x=(x_1,\ldots,x_k)\in\bDelta^{k-1}$,
$[\xi]=[\xi_1,\ldots,\xi_k]\in\bP(1^{[r]},2^{[r]},\ldots,k^{[r]})$ and
$$
\leqno\displaystyle{\rm(b)}\quad
g_{V,\Delta,k}(z,x,u)={\ii\over 2\pi}
\sum_{1\le s\le k}{x_s\over s}\sum_{i,j,\lambda,\mu}c^{(s)}_{ij\lambda\mu}(z)\,
u_{s,\lambda}\overline u_{s,\mu}\,dz_i\wedge d\overline z_j.
$$
Here $(c^{(s)}_{ij\lambda\mu})$ are the coefficients of
the curvature tensor $-\Theta_{V\langle\Delta^{(s)}\rangle,\wt h_s}$, and the
error terms  are
$O(\max_{2\le s\le k}(\varepsilon_s/\varepsilon_{s-1})^s)$, uniformly on
the projectivized orbifold variety~$X_k(V\langle\Delta\rangle)$.
\endclaim

\noindent
Notice, as is clear from the expressions $(3.16'')$, (3.17) and the fact that
$v_j=z_jv^\orb_j$, that our orbifold Finsler metrics always have
fiberwise positive curvature, equal to $\omega_{k,r,b}(\xi)$, along
the fibers of $X_k(V\langle\Delta\rangle)\to X$ (even after taking into
account the so-called error terms, because fiberwise, the functions
under consideration are just sums of even powers $|\wt\xi_s^\orb|^{2b/s}$
in suitable $k$-jet components, and are therefore plurisubharmonic.)

\section{4. Existence theorems for jet differentials}

\subsection 4.A. Expression of the Morse integral|

Thanks to the uniform approximation provided by proposition 3.20,
we can (and will) neglect the $O(\varepsilon_s/\varepsilon_{s-1})$ error
terms in our calculations. Since $\omega_{r,k,b}$ is positive definite on
the fibers of $X_k(V\langle\Delta\rangle)\to X$ (at least outside of
the axes $\xi_s=0$), the index of the $(1,1)$ curvature form
$\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}(z,[\xi])$ is equal to the index
of the $(1,1)$-form $g_{V,\Delta,k}(z,x,u)$. By the binomial formula,
the $q$-index integral of $(L_k ,\Psi_{h,b,\varepsilon}^*)$ on
$X_k(V\langle\Delta\rangle)$ is therefore equal to
$$
\leqalignno{
&\int_{X_k(V\langle\Delta\rangle)(L_k,q)}
\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}^{n+kr-1}\cr
&\qquad{}={(n+kr-1)!\over n!(kr-1)!}
\int_{z\in X}\int_{\xi\in \bP(1^{[r]},\ldots,k^{[r]})}\omega_{r,k,b}^{kr-1}(\xi)
\wedge\bOne_{g_{V,\Delta,k},q}(z,x,u)\,g_{V,\Delta,k}(z,x,u)^n
&(4.1)\cr}
$$
where $\bOne_{g_{V,\Delta,k},q}(z,x,u)$ is the characteristic function
of the open set of points where $g_{V,\Delta,k}(z,x,u)$ has signature
$(n-q,q)$ in terms of the $dz_j$'s. Notice that since
$g_{V,\Delta,k}(z,x,u)^n$ is~a determinant, the product
$\bOne_{g_{V,\Delta,k},q}(z,x,u)\,g_{V,\Delta,k}(z,x,u)^n$ gives rise to
a continuous function on~$X_k(V\langle\Delta\rangle)$. By Formula 3.10~(a),
we get
$$
\leqalignno{
&\int_{X_k(V\langle\Delta\rangle)(L_k,q)}
\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}^{n+kr-1}
={(n+kr-1)!\over n!(k!)^r(kr-1)!}~~\times\cr
&\qquad\int_{z\in X}
\int_{(x,u)\in\bDelta^{k-1}\times(\bS^{2r-1})^k}\bOne_{g_{V,\Delta,k},q}(z,x,u)\,
g_{V,\Delta,k}(z,x,u)^n\,d\nu_{k,r}(x)\,d\mu(u).&(4.2)\cr}
$$

\subsection 4.B. Probabilistic estimate of cohomology groups|

We assume here that we are either in the ``compact'' case $(\Delta=0)$,
or in the logarithmic case $(\rho_j=\infty)$. Then the curvature
coefficients $\smash{c^{(s)}_{ij\lambda\mu}}=c_{ij\lambda\mu}$ do not
depend on $s$
and are those of the dual bundle $V^*$ (resp.\ $V^*\langle\Delta\rangle$).
In this situation, formula 3.20~(b) for $g_{V,\Delta,k}(z,x,u)$ can be
thought of as
a ``Monte Carlo'' evaluation of the curvature tensor, obtained by
averaging the curvature
at random points $u_s\in \bS^{2r-1}$ with certain positive weights $x_s/s\,$; 
we then think of the \hbox{$k$-jet}
$f$ as some sort of random variable such that the derivatives 
$\nabla^kf(0)$ (resp.\ logarithmic derivatives) are uniformly
distributed in all directions. Let us compute the expected value of
$(x,u)\mapsto g_{V,\Delta,k}(z,x,u)$ with respect to the probability measure
$d\nu_{k,r}(x)\,d\mu(u)$. Since 
$\int_{\bS^{2r-1}}u_{s,\lambda}\overline u_{s,\mu}d\mu(u_s)={1\over r}
\delta_{\lambda\mu}$ and $\int_{\bDelta^{k-1}}x_s\,d\nu_{k,r}(x)={1\over k}$,
we~find
$$
{\bf E}(g_{V,\Delta,k}(z,\bu,\bu))={1\over kr}
\sum_{1\le s\le k}{1\over s}\cdot{\ii\over 2\pi}\sum_{i,j,\lambda}
c_{ij\lambda\lambda}(z)\,dz_i\wedge d\overline z_j.
$$
In other words, we get the normalized trace of the curvature, i.e.
$$
{\bf E}(g_{V,\Delta,k}(z,\bu,\bu))={1\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)
\Theta_{\det(V^*\langle\Delta\rangle),\det h^*},
\leqno(4.3)
$$
where $\Theta_{\det(V^*\langle\Delta\rangle),\det h^*}$ is the
$(1,1)$-curvature form of $\det(V^*\langle\Delta\rangle)$ with the
metric induced by~$h$. It is natural to guess that 
$g_{V,\Delta,k}(z,x,u)$ behaves asymptotically as its expected value
${\bf E}(g_{V,\Delta,k}(z,\bu,\bu))$ when $k$ tends to infinity. If we replace brutally 
$g_{V,\Delta,k}$ by its expected value in~(4.2), we get the integral
$$
{(n+kr-1)!\over n!(k!)^r(kr-1)!}{1\over (kr)^n}
\Big(1+{1\over 2}+\cdots+{1\over k}\Big)^n\int_X\bOne_{\eta,q}\eta^n,
$$
where $\eta:=\Theta_{\det(V^*\langle\Delta\rangle),\det h^*}$ and
$\bOne_{\eta,q}$ is the
characteristic function of its $q$-index set in~$X$. The leading constant is
equivalent to $(\log k)^n/n!(k!)^r$ modulo 
a multiplicative factor \hbox{$1+O(1/\log k)$}. By working out a more
precise analysis of the deviation, the following result has been
proved in [Dem11] in the compact case; the more general logarithmic case
can be treated without any change, so we state the result in this situation
by just transposing the results of [Dem11].

