Common selections for the metric projections

Costica Mustata
(original), Approximation Theory, paper

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Costica Mustata
“Tiberiu Popoviciu” Institute of Numerical Analysis, Romanian Academy, Romania

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C. Mustăţa, Common selections for the metric projections, Mathematica 35 (58) (1993) 2, 193-200.

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Mathematica

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Romanian Academy

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 2601-744X

MR # 96b: 46018

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[1] Czipser, J. and Geher, L., Extension of Funcitons Satisfying a Lipschitz Condition, Acta Math. Acad. Sci. Hungar, 6 (1955), 213-220.
[2] Deutsch, F., Linear Selections for Metric Projeciton, J. Funct. Analysis 49, 3 (1982), 269-292.
[3] Deutsch, F., Wu Li, Sung-Ho Park, Tietze Extensions and Continuous Selections for Metric Projections, J. Approx. Theory 64, 1 (1991), 55-68.
[4] Mc Shane, E.J., Extension of Range of Funcitons, bull. Amer. Math. Soc. 40 (1934), 837-842.
[5] Mustata, C., Asupra unor subspații cebîșeniene din spațiul normal al funcțiilor lipschitziene, Rev. Anal. Numer. Teoria Aproximației 2 (1973), 81-87.
[6] Mustata, C., Best Approximation and Unique Extension of Lipschitz Functions, J. Approx. Theory 19, 3, (1977), 222-230.
[7] Mustata, C., M-ideal in Metric Spaces, “Babes-Bolyai” Univ. Research Seminars, Seminar on Mathematical Analysis, Preprint nr.7, (1988), 65-74.
[8] Mustata, C., Extension of Holder Functions and Some Related Problems of Best Approximation, “Babes-Bolyai” Univ. Research Seminars, Seminar on Mathematical analysis, Preprint, nr.7 (1991), 71-86.
[9] Mustata C., Selections Associated to Mc Shane’s Extension Theorem for Lipschitz Functions, Revue d’Analyse Numer. et de la Theorie de l’Approximation 21, 2 (1992), 135-145.

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1993-Mustata-Mathematica-Common-selections-for-the-metric-projections

COMMON SELECTIONS FOR THE METRIC PROJECTIONS

COSTICĂ MUSTĂTA

  1. Let X X XXX be a normed space and M M MMM a closed subspace of X X XXX. The subspace M M MMM is called proximinal (Chebyshev) if for every x X x X x in Xx \in XxX, the set of the elements of best approximation for x x xxx in M M MMM, given by
(1) P M ( x ) = { y M : x y = d ( x , M ) } (1) P M ( x ) = { y M : x y = d ( x , M ) } {:(1)P_(M)(x)={y in M:||x-y||=d(x","M)}:}\begin{equation*} P_{M}(x)=\{y \in M:\|x-y\|=d(x, M)\} \tag{1} \end{equation*}(1)PM(x)={yM:xy=d(x,M)}
where
(2) d ( x , M ) = inf { x y : y M } (2) d ( x , M ) = inf { x y : y M } {:(2)d(x","M)=i n f{||x-y||:y in M}:}\begin{equation*} d(x, M)=\inf \{\|x-y\|: y \in M\} \tag{2} \end{equation*}(2)d(x,M)=inf{xy:yM}
is nonvoid (respectively a one-point set).
The quantity d ( x , M ) d ( x , M ) d(x,M)d(x, M)d(x,M) is called the distance from x x xxx to M M MMM.
If M M MMM is a proximinal subspace of X X XXX, then the operator P M : X 2 M P M : X 2 M P_(M):X rarr2^(M)P_{M}: X \rightarrow 2^{M}PM:X2M is called the metric projection on M M MMM, and the set
(3) ker P M = { x X : 0 P M ( x ) } = { x X : x = d ( x , M ) } (3)  ker  P M = x X : 0 P M ( x ) = { x X : x = d ( x , M ) } {:(3)" ker "P_(M)={x in X:0inP_(M)(x)}={x in X:||x||=d(x","M)}:}\begin{equation*} \text { ker } P_{M}=\left\{x \in X: 0 \in P_{M}(x)\right\}=\{x \in X:\|x\|=d(x, M)\} \tag{3} \end{equation*}(3) ker PM={xX:0PM(x)}={xX:x=d(x,M)}
is called the kernel of the metric projection P M P M P_(M)P_{M}PM.
Definition 1. A function p : X M p : X M p:X rarr Mp: X \rightarrow Mp:XM is called a selection for the metric projection P M P M P_(M)P_{M}PM, if p ( x ) P M ( x ) p ( x ) P M ( x ) p(x)inP_(M)(x)p(x) \in P_{M}(x)p(x)PM(x), for all x X x X x in Xx \in XxX.
The existence of continuous (and eventualy linear) selections and characterizations of continuous or linear selections for P M P M P_(M)P_{M}PM have been studied in [2], for arbitrary normed spaces X X XXX.
The finding of continuous or linear metric selections in concrete normed spaces is a problem specific to each considered case. Two such concrete cases were considered in [3] and [91,
This paper will be concerned with the following natural problem: if 1 1 ||||_(1):}\left\|\|_{1}\right.1 and 2 2 ||||_(2)\| \|_{2}2 are two norms on a linear space X X XXX and M M MMM is a subspace of X X XXX which is proximinal with respect to each of these norms, find a common selection for the metric projections P M 1 P M 1 P_(M)^(1)P_{M}^{1}PM1 and P M 2 P M 2 P_(M)^(2)P_{M}^{2}PM2; i.e. an application p : X M p : X M p:X rarr Mp: X \rightarrow Mp:XM such that p ( x ) P M 1 ( x ) P M 2 ( x ) p ( x ) P M 1 ( x ) P M 2 ( x ) p(x)inP_(M)^(1)(x)nnP_(M)^(2)(x)p(x) \in P_{M}^{1}(x) \cap P_{M}^{2}(x)p(x)PM1(x)PM2(x), for all x X x X x in Xx \in XxX.