\claim 4.4. Probabilistic estimate|Let $(X,V,\Delta)$ be a non singular
logarithmic directed variety.
Fix smooth hermitian metrics $\omega$ on $T_X$, $h$ on $V\langle\Delta\rangle$,
and write
$\omega={\ii\over 2\pi} \sum\omega_{ij}dz_i\wedge d\overline z_j$ on~$X$. 
Denote by $\Theta_{V\langle\Delta\rangle,h}=-{\ii\over 2\pi}\sum
c_{ij\lambda\mu}dz_i\wedge d\overline z_j\otimes e_\lambda^*\otimes
e_\mu$ the curvature tensor of $V\langle\Delta\rangle$ with respect to
an $h$-orthonormal frame $(e_\lambda)$, and put
$$
\eta(z):=\Theta_{\det(V^*\langle\Delta\rangle),\det h^*}=
{\ii\over 2\pi}\sum_{1\le i,j\le n}\eta_{ij}
dz_i\wedge d\overline z_j,\qquad
\eta_{ij}:=\sum_{1\le\lambda\le r}c_{ij\lambda\lambda}.
$$
Finally consider the $k$-jet line bundle
$L_k=\smash{\cO_{X_k(V\langle\Delta\rangle)}(1)}\to
X_k(V\langle\Delta\rangle)$ equipped with the induced metric
$\Psi^*_{h,b,\varepsilon}$
$($as defined above, with $1=\varepsilon_1\gg\varepsilon_2\gg\ldots\gg
\varepsilon_k>0)$. When $k$ tends 
to infinity, the integral of the top power of the curvature of $L_k$ on its
$q$-index set $X_k(V\langle\Delta\rangle)(L_k,q)$ is given by
$$
\int_{X_k(V\langle\Delta\rangle)(L_k,q)}
\Theta_{L_k,\Psi^*_{h,b,\varepsilon}}^{n+kr-1}=
{(\log k)^n\over n!\,(k!)^r}\bigg(
\int_X\bOne_{\eta,q}\eta^n+O((\log k)^{-1})\bigg)
$$
for all $q=0,1,\ldots,n$, and the error term $O((\log k)^{-1})$ can be 
bounded explicitly in terms of $\Theta_{V\langle\Delta\rangle}$, $\eta$
and $\omega$. Moreover, the  left hand side is identically zero for $q>n$.
\endclaim

The final statement follows from the observation that the curvature of
$L_k$ is positive along the fibers of $X_k(V\langle\Delta\rangle)\to X$, by the 
plurisubharmonicity of the weight (this is true even 
when the error terms are taken into account, since they
depend only on the base); therefore the $q$-index sets are empty for
$q>n$. It will be useful to extend the above estimates to the 
case of sections of
$$
L_{F,k}=\cO_{X_k(V\langle\Delta\rangle)}(1)\otimes
\pi_k^*\cO\Big({1\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big)
\leqno(4.5)
$$
where $F\in\Pic_\bQ(X)$ is an arbitrary $\bQ$-line bundle on~$X$ and 
$\pi_k:X_k(V\langle\Delta\rangle)\to X$ is the natural projection. We assume here
that $F$ is also equipped with a smooth hermitian metric $h_F$. In formulas
(4.2--4.4), the curvature $\Theta_{L_{F,k}}$ of $L_{F,k}$ takes 
the form $\Theta_{L_{F,k}}=\omega_{r,k,b}(\xi)+g_{V,\Delta,F,k}(z,x,u)$ where
$$
g_{V,\Delta,F,k}(z,x,u)=g_{V,\Delta,k}(z,x,u)+
{1\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)\Theta_{F,h_F}(z),
\leqno(4.6)
$$
and by the same calculations its normalized expected value is
$$
\eta_F(z):={1\over{1\over kr}(1+{1\over 2}+\cdots+{1\over k})}
{\bf E}(g_{V,\Delta,F,k}(z,\bu,\bu))=
\Theta_{\det V^*\langle\Delta\rangle,\det h^*}(z)+\Theta_{F,h_F}(z).
\leqno(4.7)
$$
Then the variance estimate for $g_{V,\Delta,F,k}$ is the same as the
variance estimate for $g_{V,\Delta,k}$, and the recentered
$L^p$ bounds are still valid, since our forms are just shifted
by adding the constant smooth term $\Theta_{F,h_F}(z)$. The probabilistic
estimate 4.4 is therefore still true in exactly the same form for $L_{F,k}$,
provided we use $g_{V,\Delta,F,k}$ and $\eta_F$ instead of $g_{V,\Delta,k}$
and $\eta$. An application of holomorphic Morse inequalities gives the 
desired cohomology estimates for 
$$
\eqalign{
h^q\Big(X,E_{k,m}V^*\langle\Delta\rangle&{}\otimes
\cO\Big({m\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big)\Big)\cr
&{}=h^q(X_k(V\langle\Delta\rangle),\cO_{X_k(V\langle\Delta\rangle)}(m)\otimes
\pi_k^*\cO\Big({m\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big)\Big),
\cr}
$$
provided $m$ is sufficiently divisible to give a multiple of $F$ which
is a $\bZ$-line bundle.

\claim 4.8. Theorem| Let $(X,V\langle\Delta\rangle)$ be a directed
manifold, $F\to X$ a
$\bQ$-line bundle, $(V\langle\Delta\rangle,h)$ and $(F,h_F)$ smooth
hermitian structure on $V\langle\Delta\rangle$ 
and $F$ respectively. We define
$$
\eqalign{
L_{F,k}&=\cO_{X_k(V\langle\Delta\rangle)}(1)\otimes
\pi_k^*\cO\Big({1\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big),\cr
\eta_F&=\Theta_{\det V^*\langle\Delta\rangle,\det h^*}+\Theta_{F,h_F}
=\Theta_{\det V^*\langle\Delta\rangle\otimes F,\det h^*}.\cr}
$$
Then for all $q\ge 0$ and all $m\gg k\gg 1$ such that 
m is sufficiently divisible, we have
$$\leqalignno{\kern20pt
h^q(X_k(V\langle\Delta\rangle),\cO(L_{F,k}^{\otimes m}))&\le {m^{n+kr-1}\over (n+kr-1)!}
{(\log k)^n\over n!\,(k!)^r}\bigg(
\int_{X(\eta_F,q)}(-1)^q\eta_F^n+O((\log k)^{-1})\bigg),&\hbox{\rm(a)}\cr
h^0(X_k(V\langle\Delta\rangle),\cO(L_{F,k}^{\otimes m}))&\ge {m^{n+kr-1}\over (n+kr-1)!}
{(\log k)^n\over n!\,(k!)^r}\bigg(
\int_{X(\eta_F,\le 1)}\eta_F^n-O((\log k)^{-1})\bigg),&\hbox{\rm(b)}\cr
\cr
\chi(X_k(V\langle\Delta\rangle),\cO(L_{F,k}^{\otimes m}))&={m^{n+kr-1}\over (n+kr-1)!}
{(\log k)^n\over n!\,(k!)^r}\big(
c_1(V^*\langle\Delta\rangle\otimes F)^n+O((\log k)^{-1})\big).
&\hbox{\rm(c)}\cr
\cr}
$$
\vskip-4pt
\endclaim

Green and Griffiths [GrGr80] already checked the Riemann-Roch
calculation (4.8$\,$c) in the special case $\Delta=0$,
$V=T_X^*$ and $F=\cO_X$. Their proof is much simpler since it relies only
on Chern class calculations, but it cannot provide any information on
the individual cohomology groups, except in very special cases where
vanishing theorems can be applied; in fact in dimension 2, the
Euler characteristic satisfies $\chi=h^0-h^1+h^2\le h^0+h^2$, hence
it is enough to get the vanishing of the top cohomology group $H^2$
to infer $h^0\ge\chi\,$; this works for surfaces by means of a well-known
vanishing theorem of Bogomolov which implies in general
$$H^n\bigg(X,E_{k,m} T_X^*\otimes
\cO\Big({m\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big)\Big)\bigg)=0
$$
as soon as $K_X\otimes F$ is big and $m\gg 1$.