The following characterization result of common linear selections for two metric projections is an immediate consequence of Theorem 2.2 in [2].
Theorem A. Let M M MMM be a subspace of the linear space X X XXX which is proximinal with respect to each of the norms 1 , 2 1 , 2 ||||_(1),||||_(2)\left\|\left\|_{1},\right\|\right\|_{2}1,2 on X X XXX. Then the following assertions are equivalent:
1 P M 1 1 P M 1 1^(@)P_(M)^(1)1^{\circ} P_{M}^{1}1PM1 and P M 2 P M 2 P_(M)^(2)P_{M}^{2}PM2 admit a common linear selection;
2 2 2^(@)2^{\circ}2 The set ker P M 1 P M 1 P_(M)^(1)nnP_{M}^{1} \capPM1 ker P M 2 P M 2 P_(M)^(2)P_{M}^{2}PM2 contains a closed subspace N N NNN such that X = M N X = M N X=M o+NX=M \oplus NX=MN (algebraic direct sum);
3 3 3^(@)3^{\circ}3 The set ker P M 1 ker P M 2 P M 1 ker P M 2 P_(M)^(1)nn kerP_(M)^(2)P_{M}^{1} \cap \operatorname{ker} P_{M}^{2}PM1kerPM2 contains a closed subspace N N NNN such that X = M + N X = M + N X=M+NX=M+NX=M+N (algebraic and topological direct sum).
In the following we shall iluustrate Theorem A in a concrete setting.
First, we shall define a linear and continuous selection for the extension operator which preserves both the Lipschitz and uniform norms and then, using a Phelps' type result ([8], Theorem 3) we shall define a common selection for the operators of metric projection in the Lipschitz and in the uniform norms.
2. Let a , b , c , d R a , b , c , d R a,b,c,d in Ra, b, c, d \in Ra,b,c,dR be such that c < a < b < d c < a < b < d c < a < b < dc<a<b<dc<a<b<d and let X = [ c , d ] Y = [ a , b ] , x 0 [ a , b ] X = [ c , d ] Y = [ a , b ] , x 0 [ a , b ] X=[c,d]Y=[a,b],x_(0)in[a,b]X=[c, d] Y=[a, b], x_{0} \in[a, b]X=[c,d]Y=[a,b],x0[a,b] fixed and d ( x , y ) = | x y | d ( x , y ) = | x y | d(x,y)=|x-y|d(x, y)=|x-y|d(x,y)=|xy|.
A function f : Y R f : Y R f:Y rarr Rf: Y \rightarrow Rf:YR is called Lipschitz (on Y Y YYY ) if there exists K 0 K 0 K >= 0K \geqslant 0K0 such that
(4) | f ( x ) f ( y ) | K d ( x , y ) (4) | f ( x ) f ( y ) | K d ( x , y ) {:(4)|f(x)-f(y)| <= K*d(x","y):}\begin{equation*} |f(x)-f(y)| \leqslant K \cdot d(x, y) \tag{4} \end{equation*}(4)|f(x)f(y)|Kd(x,y)
for all x , y Y x , y Y x,y in Yx, y \in Yx,yY. The smallest constant K K KKK for which (4) holds is
(5) f L = sup { | f ( x ) f ( y ) | / d ( x , y ) : x , y Y , x y } (5) f L = sup { | f ( x ) f ( y ) | / d ( x , y ) : x , y Y , x y } {:(5)||f||_(L)=s u p{|f(x)-f(y)|//d(x","y):x","y inY","x!=y}:}\begin{equation*} \|f\|_{L}=\sup \{|f(x)-f(y)| / d(x, y): x, y \in \mathbf{Y}, x \neq y\} \tag{5} \end{equation*}(5)fL=sup{|f(x)f(y)|/d(x,y):x,yY,xy}
and is called the Lipschitz norm of the function f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y, where
(6) Lip 0 Y = { f ; f : [ a , b ] R , f is Lipschitz on Y , f ( x 0 ) = 0 } (6) Lip 0 Y = f ; f : [ a , b ] R , f  is Lipschitz on  Y , f x 0 = 0 {:(6)Lip_(0)Y={f;f:[a,b]rarr R,f" is Lipschitz on "Y,f(x_(0))=0}:}\begin{equation*} \operatorname{Lip}_{0} Y=\left\{f ; f:[a, b] \rightarrow R, f \text { is Lipschitz on } Y, f\left(x_{0}\right)=0\right\} \tag{6} \end{equation*}(6)Lip0Y={f;f:[a,b]R,f is Lipschitz on Y,f(x0)=0}
is the Banach space of all real valued Lipschitz functions defined on Y Y YYY and vanishing at the fixed point x 0 Y x 0 Y x_(0)in Yx_{0} \in Yx0Y.