In fact, thanks to Bonavero's singular holomorphic Morse inequalities 
(Theorem 2.9, cf.\ [Bon93]), everything works almost unchanged in the
case where the metric $h$ on $V$ is taken to a product
$h=h_\infty e^\varphi$ of a smooth
metric $h_\infty$ by the exponential of a quasi-plurisubarmonic
weight~$\varphi$ with analytic singularities (so that
$\det(h^*)=\det(h_\infty^*)e^{-r\varphi}$). Then $\eta$ is a
$(1,1)$-current with logarithmic poles, and we just have to twist
our cohomology groups by the appropriate multiplier ideal
sheaves $\cI_{k,m}$ associated with the weight
${1\over k}(1+{1\over 2}+\cdots+{1\over k})m\,\varphi$, since this
is the multiple of $\det V^*$ that occurs in the calculation, up to
the factor ${1\over r}\times r\varphi$. The corresponding Morse
integrals need only
be evaluated in the complement of the poles, i.e., on
$X(\eta,q)\ssm S$ where $S=\Sing(\varphi)$. Since
$$
(\pi_k)_*\big(\cO(L_{F,k}^{\otimes m})\otimes\cI_{k,m}\big)\subset
E_{k,m} V^*\otimes
\cO\Big({m\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big)\Big)
$$
we still get a lower bound for the $H^0$ of the latter sheaf (or for the $H^0$
of the un-twisted line bundle $\cO(L_k^{\otimes m})$ on $\smash{X_k(V)}$).
If we assume that $K_V\otimes F$ is big, these considerations
also allow us to obtain a strong estimate in terms of the volume, by
using an approximate Zariski decomposition on a suitable blow-up of~$X$.

\claim 4.9. Corollary|
If $F$ is an arbitrary $\bQ$-line bundle over~$X$, one has
$$
\eqalign{
h^0\bigg(&X_k(V),\cO_{X_k(V)}(m)\otimes\pi_k^*\cO
\Big({m\over kr}\Big(1+{1\over 2}+\cdots+{1\over k}\Big)F\Big)\bigg)\cr
&\ge {m^{n+kr-1}\over (n+kr-1)!}
{(\log k)^n\over n!\,(k!)^r}\Big(
\Vol(K_V\otimes F)-O((\log k)^{-1})\Big)-o(m^{n+kr-1}),\cr}
$$
when $m\gg k\gg 1$, in particular there are many sections of the
$k$-jet differentials of degree $m$ twisted by the appropriate
power of $F$ if $K_V\otimes F$ is big.
\endclaim

\proof. The volume is computed here as usual, i.e.\ after performing a
suitable modifi\-cation $\mu:\smash{\wt X}\to X$ which converts $K_V$ into 
an invertible sheaf. There is of course nothing to prove if
$K_V\otimes F$ is not big, so we can assume $\Vol(K_V\otimes F)>0$.
Let us fix smooth hermitian metrics $h_0$ on $T_X$
and $h_F$ on $F$. They induce a metric $\mu^*(\det h_0^{-1}\otimes
h_F)$ on $\mu^*(K_V\otimes F)$ which, by our definition of $K_V$, is
a smooth metric. By the result of Fujita [Fuj94] on
approximate Zariski decomposition, for every $\delta>0$, one can find
a modification $\mu_\delta:\smash{\wt X_\delta}\to X$ dominating
$\mu$ such that
$$
\mu_\delta^*(K_V\otimes F) =\cO_{\wt X_\delta}(A+E)
$$
where $A$ and $E$ are $\bQ$-divisors, $A$ ample and $E$ effective,
with 
$$\Vol(A)=A^n\ge \Vol(K_V\otimes F)-\delta.$$
If we take a smooth metric $h_A$ with positive definite curvature form
$\Theta_{A,h_A}$, then we get a singular hermitian metric $h_Ah_E$ on
$\mu_\delta^*(K_V\otimes F)$ with poles along $E$, i.e.\ the quotient
$h_Ah_E/\mu^*(\det h_0^{-1}\otimes h_F)$ is of the form $e^{-\varphi}$ where
$\varphi$ is quasi-psh with log poles $\log|\sigma_E|^2$ 
(mod $C^\infty(\smash{\wt X_\delta}))$ precisely given
by the divisor~$E$. We then only need to take the singular metric $h$
on $T_X$ defined by
$$
h=h_0e^{{1\over r}(\mu_\delta)^*\varphi}
$$
(the choice of the factor ${1\over r}$ is there to correct adequately 
the metric on $\det V$). By construction $h$ induces an 
admissible metric on $V$ and the resulting 
curvature current $\eta_F=\Theta_{K_V,\det h^*}+\Theta_{F,h_F}$ is such that
$$
\mu_\delta^*\eta_F = \Theta_{A,h_A} +[E],\qquad
\hbox{$[E]={}$current of integration on $E$.}
$$
Then the $0$-index Morse integral in the complement of the poles 
is given by
$$
\int_{X(\eta,0)\ssm S}\eta_F^n=\int_{\wt X_\delta}\Theta_{A,h_A}^n=A^n\ge
\Vol(K_V\otimes F)-\delta
$$
and Corollary 4.9 follows from the fact that $\delta$ can be taken arbitrary 
small.\qed

\claim 4.10. Remark|{\rm Since the probability estimate requires
$k$ to be very large, and since all non logarithmic components disappear
from $\Delta^{(s)}$ when $s$ is large, the above lower bound does not work
in the general orbifold case. In that case, one can only hope to get
an interesting result when $k$ is fixed and not too large. This is what
we aim at in the next section.}
\endclaim

\section{5. Non probabilistic estimate of the Morse integrals}

\subsection 5.A. Case of general directed orbifolds|

The non probabilistic estimate uses more explicit curvature inequalities and
has the advantage of producing results also in the general orbifold case.
Let us fix an ample line bundle $A$ on $X$ equipped with a smooth hermitian
metric $h_A$ such that $\omega_A:=\Theta_{A,h_A}>0$.
We assume here that the $s$-th directed (dual) orbifold bundle
$V^*\langle\Delta^{(s)}\rangle$ (cf.\ \S$\,$1.B)
possesses a hermitian metric $\wt h_s^*$ such that its curvature
tensor satisfies an inequality
$$
\Theta_{V^*\langle\Delta^{(s)}\rangle,\wt h_s^*}+\gamma_s\,\omega_A\otimes
\Id_{V^*\langle\Delta^{(s)}\rangle}
\ge 0\leqno(5.1)
$$
in the sense of Griffiths, for some number $\gamma_s\ge 0$.
Now, instead of exploiting a Monte Carlo convergence process for
the curvature tensor, we replace $\Theta_{V^*\langle\Delta^{(s)}\rangle}$
with
$$
\Theta_{V^*\langle\Delta^{(s)}\rangle}^A:=
\Theta_{V^*\langle\Delta^{(s)}\rangle}+\gamma_s\,\omega_A\otimes\Id\ge 0,
$$
and in this way get new curvature coefficients 
$c_{ij\lambda\mu}^{(s,A)}=c^{(s)}_{ij\lambda\mu}+\gamma_s\,\omega_{A,ij}\,
\delta_{\lambda\mu}$. This has the effect of replacing
$\Theta_{\det V^*\langle\Delta^{(s)}\rangle}=
\Tr\Theta_{V^*\langle\Delta^{(s)}\rangle}$  by
$\Theta_{\det V^*\langle\Delta^{(s)}\rangle}+r\gamma_s\,\omega_A$.
Also, we take
$$
L_{\varepsilon,k}:=\cO_{X_k(V\langle\Delta\rangle)}(1)\otimes
\pi_k^*\cO_X(-\varepsilon A).
\leqno(5.2)
$$
Then our earlier formulas 3.20~(a,b) become
$$
\leqalignno{
&\Theta_{L_{\varepsilon,k}}=\omega_{r,k,b}(\xi)+g_{\varepsilon,k}(z,x,u)\quad
\hbox{where}&(5.3)\cr  
\qquad~~~&g_{\varepsilon,k}(z,x,u)={\ii\over 2\pi}\kern-1pt
\sum_{1\le s\le k}\kern-2pt{x_s\over s}\kern-2pt
\sum_{i,j,\lambda,\mu}c^{(s)}_{ij\lambda\mu}(z)\,
u_{s,\lambda}\overline u_{s,\mu}\,dz_i\wedge d\overline z_j-
\varepsilon\,\omega_A.&(5.3')\cr}
$$
We want to express $g_{\varepsilon,k}(z,x,u)$ as a difference of two non
negative terms. For this, we write
$$
\leqalignno{
&g_{\varepsilon,k}(z,x,u)=g_{V,\Delta,k}^A(z,x,u)-
\bigg(\varepsilon+\sum_{1\le s\le k}{\gamma_sx_s\over s}\bigg)
\omega_A\quad\hbox{where}&(5.4)\cr
\kern30pt&g_{V,\Delta,k}^A(z,x,u)=
{\ii\over 2\pi}\sum_{1\le s\le k}{x_s\over s}
\sum_{i,j,\lambda,\mu}c^{(s,A)}_{ij\lambda\mu}(z)\,
u_{s,\lambda}\overline u_{s,\mu}\,dz_i\wedge d\overline z_j\ge 0.
&(5.4')\cr}
$$
Let us apply Corollary 2.4 with $\alpha,\beta$ replaced by
$$
\alpha_k=g_{V,\Delta,k}^A(z,x,u),\qquad\beta_k=
\bigg(\varepsilon+\sum_{1\le s\le k}{\gamma_sx_s\over s}\bigg)\omega_A,
$$
both forms being semipositive by our assumptions. Then (4.2) leads to
$$
\leqalignno{\qquad
&\int_{X_k(V)(L_k,\le 1)}\Theta_{L_{\varepsilon,k},\Psi^*_{h,b,\varepsilon}}^{n+kr-1}\cr
&\quad{}={(n+kr-1)!\over n!(k!)^r(kr-1)!}\int_{z\in X}
\int_{(x,u)\in\bDelta^{k-1}\times(\bS^{2r-1})^k}
\bOne_{\alpha_k-\beta_k,\le 1}\;(\alpha_k-\beta_k)^n\,d\nu_{k,r}(x)\,d\mu(u)\cr
&\quad{}\ge{(n+kr-1)!\over n!(k!)^r(kr-1)!}\int_{z\in X}
\int_{(x,u)\in\bDelta^{k-1}\times(\bS^{2r-1})^k}
\big(\alpha_k^n-n\alpha_k^{n-1}\wedge\beta_k\big)\,d\nu_{k,r}(x)\,d\mu(u).
&(5.6)\cr}
$$
The resulting integral now produces a ``closed formula'' which can be
expressed solely in terms of Chern classes (at least if we assume that
$\gamma$ is the Chern form of some semipositive line bundle). It is
then just a matter of routine to find a sufficient condition for the
positivity of the integral. One can readily obtain an upper bound
of $\alpha_k$ by taking the trace of $(c^{(s,A)}_{ij\lambda\mu})$.
In~this way we get
$$
0\le\alpha_k\le\sum_{1\le s\le k}{x_s\over s}\big(
\Theta_s+r\gamma_s\,\omega_A\big)\quad\hbox{where}~~
\Theta_s=\Theta_{\det V^*\langle\Delta^{(s)}\rangle}
\leqno(5.7)
$$
and where the right hand side no longer depends on $u\in (\bS^{2r-1})^k$. 
Also, $\alpha_k=g_{V,\Delta,k}^A$ can be written as a sum of
semipositive $(1,1)$-forms
$$
g_{V,\Delta,k}^A =\sum_{1\le s\le k}{x_s\over s}\theta^{s,A}(u_s),\qquad
\theta^{s,A}(u)={\ii\over 2\pi}\sum_{i,j,\lambda,\mu}c_{ij\lambda\mu}^{(s,A)}
u_\lambda\ol u_\mu\,dz_i\wedge d\ol z_j,
$$
hence for $k\ge n$ we have
$$
\alpha_k^n=(g_{V,\Delta,k}^A)^n\ge n!\sum_{1\le s_1<\ldots<s_n\le k}
{x_{s_1}\ldots\,x_{s_n}\over s_1\ldots\,s_n}\,
\theta^{s_1,A}(u_{s_1})\wedge \theta^{s_2,A}(u_{s_2})\wedge
\ldots\wedge \theta^{s_n,A}(u_{s_n}).
$$
Since $\int_{\bS^{2r-1}}\theta^{s,A}(u)\,d\mu(u)=
{1\over r}\Tr(\Theta_{V^*\langle\Delta^{(s)}\rangle}+\gamma_s\,\omega_A\otimes\Id)
={1\over r}(\Theta_s+r\gamma_s\,\omega_A)$,
we infer from this
$$
\leqalignno{\qquad
&\int_{(x,u)\in\bDelta^{k-1}\times(\bS^{2r-1})^k}
\alpha_k^n\,d\nu_{k,r}(x)\,d\mu(u)\cr
&\qquad\ge 
{n!\over r^n}\sum_{1\le s_1<\ldots<s_n\le k}
{1\over s_1\ldots\,s_n}\int_{\bDelta^{k-1}}x_1\ldots x_n\,d\nu_{k,r}(x)
\bigwedge_{\ell=1}^n\big(\Theta_{s_\ell}+r\gamma_s\,\omega_A\big).&(5.8)\cr}
$$
By formula 3.10~(a) and an elementary calculation (cf.\ [Dem11, Prop.~1.13]),
one gets
$$
\int_{\bDelta^{k-1}}x_1\ldots x_n\,d\nu_{k,r}(x)={(kr-1)!\over (r-1)!^k}\;
{r!^n(r-1)!^{k-n}\over(n+rk-1)!}={(kr-1)!\,r^n\over(n+rk-1)!}.
\leqno(5.9)
$$
Now, the upper bound (5.7) for $\alpha_k$ and the definition of $\beta_k$ imply
$$
n\alpha_k^{n-1}\wedge\beta_k\le n
\bigg(\varepsilon+\sum_{1\le s\le k}{\gamma_sx_s\over s}\bigg)
\bigg(\sum_{1\le s\le k}{x_s\over s}(\Theta_s+r\gamma_s\,\omega_A)
\bigg)^{n-1}\wedge\omega_A,\leqno(5.10)
$$
and we need an estimate of the integral, starting with
$\int_{\bDelta^{k-1}}(...)$. For every multi-index
$a=(a_1,\ldots,a_k)\in\bN^k$ with $\sum a_s=n$, we find
$$
\int_{\bDelta^{k-1}}x_1^{a_1}\ldots\,x_k^{a_k}\,d\nu_{k,r}(x)
={(kr-1)!\over(r-1)!^k}{
\prod_{s=1}^k(r+a_s-1)!\over(n+kr-1)!}~~
\cases{
  \le{\displaystyle (kr-1)!(n+r-1)!\over\displaystyle(r-1)!(n+kr-1)!},\cr
  \noalign{\vskip3pt}
  \ge{\displaystyle(kr-1)!\,r^n\over\displaystyle(n+kr-1)!},\cr}
$$
because the maximum is attained for the length $n$ multi-index
$a=(n,0,\ldots,0)$, and the
mini\-mum for $a=(1,\ldots,1,0,\ldots,0)$ (or any permutation). 
An expansion of
$$
\bigglp2pt(\sum_{1\le s\le k}{\gamma_sx_s\over s}\biggrp2pt)
\bigglp2pt(\sum_{1\le s\le k}{x_s\over s}(\Theta_s+r\gamma_s\,\omega_A)
\biggrp2pt)^{n-1}
$$
in terms of its monomials $x^a$ then gives
$$
\leqalignno{
\int_{\bDelta^{k-1}}\bigglp2pt(
&\sum_{1\le s\le k}{\gamma_sx_s\over s}\biggrp2pt)
\bigglp2pt(\sum_{1\le s\le k}{x_s\over s}
(\Theta_s+r\gamma)\biggrp2pt)^{n-1}\,d\nu_{k,r}(x)\cr
&\cases{\displaystyle
  \le{\displaystyle (kr-1)!(n+r-1)!\over\displaystyle(r-1)!(n+kr-1)!}\,
  \bigglp2pt(\sum_{1\le s\le k}{\gamma_s\over s}\biggrp2pt)
  \bigglp2pt(\sum_{1\le s\le k}{1\over s}(\Theta_s+r\gamma_s\,\omega_A)
  \biggrp2pt)^{n-1},\cr
  \noalign{\vskip5pt}
  \ge  \displaystyle{\displaystyle(kr-1)!\,r^n\over\displaystyle (n+kr-1)!}\,
  \bigglp2pt(\sum_{1\le s\le k}{\gamma_s\over s}\biggrp2pt)
  \bigglp2pt(\sum_{1\le s\le k}{1\over s}(\Theta_s+r\gamma_s\,\omega_A)
  \biggrp2pt)^{n-1}.\cr}
&(5.11)\cr}
$$
The inequalities are to be understood as inequalities between
$(n-1,n-1)$-forms, and they hold because our assumption (5.1) implies
$\Theta_s+r\gamma_s\,\omega_1\ge 0$. Also observe that
the ratio between the upper bound and the lower bound is
${(n+r-1)!\over r^n(r-1)!}$ which, for $r=n$ 
is${}\sim 2^{-1/2}(4/e)^n$ by Stirling's formula; thus, when taking
the upper bound, the ``inaccuracy'' factor is at most exponential in $n$
with a small constant $4/e<1.5$. By using integrals of monomials $x^a$ of
degree $|a|=n-1$, we would obtain in a similar way
$$
\leqalignno{
\int_{\bDelta^{k-1}}\varepsilon
\bigglp2pt(\sum_{1\le s\le k}{x_s\over s}
&(\Theta_s+r\gamma)\biggrp2pt)^{n-1}\,d\nu_{k,r}(x)\cr
&
\le\varepsilon\,{(kr-1)!(n+r-2)!\over\displaystyle(r-1)!(n+kr-2)!}\,
  \bigglp2pt(\sum_{1\le s\le k}{1\over s}(\Theta_s+r\gamma_s\,\omega_A)
  \biggrp2pt)^{n-1}.&(5.12)\cr}
$$
By putting $(5.8-5.12)$ together we obtain
$$
\eqalign{
&\int_{(x,u)\in\bDelta^{k-1}\times(\bS^{2r-1})^k}
\big(\alpha_k^n-n\alpha_k^{n-1}\wedge\beta_k\big)\,d\nu_{k,r}(x)\,d\mu(u)\cr
&\ge{n!\over r^n}\,{(kr-1)!\,r^n\over(n+rk-1)!}
\sum_{1\le s_1<\ldots<s_n\le k}~
{1\over s_1\ldots\,s_n}
\bigwedge_{\ell=1}^n\big(\Theta_{s_\ell}+r\gamma_{s_\ell}\,\omega_A\big)\cr
&-n\,
{\displaystyle (kr-1)!(n+r-1)!\over\displaystyle(r-1)!(n+kr-1)!}
  \bigg({(n+kr-1)\varepsilon\over n+r-1}+\sum_{1\le s\le k}{\gamma_s\over s}
  \bigg)\bigglp2pt(\displaystyle\sum_{1\le s\le k}{1\over s}(
  \Theta_s+r\gamma_s\,\omega_A)\biggrp2pt)^{n-1}\wedge\omega_A.  
\cr}
$$
The Morse integral lower bound (5.6) finally implies