The Banach space Lip 0 X 0 X _(0)X{ }_{0} X0X is defined in a similar way (the fixed point x 0 x 0 x_(0)x_{0}x0 is the same as for Lip 0 Y Lip 0 Y Lip_(0)Y\operatorname{Lip}_{0} YLip0Y )
Since Y Y YYY is a compact subset of R R RRR one can also define the uniform norm on Lip 0 I Lip 0 I Lip_(0)I\operatorname{Lip}_{0} \boldsymbol{I}Lip0I by
(7) f u = max { | f ( y ) | : y I } (7) f u = max { | f ( y ) | : y I } {:(7)||f||_(u)=max quad{|f(y)|:y in I}:}\begin{equation*} \|f\|_{u}=\max \quad\{|f(y)|: y \in I\} \tag{7} \end{equation*}(7)fu=max{|f(y)|:yI}
for f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y. The uniform norm on Lip Lip 0 X Lip 0 X Lip_(0)X\operatorname{Lip}_{0} XLip0X is defined similarly.

It holds:

Theorem 1. (a) For every f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y there exists F Lip 0 X F Lip 0 X F inLip_(0)XF \in \operatorname{Lip}_{0} XFLip0X such that
(8) F | X = f and F L = f L ; (8) F X = f  and  F L = f L ; {:(8)F|_(X^('))=f" and "||F||_(L)=||f||_(L);:}\begin{equation*} \left.F\right|_{X^{\prime}}=f \text { and }\|F\|_{L}=\|f\|_{L} ; \tag{8} \end{equation*}(8)F|X=f and FL=fL;
(b) For every f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y there exists F ¯ Lip 0 X F ¯ Lip 0 X bar(F)inLip_(0)X\bar{F} \in \operatorname{Lip}_{0} XF¯Lip0X such that
(9) F ¯ | Y = f and F ¯ u = f u . (9) F ¯ Y = f  and  F ¯ u = f u . {:(9)( bar(F))|_(Y)=f" and "|| bar(F)||_(u)=||f||_(u).:}\begin{equation*} \left.\bar{F}\right|_{Y}=f \text { and }\|\bar{F}\|_{u}=\|f\|_{u} . \tag{9} \end{equation*}(9)F¯|Y=f and F¯u=fu.
Proof. The assertion (a) is a particular case of a theorem of Mc Shane [4] (see also [1], [6]).
Denoting by
(10) E L ( f ) = { F Lip 0 X : F | Y = f and F L = f L { , (10) E L ( f ) = F Lip 0 X : F Y = f  and  F L = f L { , {:(10)E_(L)(f)={F inLip_(0)X:F|_(Y)=f" and "||F||_(L)=||f||_(L){,:}:}\begin{equation*} E_{L}(f)=\left\{F \in \operatorname{Lip}_{0} X:\left.F\right|_{Y}=f \text { and }\|F\|_{L}=\|f\|_{L}\{,\right. \tag{10} \end{equation*}(10)EL(f)={FLip0X:F|Y=f and FL=fL{,
the non-void set of all extensions of the function f f fff, preserving the Lipschitz norm, let
T : E L ( f ) E L ( f ) , T : E L ( f ) E L ( f ) , T:E_(L)(f)rarrE_(L)(f),T: E_{L}(f) \rightarrow E_{L}(f),T:EL(f)EL(f),
be the truncation operator defined, for F E L ( f ) F E L ( f ) F inE_(L)(f)F \in E_{L}(f)FEL(f), by T ( F ) = F ¯ T ( F ) = F ¯ T(F)= bar(F)T(F)=\bar{F}T(F)=F¯, where
(11) F ¯ ( x ) = f u if F ( x ) > f u , = F ( x ) if f u F ( x ) f w , = f u if F ( x ) < f u . (11) F ¯ ( x ) = f u  if  F ( x ) > f u , = F ( x )  if  f u F ( x ) f w , = f u  if  F ( x ) < f u . {:[(11) bar(F)(x)=||f||_(u)quad" if "quad F(x) > ||f||_(u)","],[=F(x)quad" if "-||f||_(u) <= F(x) <= ||f||_(w)","],[=-||f||_(u)" if "quadF^(')(x) < -||f||_(u).]:}\begin{align*} \bar{F}(x) & =\|f\|_{u} \quad \text { if } \quad F(x)>\|f\|_{u}, \tag{11}\\ & =F(x) \quad \text { if }-\|f\|_{u} \leqslant F(x) \leqslant\|f\|_{w}, \\ & =-\|f\|_{u} \text { if } \quad F^{\prime}(x)<-\|f\|_{u} . \end{align*}(11)F¯(x)=fu if F(x)>fu,=F(x) if fuF(x)fw,=fu if F(x)<fu.
Obviously, T ( F ) = F ¯ E L ( f ) T F = F ¯ E L ( f ) T(F^('))= bar(F)inE_(L)(f)T\left(F^{\prime}\right)=\bar{F} \in E_{L}(f)T(F)=F¯EL(f) and F ¯ u = f u F ¯ u = f u || bar(F)||_(u)=||f||_(u)\|\bar{F}\|_{u}=\|f\|_{u}F¯u=fu, proving the assertion (b) of the Theorem.
Denote by
(12) E u ( f ) = { F ¯ Lip 0 X : F ¯ | Y = f and F ¯ u = f u } , (12) E u ( f ) = F ¯ Lip 0 X : F ¯ Y = f  and  F ¯ u = f u , {:(12)E_(u)(f)={( bar(F))inLip_(0)X:( bar(F))|_(Y)=f" and "||( bar(F))||_(u)=||f||_(u)}",":}\begin{equation*} E_{u}(f)=\left\{\bar{F} \in \operatorname{Lip}_{0} X:\left.\bar{F}\right|_{Y}=f \text { and }\|\bar{F}\|_{u}=\|f\|_{u}\right\}, \tag{12} \end{equation*}(12)Eu(f)={F¯Lip0X:F¯|Y=f and F¯u=fu},
the set of all extensions of the function f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y which preserve the uniform norm of f f fff (this set is non-void by the assertion (b) of the above theorem).