\claim 5.13.~Theorem|Assume that the curvature of the orbifold bundles satisfy
the lower bounds
$\Theta_{V^*\langle\Delta^{(s)}\rangle}\ge-\gamma_s\,\omega_1\otimes\Id_{V^*}$
$($in the sense of Griffiths$)$, for some number $\gamma_s\in\bR_+$.
Then the orbifold line bundle
$$
L_{\varepsilon,k}=\cO_{X_k(V\langle\Delta\rangle)}(1)\otimes
\pi_k^*\cO(-\varepsilon A)
$$
admits for all $k\ge n$ and $\varepsilon\in\bQ_+$ a number of sections
$h^0(X_k(V\langle\Delta\rangle), L_{\varepsilon,k}^{\otimes m})$ that
is bounded below asympto\-tically, modulo an error term
$o(m^{n+kr-1})$, by
$$
\eqalign{
&{m^{n+kr-1}\over (n+kr-1)!}\int_{X_k(V\langle\Delta\rangle)
(L_{\varepsilon,k},\le 1)}\Theta_{L_{\varepsilon,k},
\Psi^*_{h,b,\varepsilon}}^{n+kr-1}
\ge{m^{n+kr-1}\over (k!)^r(n+kr-1)!}\times{}\cr
&\qquad{}
\int_X\sum_{1\le s_1<\ldots<s_n\le k}{1\over s_1\ldots\,s_n}
\bigwedge_{\ell=1}^n\big(\Theta_{s_\ell}+r\gamma_{s_\ell}\,\omega_A\big)\cr
&\quad\qquad{}-{\displaystyle (n+r-1)!\over\displaystyle (n-1)!(r-1)!}
  \bigg({(n+kr-1)\varepsilon\over n+r-1}+\sum_{1\le s\le k}{\gamma_s\over s}
  \bigg)\bigglp2pt(\displaystyle\sum_{1\le s\le k}{1\over s}(
  \Theta_s+r\gamma_s\,\omega_A)\biggrp2pt)^{n-1}\wedge\omega_A.  
\cr}
$$
where $\Theta_s=\Theta_{\det V^*\langle\Delta^{(s)}\rangle}$.
Especially, for $m\gg 1$,  we have a lot of sections in
$$
H^0(X_k(V\langle\Delta\rangle),L_{\varepsilon,k}^{\otimes m})=
H^0(X,E_{k,m}V^*\langle\Delta\rangle\otimes\cO_X(-m\varepsilon A)),
$$
whenever the integral in the right hand side of the lower bound is positive.
\endclaim

The statement is also true for $k<n$, but then the first sum is equal to $0$
and the lower bound cannot be positive (by Corollary 1.11, it still
provides a non trivial lower bound for
$h^0(X_k(V\langle\Delta\rangle),L_{\varepsilon,k}^{\otimes m})-
h^1(X_k(V\langle\Delta\rangle),L_{\varepsilon,k}^{\otimes m})$, though).
For $k=n$, there is a single term $s_1=1,s_2=2,\ldots,s_n=n$, so that
${1\over s_1\ldots\,s_n}={1\over n!}$, and we get the simpler estimate
$$
\leqalignno{
&{m^{n+nr-1}\over (n+nr-1)!}\int_{X_n(V\langle\Delta\rangle)
(L_{n,\varepsilon},\le 1)}
\Theta_{L_{\varepsilon,k},\Psi^*_{h,b,\varepsilon}}^{n+nr-1}
\ge{m^{n+nr-1}\over (n!)^{r+1}(n+nr-1)!}
\int_X\bigwedge_{\ell=1}^n\big(\Theta_\ell+r\gamma_\ell\,\omega_A\big)\cr
&\quad\qquad{}-{\displaystyle n\,(n+r-1)!\over\displaystyle (r-1)!}
\bigglp2pt({(n+nr-1)\varepsilon\over n+r-1}+\sum_{1\le s\le n}{\gamma_s\over s}
\biggrp2pt)\bigglp2pt(\displaystyle\sum_{1\le s\le n}{1\over s}(
\Theta_s+r\gamma_s\,\omega_A)\biggrp2pt)^{n-1}\wedge\omega_A.&(5.14)
\cr}
$$

\subsection 5.B. Case of orbifold structures on projective $n$-space|

The following elementary result shows that the hypothesis made in
Theorem 5.13 on the lower bound of the curvature is very natural and
always holds true.

\claim 5.15.~Proposition|Let $X\subset\bP^N$ be a projective variety and
$(X,V,\Delta)$ an orbifold directed structure where
$\Delta=\sum(1-{1\over\rho_j})\Delta_j$ is a 
normal crossing divisor transverse to~$V$ in~$X$. Let $a_j$ be the
infimum of numbers
$\lambda\in\bR_+$ such that $\lambda\,\cO_X(1)-\Delta_j$ is~nef.
Then for every $a>\max(a_j/\rho_j,2)$, the orbifold vector bundle
$V\langle\Delta\rangle$
possesses a hermitian metric $h_a$ such that
\vskip2pt
\item{\rm(a)} $h_a$ is smooth on $X\ssm|\Delta|,$
\vskip2pt
\item{\rm(b)} $h_a$ has the appropriate orbifold singularities
along $\Delta,$
\vskip2pt
\item{\rm(c)} the curvature tensor
of $V^*\langle\Delta\rangle \otimes\cO_X(a)$~is Griffiths positive.
\vskip2pt  
\endclaim