Since the truncation F ¯ F ¯ bar(F)\bar{F}F¯ of the extension F F FFF of a function f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y. is *\cdot in E L ( f ) E u ( f ) E L ( f ) E u ( f ) E_(L)(f)nnE_(u)(f)E_{L}(f) \cap E_{u}(f)EL(f)Eu(f), it follows that
(13) E L ( f ) E u ( f ) , (13) E L ( f ) E u ( f ) , {:(13)E_(L)(f)nnE_(u)(f)!=O/",":}\begin{equation*} E_{L}(f) \cap E_{u}(f) \neq \emptyset, \tag{13} \end{equation*}(13)EL(f)Eu(f),
for every f Lip 0 Y f Lip 0 Y f inLip_(0)quad Yf \in \operatorname{Lip}_{0} \quad YfLip0Y and it holds the inclusion
(14) T ( E L ( f ) ) E u ( f ) , (14) T E L ( f ) E u ( f ) , {:(14)T(E_(L)(f))subE_(u)(f)",":}\begin{equation*} T\left(E_{L}(f)\right) \subset E_{u}(f), \tag{14} \end{equation*}(14)T(EL(f))Eu(f),
(the example given at the end of this paper shows that the inclusion can be strict).
A function e L : Lip 0 Y Lip 0 X e L : Lip 0 Y Lip 0 X e_(L):Lip_(0)Y rarrLip_(0)Xe_{L}: \operatorname{Lip}_{0} Y \rightarrow \operatorname{Lip}_{0} XeL:Lip0YLip0X is called a selection associated to the extension operator
E L : Lip 0 Y 2 Lip 0 X E L : Lip 0 Y 2 Lip 0 X E_(L):Lip_(0)Y rarr2^(Lip_(0)X)E_{L}: \operatorname{Lip}_{0} Y \rightarrow 2^{\operatorname{Lip}_{0} X}EL:Lip0Y2Lip0X
if e L ( f ) E L ( f ) e L ( f ) E L ( f ) e_(L)(f)inE_(L)(f)e_{L}(f) \in E_{L}(f)eL(f)EL(f), for every f Lip p 0 Y f Lip p 0 Y f in Lipp_(0)Yf \in \operatorname{Lip} p_{0} YfLipp0Y. A selection e u e u e_(u)e_{u}eu associated to the extension operator E u E u E_(u)E_{u}Eu is defined in a similar way.
Now we shall consider the following problem : there exists a common linear and continuous selection associated to the operators E L E L E_(L)E_{L}EL and E u E u E_(u)E_{u}Eu ?
The answer is given by the following theorem:
Theorem 2. The function e : Lip 0 Y Lip 9 X e : Lip 0 Y Lip 9 X e:Lip_(0)Y rarrLip_(9)Xe: \operatorname{Lip}_{0} Y \rightarrow \operatorname{Lip}_{9} Xe:Lip0YLip9X, given by the equality
(15) e ( f ) = 1 2 ( F 1 + F 2 ) , j Lip 0 Y , (15) e ( f ) = 1 2 F 1 + F 2 , j Lip 0 Y , {:(15)e(f)=(1)/(2)(F_(1)+F_(2))","quad j inLip_(0)Y",":}\begin{equation*} e(f)=\frac{1}{2}\left(F_{1}+F_{2}\right), \quad j \in \operatorname{Lip}_{0} Y, \tag{15} \end{equation*}(15)e(f)=12(F1+F2),jLip0Y,
where
F 1 ( x ) = max { f ( y ) f L | x y | : y Y } , F 1 ( x ) = max f ( y ) f L | x y | : y Y , F_(1)(x)=max{f(y)-||f||_(L)*|x-y|:y inY},F_{1}(x)=\max \left\{f(y)-\|f\|_{L} \cdot|x-y|: y \in \mathbf{Y}\right\},F1(x)=max{f(y)fL|xy|:yY},
(16) F 2 ( x ) = min { f ( y ) + f L | x y | : y Y } , (16) F 2 ( x ) = min f ( y ) + f L | x y | : y Y , {:(16)F_(2)(x)=min{f(y)+||f||_(L)*|x-y|:y in Y}",":}\begin{equation*} F_{2}(x)=\min \left\{f(y)+\|f\|_{L} \cdot|x-y|: y \in Y\right\}, \tag{16} \end{equation*}(16)F2(x)=min{f(y)+fL|xy|:yY},
is a common linear and continuous selection for the operators E L E L E_(L)E_{L}EL and E w E w E_(w)E_{w}Ew.
Proof. For f Lip 0 Y f Lip 0 Y f inLip_(0)Yf \in \operatorname{Lip}_{0} YfLip0Y, the functions given by (16) are extensions of the function f f fff, preserving the Lipschitz norm (see [1], [4], [8] for the properties of the functions F 1 , F 2 F 1 , F 2 F_(1),F_(2)F_{1}, F_{2}F1,F2 and of the set E L ( f ) E L ( f ) E_(L)(f)E_{L}(f)EL(f) ).