\proof. Let $\Theta_{\cO_{\bP^N}(1),\FS}=\omega_\FS(\zeta)=
{\ii\over 2\pi}\ddbar\log|\zeta|^2$ be the
Fubini-Study metric. Consider the tautological sections
$\sigma_j\in H^0(X,\cO_X(\Delta_j))$ such that $\Delta_j=\sigma_j^{-1}(0)$,
and let $h_j$ be a smooth hermitian metric on
$\cO_X(\Delta_j)$ for which
$$
{1\over\rho_j}
\Theta_{\cO_X(\Delta_j),h_j}<a\,\Theta_{\cO_X(1),\FS}=a\,\omega_{\FS|X},
\leqno(5.16)
$$
as is possible by our choice of constants $a_j$ and $a$.
Finally, denote by $\nabla_j$ the associated Chern connection on
$\cO_X(\Delta_j)$. If we write $h_j=e^{-\varphi_j}$ in some local
trivialization, then $\nabla_j\sigma_j=\nabla_j^{1,0}\sigma_j=
\partial\sigma_j-\sigma_j\partial\varphi_j$.
We are going to estimate the curvature of the orbifold metric on
$V\langle\Delta\rangle$ defined by
$$
\Vert v\Vert_h^2=
\sum_j|\sigma_j|_{h_j}^{-2(1-1/\rho_j)}\,|\nabla_j\sigma_j(v)|_{h_j}^2
+\big(K+K'|\sigma_j|_{h_j}^{2/\rho_j}\big)\,|v|_\FS^2,\quad K\gg K'\gg 1,
\leqno(5.17)
$$
where the metric $|\bu|_\FS^2$ on $V\subset T_X\subset T_{\bP^N}$ is
the restriction of the Fubini-Study metric~$\omega_\FS$.
What we need to prove is that over $X\ssm|\Delta|$ we have
$$
{\ii\over 2\pi}\ddbar\log\Vert v\Vert_h^2+a\,p^*\omega_\FS\ge 0
$$
on the total space of $V$, where $p:V\to X$ is the natural projection.
We make this calculation at an arbitrary point $z_0\in X$.
By the homogeneity of $\bP^N$, we can always find orthonormal coordinates
such that $z_0=0\in\bC^N\subset\bP^N$ in
the affine chart $z\mapsto [1:z]$,
and $T_X=\Span({\partial\over\partial z_\ell})_{1\le\ell\le n}$.
We take $(z_1,\ldots,z_n)$ as local coordinates on $X$ and
$v=\sum_{\ell=1}^nv_\ell{\partial\over\partial z_\ell}$ in
$V\subset T_X\simeq\bC^n$. In terms of the standard hermitian metric
on $\bC^n$, we then find
$$
\eqalign{
\Vert v\Vert_h^2&=\sum_j
\big(|\sigma_j|^2e^{-\varphi_j}\big)^{-1+1/\rho_j}\,
\big|\partial\sigma_j(v)-\sigma_j\partial\varphi_j(v)\big|^2e^{-\varphi_j}\cr
&\kern120pt{}+\big(K+K'e^{-\varphi_j/\rho_j}|\sigma_j|^{2/\rho_j}\big)
\bigg({|v|^2\over 1+|z|^2}-{|\langle v,z\rangle|^2\over (1+|z|^2)^2}\bigg)\cr
&=\sum_je^{-\varphi_j/\rho_j}\,|\sigma_j|^{-2+2/\rho_j}
\Big(|\partial\sigma_j(v)|^2+|\sigma_j|^2|\partial\varphi_j(v)|^2
-2\Re\,\big(\overline\sigma_j\,\partial\sigma_j(v)\,
\dbar\varphi_j(v)\big)\Big)\cr
&\kern120pt{}+\big(K+K'e^{-\varphi_j/\rho_j}|\sigma_j|^{2/\rho_j}\big)\,
{|v|^2+|v\wedge z|^2\over (1+|z|^2)^2}.\cr}
$$
By the homogeneity in $v$, it is enough to show that
$$
\beta:=i\ddbar\big(\Vert v\Vert_h^2(1+|z|^2)^a\big)_{(z_0,v_0)}\ge 0
\quad\hbox{on}\quad T(T_X)_{(z_0,v_0)}=
\Span\Big({\partial\over \partial z_j},{\partial\over\partial v_j}\Big)
\simeq\bC^N\times\bC^N,
$$
for every $v_0\in\bC^N$. In order to simplify our calculations, we take
holomorphic trivializations of the line bundles $\cO_X(\Delta_j)$ so that
$\varphi_j(z)=\sum_{\ell,m}\alpha_{j,\ell,m}\,z_\ell\overline z_m+O(|z|^3)$ near
$z_0=0$. Then
$$
\partial\varphi_j=\sum\alpha_{j,\ell,m}\,\overline z_m dz_\ell+O(|z|^2),
\quad
\dbar\varphi_j=\sum\alpha_{j,\ell,m}\,z_\ell\,d\overline z_m+O(|z|^2).
\leqno(5.18)
$$
It turns out that most of the terms occurring in $\beta_{(z_0,v_0)}$ are non
negative, since we have many squares of holomorphic functions in $(z,v)$
(such as $|\partial\sigma_j(v)|^2$), and likewise
$i\ddbar|\partial\varphi_j(v)|^2=|\ddbar\varphi_j(v,dz)|^2\ge 0$ at $z=0$,
thanks to the Taylor expansion (5.18).
In what follows, we only keep track of the potentially negative terms and
of a few positive ones that can be used to control them. Especially, one of
the problematic terms is $2\Re(\ldots)$, which we rewrite
$\smash{2\Re\big(e^{O(|z|^2)}\,\sigma_j^{-1+1/\rho_j}\,
\overline\sigma_j^{\,1/\rho_j}\,\partial\sigma_j(v)\,\dbar\varphi_j(v)\big)}$.
This gives, modulo the usual identification of $(1,1)$-forms and
hermitian forms:
$$
\leqalignno{
\beta_{(z_0,v_0)}&\ge\sum_j K\Big(|\partial v|^2+(a-2)|v|^2|\partial z|^2\Big)+
K'\bigg(\ii\ddbar(|\sigma_j|^{2/\rho_j}|v|^2)
-{1\over\rho_j}(\ii\ddbar\varphi_j)\,
|\sigma_j|^{2/\rho_j}|v|^2\bigg)\cr
&\qquad{}
+\Big(a|\partial z|^2-{1\over\rho_j}\ii\ddbar\varphi_j\Big)\,
|\sigma_j|^{-2+2/\rho_j}\,
|\partial\sigma_j(v)|^2&(5.19_1)\cr
&\qquad{}-2\Re\bigg({1\over\rho_j}\,|\sigma_j|^{-2+2/\rho_j}\,
\partial\sigma_j(v)\,\ddbar\varphi_j(dz,v)\,\overline{\partial\sigma_j}\bigg).
&(5.19_2)\cr}  
$$
Since $K\gg K'$, the term $K'\cdot{1\over\rho_j}(\ii\ddbar\varphi_j)\,
|\sigma_j|^{2/\rho_j}|v|^2$ is controlled by
$K\cdot(a-2)|v|^2|\partial z|^2$, thanks to a compactness argument. The term
$(5.19_1)$ is positive by our curvature condition~(5.16).
Moreover, by the Cauchy-Schwarz inequality, there exists a constant
$C>0$ (independent of $z_0$, $K$, $K'$) such that
$$
\big|(5.19_2)\big|\le
\varepsilon\,|\sigma_j|^{-2+2/\rho_j}\,|\partial\sigma_j(v)|^2\,
|\partial z|^2
+{C\over\varepsilon}\,|\sigma_j|^{-2+2/\rho_j}\,|v|^2\,|\partial\sigma_j|^2
\leqno(5.20)
$$
for every $\varepsilon>0$. The $\varepsilon$-term can be absorbed
in $(5.19_1)$ after replacing $a$ by $a-\varepsilon$. Finally
$$
\eqalign{
K'\cdot\ii\ddbar(|\sigma_j|^{2/\rho_j}|v|^2)&=
K'\,\bigg|{1\over\rho_j}\sigma_j^{-1+1/\rho_j}v\,\partial\sigma_j
+\sigma_j^{1/\rho_j}\partial v\bigg|^2\cr
&\ge
{K'\over 2\rho_j^2}\,|\sigma_j|^{-2+2/\rho_j}|v|^2\,
|\partial\sigma_j|^2-K'|\sigma_j|^{2/\rho_j}\,|\partial v|^2,
\cr}
$$
where the term ${K'\over 2\rho_j^2}...$ can be used to control the term
${C\over \varepsilon}...$ in (5.20), and the term
$-K'|\sigma_j|^{2/\rho_j}\,|\partial v|^2$ is bounded by $K\,|\partial v|^2$.
The proof is complete.\qed

\claim 5.21. Remark|{\rm The conclusion of Proposition 5.15 stills holds if we
take $a_j$ to be the infimum of numbers $\lambda\in\bR_+$ such that
$(\lambda\,\cO_X(1)-\Delta_j)_{|\Delta_j}$ is~nef on $\Delta_j$. In fact,
the curvature estimate (5.17) is merely needed in a neighborhood
of $|\Delta_j|$, since all terms occurring in $\beta_{(z_0,v_0)}$
are controlled by the main
term $K\big(|\partial v|^2+(a-2)|v|^2|\partial z|^2\big)$ in the complement
of such a neighborhood.}
\endclaim

An interesting special orbifold example is the case when $X=\bP^n$, $V=T_X$,
$A=\cO(1)$ and
$\Delta=\sum (1-{1\over\rho_j})\Delta_j$ is a normal crossing divisor,
with components $\Delta_j$ of degree $d_j$. Then
$\Delta^{(s)}=\sum\big(1-{s\over\rho_j}\big)_+\Delta_j$, hence
$$
\det V^*\langle\Delta^{(s)}\rangle
=\cO_{\bP^n}\big(-n-1+\sum_j d_j(1-s/\rho_j)_+\big)
$$
and the associated curvature form is
$$
\Theta_s=\Big(-n-1+\sum_j d_j(1-s/\rho_j)_+\Big)\omega_A.
$$
Moreover, by Proposition~5.15, we have
$$
\Theta_{V^*\langle\Delta^{(s)}\rangle}+\gamma_s\,\omega_\FS\otimes\Id>0
$$
as soon as $\gamma_s>2$ and
$\gamma_s>d_j/\max(\rho_j/s,1)$ for all components $\Delta_j$
in $\Delta^{(s)}$. We can take for instance $\gamma_s>\max(sd_j/\rho_j,2)$.
Then, for $k=n$ and
$\varepsilon\in\bQ_+$ small, the estimate (5.14)
guarantees the existence of jet differentials under the following
complicated condition.