For x X x X x in Xx \in XxX we find
(17) c ( f ) ( x ) = f ( a ) for x [ c , a ) = f ( x ) for x [ a , b ] = Y = f ( b ) for x ( b , d ] (17) c ( f ) ( x ) = f ( a )  for  x [ c , a ) = f ( x )  for  x [ a , b ] = Y = f ( b )  for  x ( b , d ] {:[(17)c(f)(x)=f(a)" for "x in[c","a)],[=f(x)" for "x in[a","b]=Y],[=f(b)" for "x in(b","d]]:}\begin{align*} c(f)(x) & =f(a) \text { for } x \in[c, a) \tag{17}\\ & =f(x) \text { for } x \in[a, b]=\mathbf{Y} \\ & =f(b) \text { for } x \in(b, d] \end{align*}(17)c(f)(x)=f(a) for x[c,a)=f(x) for x[a,b]=Y=f(b) for x(b,d]
Obviously that e ( f ) L = f L e ( f ) L = f L ||e(f)||_(L)=||f||_(L)\|e(f)\|_{L}=\|f\|_{L}e(f)L=fL so that e ( f ) E L ( f ) e ( f ) E L ( f ) e(f)inE_(L)(f)e(f) \in E_{L}(f)e(f)EL(f). Furthermore, e ( f ) u = f u e ( f ) u = f u ||e(f)||_(u)=||f||_(u)\|e(f)\|_{u}=\|f\|_{u}e(f)u=fu so that e ( f ) e ( f ) e(f)e(f)e(f) belongs to the set E u ( f ) E u ( f ) E_(u)(f)E_{u}(f)Eu(f), too.
In [9] Theorem 4 and Corollary 5 , it was proved that e e eee is a linear selection, continuous with respect to the topology generated by the Lipschitz norm.
We shall show that e e eee is continuous with respect to the topology generated by the uniform norm, too. To this end, let ε > 0 ε > 0 epsi > 0\varepsilon>0ε>0 and let 0 < δ < ε 0 < δ < ε 0 < delta < epsi0<\delta<\varepsilon0<δ<ε. If f , g Lip 0 Y f , g Lip 0 Y f,g inLip_(0)Yf, g \in \operatorname{Lip}_{0} Yf,gLip0Y are such that f g u < δ f g u < δ ||f-g||_(u) < delta\|f-g\|_{u}<\deltafgu<δ, then e 1 f ) e ( g ) u == f g u < δ < ε e 1 f e ( g ) u == f g u < δ < ε {:||e_(1)f)-e(g)||_(u)==||f-g||_(u) < delta < epsi\left.\| e_{1} f\right)-e(g) \|_{u}= =\|f-g\|_{u}<\delta<\varepsilone1f)e(g)u==fgu<δ<ε, proving the continuity of e e eee with respect to the uniform norm. Theorem is proved.
There is a close relation between the selections associated to the extensions operators E L E L E_(L)E_{L}EL and E u E u E_(u)E_{u}Eu and those associated to the operators of metric projection (in the Lipschitz norm and respectively in the uniform norm) on the annihilator of the set Y Y YYY in Lip 0 X Lip 0 X Lip_(0)X\operatorname{Lip}_{0} XLip0X, i.e. on the subspace.
(18) Y = { G Lip 0 X : G | Y = 0 } . (18) Y = G Lip 0 X : G Y = 0 . {:(18)Y^(_|_)={G inLip_(0)X:G|_(Y)=0}.:}\begin{equation*} Y^{\perp}=\left\{G \in \operatorname{Lip}_{0} X:\left.G\right|_{Y}=0\right\} . \tag{18} \end{equation*}(18)Y={GLip0X:G|Y=0}.
Let P Y L , P Y n P Y L , P Y n P_(Y)^(L)_|_,P_(Y)^(n)_|_P_{Y}^{L} \perp, P_{Y}^{n} \perpPYL,PYn Lip 0 X 2 Y 0 X 2 Y 0X rarr2^(Y _|_)0 X \rightarrow 2^{Y \perp}0X2Y denote the operators of metric projection on Y Y Y^(_|_)Y^{\perp}Y (in the Lipschitz respectively in the uniform norm) and let
(19) d L ( F , Y ) = inf { F G L : G Y } , d u ( F , Y ) = inf { F G A : G Y } , (19) d L F , Y = inf F G L : G Y , d u F , Y = inf F G A : G Y , {:[(19)d_(L)(F,Y^(_|_))=i n f{||F-G||_(L):G inY^(_|_)}","],[d_(u)(F^('),Y^(_|_))=i n f{||F-G||_(A):G inY^(_|_)}","]:}\begin{gather*} d_{L}\left(F, Y^{\perp}\right)=\inf \left\{\|F-G\|_{L}: G \in Y^{\perp}\right\}, \tag{19}\\ d_{u}\left(F^{\prime}, Y^{\perp}\right)=\inf \left\{\|F-G\|_{A}: G \in Y^{\perp}\right\}, \end{gather*}(19)dL(F,Y)=inf{FGL:GY},du(F,Y)=inf{FGA:GY},
be the distances from an element F Lip 0 X F Lip 0 X F inLip_(0)XF \in \operatorname{Lip}_{0} XFLip0X to the subspace Y Y Y^(_|_)Y^{\perp}Y with respect to the Lipschitz and the uniform norm, respectively.
An element G 1 Y G 1 Y G_(1)inY^(_|_)G_{1} \in Y^{\perp}G1Y such that F G 1 L = d L ( F , Y ) F G 1 L = d L F , Y ||F-G_(1)||_(L)=d_(L)(F,Y^(_|_))\left\|F-G_{1}\right\|_{L}=d_{L}\left(F, Y^{\perp}\right)FG1L=dL(F,Y) is called an L L LLL - nearest point to F F FFF in Y Y Y^(_|_)Y^{\perp}Y and en element G 2 Y G 2 Y G_(2)inY^(_|_)G_{2} \in Y^{\perp}G2Y for which F G 2 == d u ( F , Y ) F G 2 == d u F , Y ||F-G_(2)||_(||)==d_(u)(F,Y^(_|_))\left\|F-G_{2}\right\|_{\|}= =d_{u}\left(F, Y^{\perp}\right)FG2==du(F,Y) is called a u u uuu - nearest point to F F FFF in Y Y Y^(_|_)\boldsymbol{Y}^{\perp}Y.
Theorem 3. (a) The equalities
(20) d L ( F , Y ) = F | Y L ; d n ( F , Y ) = F | Y N (20) d L F , Y = F Y L ; d n F , Y = F Y N {:(20)d_(L)(F^('),Y^(_|_))=||F^(')|_(Y)||_(L);quadd_(n)(F^('),Y^(_|_))=||F^(')|_(Y)||_(N):}\begin{equation*} \boldsymbol{d}_{L}\left(\boldsymbol{F}^{\prime}, \boldsymbol{Y}^{\perp}\right)=\left\|\left.\boldsymbol{F}^{\prime}\right|_{Y}\right\|_{L} ; \quad \boldsymbol{d}_{n}\left(\boldsymbol{F}^{\prime}, \boldsymbol{Y}^{\perp}\right)=\left\|\left.\boldsymbol{F}^{\prime}\right|_{Y}\right\|_{N} \tag{20} \end{equation*}(20)dL(F,Y)=F|YL;dn(F,Y)=F|YN
hold, for every F Lip 0 X F Lip 0 X F inLip_(0)XF \in \operatorname{Lip}_{0} XFLip0X;
(b) A function G 1 Y G 1 Y G_(1)inY^(_|_)G_{1} \in Y^{\perp}G1Y is an L L LLL-nearest point to F F F^(TT)F^{\top}F in Y Y Y^(_|_)Y^{\perp}Y if and only if G 1 = F H 1 G 1 = F H 1 G_(1)=F-H_(1)G_{1}=F-H_{1}G1=FH1, for a function H 1 E L ( F | X ) H 1 E L F X H_(1)inE_(L)(F|_(X))H_{1} \in E_{L}\left(\left.F\right|_{X}\right)H1EL(F|X);
(c) A function G 2 Y G 2 Y G_(2)inY^(_|_)G_{2} \in Y^{\perp}G2Y is a u-nearest point to F F FFF in Y Y Y^(_|_)Y^{\perp}Y if and only iff G 2 = F H 2 G 2 = F H 2 G_(2)=F-H_(2)G_{2}=F-H_{2}G2=FH2, for a function H 2 E n ( F | Y ) H 2 E n F Y H_(2)inE_(n)(F|_(Y))H_{2} \in E_{n}\left(\left.F\right|_{Y}\right)H2En(F|Y).
Proof. The first equality in (20) was proved in [5], Theorem 2 and Lemma 1. To prove the second one, observe that
F | Y H = F | Y G | Y n F G u , F Y H = F Y G Y n F G u , ||F|_(Y)||_(H)=||F|_(Y)-G|_(Y)||_(n) <= ||F-G||_(u),\left\|\left.F\right|_{Y}\right\|_{H}=\left\|\left.F\right|_{Y}-\left.G\right|_{Y}\right\|_{n} \leqslant\|F-G\|_{u},F|YH=F|YG|YnFGu,
for every G Y G Y G inY^(_|_)G \in Y^{\perp}GY and, taking the infimum with respect to G Y G Y G inY^(_|_)G \in Y^{\perp}GY, one obtains the inequality
F | Y N d n ( F , Y ) . F Y N d n F , Y . ||F^(')|_(Y)||_(N) <= d_(n)(F^('),Y^(_|_)).\left\|\left.F^{\prime}\right|_{Y}\right\|_{N} \leqslant d_{n}\left(F^{\prime}, \boldsymbol{Y}^{\perp}\right) .F|YNdn(F,Y).
On the other hand
d n ( F , Y ) F ( F H ) n = H N = F | Y N , d n F , Y F ( F H ) n = H N = F Y N , d_(n)(F,Y^(_|_)) <= ||F-(F-H)||_(n)=||H||_(N)=||F|_(Y)||_(N),d_{n}\left(F, Y^{\perp}\right) \leqslant\|F-(F-H)\|_{n}=\|H\|_{N}=\left\|\left.F\right|_{Y}\right\|_{N},dn(F,Y)F(FH)n=HN=F|YN,
for every H E n ( F | Y r ) H E n F Y r H inE_(n)(F|_(Y^(r)))H \in E_{n}\left(\left.F\right|_{Y^{r}}\right)HEn(F|Yr), implying F | Y n d n ( F , Y ) F Y n d n F , Y ||F|_(Y^(**))||_(n) >= d_(n)(F^('),Y^(_|_))\left\|\left.F\right|_{Y^{*}}\right\|_{n} \geqslant d_{n}\left(F^{\prime}, \boldsymbol{Y}^{\perp}\right)F|Yndn(F,Y).
The fact that every L L LLL-nearest point G 1 G 1 G_(1)G_{1}G1 to F F F^(_|_)F^{\perp}F in Y Y Y^(_|_)Y^{\perp}Y has the form G 1 == F H 1 G 1 == F H 1 G_(1)==F^(')-H_(1)G_{1}= =F^{\prime}-H_{1}G1==FH1, for an H 1 E L ( F | Y ) H 1 E L F Y H_(1)inE_(L)(F^(')|_(Y))H_{1} \in E_{L}\left(\left.F^{\prime}\right|_{Y}\right)H1EL(F|Y) was proved in [6], Lemma 1.
The assertion (c) can be proved in a similar way.
From Theorem 3 it follows that
(21) P Y L ( F ) = F E L ( F | Y ) ; P Y N F ) = F E n ( F | Y ) , (21) P Y L ( F ) = F E L F Y ; P Y N F = F E n F Y , {:(21){:P_(Y)^(L)_|_(F)=F-E_(L)(F^(')|_(Y));quadP_(Y)^(N)_|_F^('))=F-E_(n)(F|_(Y))",":}\begin{equation*} \left.P_{Y}^{L} \perp(F)=F-E_{L}\left(\left.F^{\prime}\right|_{Y}\right) ; \quad P_{Y}^{N} \perp F^{\prime}\right)=F-E_{n}\left(\left.F\right|_{Y}\right), \tag{21} \end{equation*}(21)PYL(F)=FEL(F|Y);PYNF)=FEn(F|Y),
and, taking into account relations (13) and (14), we find
(22) P Y u ( F ) P Y L ( F ) F T ( E L ( F | Y ) ) , (22) P Y u F P Y L ( F ) F T E L F Y , {:(22)P_(Y)^(u)_|_(F^('))nnP_(Y)^(L)_|_(F)sup F-T(E_(L)(F^(')|_(Y)))",":}\begin{equation*} P_{Y}^{u} \perp\left(F^{\prime}\right) \cap P_{Y}^{L} \perp(F) \supset F-T\left(E_{L}\left(\left.F^{\prime}\right|_{Y}\right)\right), \tag{22} \end{equation*}(22)PYu(F)PYL(F)FT(EL(F|Y)),
for every F Lip 0 X F Lip 0 X F inLip_(0)XF \in \operatorname{Lip}_{0} XFLip0X.
The following Corollary holds:
Corollary 1. (a) For every F F F inF \inF Lip 0 X 0 X _(0)X_{0} X0X there exists a function G 0 Y G 0 Y G_(0)inY^(_|_)G_{0} \in Y^{\perp}G0Y which is simultaneously an L L LLL-nearest point and a u u uuu-nearest point for F F FFF in Y Y Y^(_|_)Y^{\perp}Y;
(b) If F Lip 0 X F Lip 0 X F^(')inLip_(0)XF^{\prime} \in \operatorname{Lip}_{0} XFLip0X is such that F | Y L = F | Y u F Y L = F Y u ||F|_(Y)||_(L)=||F|_(Y)||_(u)\left\|\left.F\right|_{Y}\right\|_{L}=\left\|\left.F\right|_{Y}\right\|_{u}F|YL=F|Yu, then
(23) d L ( F , Y ) = d u ( F , Y ) ; (23) d L F , Y = d u F , Y ; {:(23)d_(L)(F^('),Y^(_|_))=d_(u)(F^('),Y^(_|_));:}\begin{equation*} d_{L}\left(F^{\prime}, Y^{\perp}\right)=d_{u}\left(F^{\prime}, Y^{\perp}\right) ; \tag{23} \end{equation*}(23)dL(F,Y)=du(F,Y);
(c) The function p : Lip 0 X Y p : Lip 0 X Y p:Lip_(0)X rarrY^(_|_)p: \operatorname{Lip}_{0} X \rightarrow Y^{\perp}p:Lip0XY given by
(24) p ( F ) = F e ( F | Y ) (24) p ( F ) = F e F Y {:(24)p(F)=F-e(F|_(Y)):}\begin{equation*} p(F)=F-e\left(\left.F\right|_{Y}\right) \tag{24} \end{equation*}(24)p(F)=Fe(F|Y)
is a common linear and continuous setection of the metric projection operators P Y L P Y L P_(Y)^(L)_|_P_{Y}^{L} \perpPYL and P Y u P Y u P_(Y)^(u)_|_P_{Y}^{u} \perpPYu.
(d) The subspace W = { e ( F | Y ) : F Lip 0 X } W = e F Y : F Lip 0 X W={e(F|_(Y)):F inLip_(0)X}W=\left\{e\left(\left.F\right|_{Y}\right): F \in \operatorname{Lip}_{0} X\right\}W={e(F|Y):FLip0X} is the algebraic and topological complement of Y Y Y _|_Y \perpY in Lip 0 X Lip 0 X Lip_(0)X\operatorname{Lip}_{0} XLip0X.
Furthermore, the assertions (c) and (d) are equivalent.
Proof. The assertions (a) and (b) are immediate consequences of Theorem 3. It is obvious that the selection p p ppp, given by (24) is linear and continuous (both in the Lipschitz and in the uniform norms). The fact that W W WWW is the complement of Y Y Y^(_|_)Y^{\perp}Y (with respect to the Lipschitz norm) was proved in [9], Corollary 7, but it follows also from Theorem 2.2 in [2]. The same theorem implies the equivalence of the assertions (c) and (d). Every function F Lip 0 X F Lip 0 X F inLip_(0)XF \in \operatorname{Lip}_{0} XFLip0X can be uniquely written in the form F == G + H F == G + H F==G+HF= =G+HF==G+H, with G Y G Y G inY^(_|_)G \in Y^{\perp}GY and H W H W H in WH \in WHW, where the functions G G GGG and H H HHH can be explicitly given by
G ( x ) = 0 for x [ a , b ] F ( x ) F ( a ) for c x < a = F ( x ) F ( b ) for b < x d G ( x ) = 0  for  x [ a , b ] F ( x ) F ( a )  for  c x < a = F ( x ) F ( b )  for  b < x d {:[G(x)=0quad" for "x in[a","b]],[≐F(x)-F(a)" for "c <= x < a],[=F(x)-F(b)" for "b < x <= d]:}\begin{aligned} G(x) & =0 \quad \text { for } x \in[a, b] \\ & \doteq F(x)-F(a) \text { for } c \leqslant x<a \\ & =F(x)-F(b) \text { for } b<x \leqslant d \end{aligned}G(x)=0 for x[a,b]F(x)F(a) for cx<a=F(x)F(b) for b<xd
and
H 1 x ) = F ( x ) for x [ a , b ] = F ( a ) for c x < a = F ( b ) for b < x d H 1 x = F ( x )  for  x [ a , b ] = F ( a )  for  c x < a = F ( b )  for  b < x d {:[{:H_(1)x)=F(x)" for "x in[a","b]],[=F^(')(a)" for "c <= x < a],[=F^(')(b)" for "b < x <= d]:}\begin{aligned} \left.H_{1} x\right) & =F(x) \text { for } x \in[a, b] \\ & =F^{\prime}(a) \text { for } c \leqslant x<a \\ & =F^{\prime}(b) \text { for } b<x \leqslant d \end{aligned}H1x)=F(x) for x[a,b]=F(a) for cx<a=F(b) for b<xd
Kemarks. 1 1 1^(@)1^{\circ}1 The assertions (c) and (d) from Corollary 1 are illustrations to the Theorem 2.2 in [2] (assertions (1), (2) and (4)).
2 2 2^(@)2^{\circ}2 The kernels of the applications P Y L P Y L P_(Y^('))^(L)P_{Y^{\prime}}^{L}PYL, and P Y u P Y u P_(Y^('))^(u)P_{Y^{\prime}}^{u}PYu are given by ker P Y L = { F Lip 0 X : F L = F | Y L } , P Y L = F Lip 0 X : F L = F Y L , quadP_(Y)^(L)={F inLip_(0)X:||F||_(L)=||F^(')|_(Y)||_(L)},quad\quad P_{Y}^{L}=\left\{F \in \operatorname{Lip}_{0} X:\|F\|_{L}=\left\|\left.F^{\prime}\right|_{Y}\right\|_{L}\right\}, \quadPYL={FLip0X:FL=F|YL}, respectively ker P L ⊥== { F Lip 0 X : F u = F | Y u } P L ⊥== F Lip 0 X : F u = F Y u quadP_(L)^('')⊥=={F inLip_(0)X:||F||_(u)=||F|_(Y)||_(u)}\quad P_{L}^{\prime \prime} \perp= =\left\{F \in \operatorname{Lip}_{0} X:\|F\|_{u}=\left\|\left.F\right|_{Y}\right\|_{u}\right\}PL⊥=={FLip0X:Fu=F|Yu}, and W W WWW is a closed subspace of Lip 0 X Lip 0 X Lip_(0)X\operatorname{Lip}_{0} XLip0X contained in ker P Y L ker P Y u P Y L ker P Y u P_(Y)^(L)^(_|_)nn kerP_(Y)^(u)_|_P_{Y}^{L}{ }^{\perp} \cap \operatorname{ker} P_{Y}^{u} \perpPYLkerPYu.
3 3 3^(@)3^{\circ}3 As Y Y Y^(_|_)Y^{\perp}Y and W W WWW are closed subspaces of Lip 0 X Lip 0 X Lip_(0)X\operatorname{Lip}_{0} XLip0X, which is a Banach space with respect to both of Lipschitz and uniform norms, it follows that their algebraic sum is also topological (a consequence of the open mapping theorem)
Example. Let Y = [ a , b ] = [ 1 , 3 ] , X = [ 2 , 5 ~ ] , x 0 = 2  Example. Let  Y = [ a , b ] = [ 1 , 3 ] , X = [ 2 , 5 ~ ] , x 0 = 2 " Example. Let "Y=[a,b]=[1,3],X=[-2, tilde(5)],x_(0)=2\text { Example. Let } Y=[a, b]=[1,3], X=[-2, \tilde{5}], x_{0}=2 Example. Let Y=[a,b]=[1,3],X=[2,5~],x0=2
The function
f ( x ) = x + 2 fer x [ 1 , 2 ] , = 2 x 4 for x ( 2 , 3 f ( x ) = x + 2  fer  x [ 1 , 2 ] , = 2 x 4  for  x ( 2 , 3 {:[f(x)=-x+2" fer "x in[1","2]","],[=2x-4quad" for "x in(2","3~|]:}\begin{aligned} f(x) & =-x+2 \text { fer } x \in[1,2], \\ & =2 x-4 \quad \text { for } x \in(2,3\rceil \end{aligned}f(x)=x+2 fer x[1,2],=2x4 for x(2,3
is in Lip 0 Y Lip 0 Y Lip_(0)Y\operatorname{Lip}_{0} YLip0Y and f L = f n = 2 f L = f n = 2 ||f||_(L)=||f||_(n)=2\|f\|_{L}=\|f\|_{n}=2fL=fn=2
The functions (16) from Theorem 2 are
F 1 ( x ) = 2 x 1 , x [ 2 , 1 ] and F 2 ( x ) = 2 x + 3 , x [ 2 , 1 ] = f ( x ) , x ( 1 , 3 ] = f ( x ) , x ( 1 , 3 ] = 2 x + 8 , x ( 3 , 5 ] = 2 x 4 , x ( 3 , 5 ] F 1 ( x ) = 2 x 1 , x [ 2 , 1 ]  and  F 2 ( x ) = 2 x + 3 , x [ 2 , 1 ] = f ( x ) , x ( 1 , 3 ] = f ( x ) , x ( 1 , 3 ] = 2 x + 8 , x ( 3 , 5 ] = 2 x 4 , x ( 3 , 5 ] {:[F_(1)(x)=2x-1","x in[-2","1]" and "F_(2)(x)=-2x+3","x in[-2","1]],[=f(x)","x in(1","3]=f(x)","x in(1","3]],[=-2x+8","