\claim 5.22. Proposition|Let $\Delta=\sum_j(1-{1\over\rho_j})\Delta_j$
a simple normal crossing orbifold divisor on~$\bP^n$. Then there exist
jet differentials of order $n$ and large degree $m$ 
on $\bP^n\langle\Delta\rangle$, with a small negative
twist $\cO_{\bP^b}(-m\varepsilon)$, as soon as
$$
\eqalign{&\prod_{s=1}^n
\bigglp2pt(n\max(sd_j/\rho_j,2)-(n-1)+\sum_jd_j(1-s/\rho_j)_+\biggrp2pt)>
{n\,(2n-1)!\over (n-1)!}\times{}\cr
&\bigglp2pt(\sum_{1\le s\le n}{1\over s}\max(sd_j/\rho_j,2)\!\biggrp2pt)
\bigglp2pt(\sum_{1\le s\le n}{1\over s}\Big(n\max(sd_j/\rho_j,2)-(n\,{-}\,1)+
\sum_jd_j(1\,{-}\,s/\rho_j)_+\Big)\!\biggrp2pt)^{n-1}\kern-0.75pt.\cr}
$$
\endclaim

\noindent
We are going to find a simpler sufficient condition.
If we set $t_j:=d_j/\rho_j$, $t=\max(t_j,2)$ and assume $\rho_j\ge\rho>n$,
we get the condition
$$
\eqalign{\prod_{s=1}^n
\bigglp2pt(nst&-(n-1)+\sum_j(d_j-st_j)\biggrp2pt)>\cr
&{n\,(2n-1)!\over (n-1)!}\times nt
\bigglp2pt(\sum_{1\le s\le n}{1\over s}
\Big(nst-(n-1)+\sum_j(d_j-st_j)\Big)\!\biggrp2pt)^{n-1},\cr}
$$
which is implied by
$$
\prod_{s=1}^n\bigglp2pt(\Big(1-{s\over \rho}\Big)\sum_jd_j\biggrp2pt)>
{n^2\,(2n-1)!\over (n-1)!}\times
t\bigglp2pt(n^2t+\Big(1+{1\over 2}+\cdots+{1\over n}\Big)
\sum_jd_j\biggrp2pt)^{n-1}.
$$
The latter condition is satisfied if
$\sum_j d_j\ge c_nt\prod_{s=1}^n\big(1-{s\over\rho}\big)^{-1}$ with
$$
c_n={n^2\,(2n-1)!\over (n-1)!}\,
\Big(1+{1\over 2}+\cdots+{1\over n-1}+{2\over n}\Big)^{n-1},
$$
since $c_n\geq n^3$, and so $n^2t\le {1\over n}\sum d_j$.
The Stirling formula gives
$$
c_n\le 2^{-1/2}\,(4/e)^n\,n^{n+2}\,(1+\log n)^{n-1}=O((2n\log n)^n)
$$
for $n$ large. In this way we get

\claim 5.23. Corollary|A sufficient condition for the existence of
negatively twisted orbifold $n$-jet differentials on 
$\bP^n\langle\Delta\rangle$ is
$$
\rho_j\ge \rho>n,\quad
\sum d_j\ge c_n\,\max\bigg({d_j\over\rho_j},2\bigg)
\prod_{s=1}^n\Big(1-{s\over\rho}\Big)^{-1}.
$$
\endclaim

\noindent
For instance, one can take all components $\Delta_j$ possessing
the same degree $d$ and ramification number $\rho>n$, and a number
of components
$$
N\ge c_n\,\max\bigg({1\over\rho},{2\over d}\bigg)
\prod_{s=1}^n\Big(1-{s\over\rho}\Big)^{-1},
$$
or a single component $(1-{1\over\rho_1})\Delta_1$
with $\rho_1\ge 2c_n$ and $d_1\ge 4c_n$ (notice that
$\prod(1-{s\over 2c_n})^{-1}<2$).
Since we have neglected many terms in the above calculations, 
the ``technological constant'' $c_n$ appearing in these
estimates is probably much larger than needed.
\bigskip\bigskip

\centerline{\twelvebf References}
\medskip

\bibitem[Cad17]&Cadorel, B.:& Jet differentials on toroidal compactifications of ball quotients.& arXiv: math.AG/1707.07875&

\bibitem[CDR18]&Campana, F., Darondeau, L., Rousseau, E.:& Orbifold hyperbolicity.& arXiv: math.AG/1803.10716&

\bibitem[Dem95]&Demailly, J.-P.:& Propriétés de semi-continuité de la cohomologie et de la dimension de Kodaira-Iitaka.& C.~R.\ Acad.\ Sci.\ Paris Sér.~I Math.\
{\bf} 320 (1995), 341--346&

\bibitem[Dem97]&Demailly, J.-P.:& Algebraic criteria for Kobayashi
hyperbolic projective varieties and jet differentials.& AMS Summer
School on Algebraic Geometry, Santa Cruz 1995, Proc.\ Symposia in
Pure Math., ed.\ by J.~Koll\'ar and R.~Lazarsfeld, Amer.\ Math.\ Soc.,
Providence, RI (1997), 285–-360&

\bibitem[Dem11]&Demailly, J.-P.:& 
Holomorphic Morse Inequalities and the Green-Griffiths-Lang Conjecture.&
Pure and Applied Math.\ Quarterly {\bf 7} (2011), 1165--1208&

\bibitem[Dem12]&Demailly, J.-P.:& 
Hyperbolic algebraic varieties and holomorphic differential equations.&
expanded version of the lectures given at the annual meeting of VIASM,
Acta Math.\ Vietnam.\ {\bf 37} (2012), 441-–512&

\bibitem[GrGr80]&Green, M., Griffiths, P.:& Two applications of algebraic
geometry to entire holomorphic mappings.& The Chern Symposium 1979,
Proc.\ Internal.\ Sympos.\ Berkeley, CA, 1979, Springer-Verlag, New York
(1980), 41--74&

\medskip

\parindent=0cm
(version of August 5, 2019, printed on \today, \timeofday)
\medskip

Fr\'ed\'eric Campana\\
Institut de Mathématiques Élie Cartan, Université de Lorraine, B.P. 70239\\
54506 Vand{\oe}uvre-lès-Nancy, France\\
E-mail : frederic.campana@univ-lorraine.fr

Lionel Darondeau\\
Université Montpellier II, 
Institut Montpellierain Alexander Grothendieck,\\
Case courrier 051, Place Eugène Bataillon, 34090 Montpellier, France\\
E-mail : lionel.darondeau@normalesup.org

Jean-Pierre Demailly\\
Université Grenoble Alpes,\\
Institut Fourier, 100 rue des Maths, 38610 Gières, France\\
E-mail : jean-pierre.demailly@univ-grenoble-alpes.fr

Erwan Rousseau\\
Institut Universitaire de France,\\
CMI, Université d'Aix-Marseille, 39, rue Frédéric Joliot-Curie,
13453 Marseille, France\\
E-mail : erwan.rousseau@univ-amu.fr     

\end

% Local Variables:
% TeX-command-default: "TeX"
% End: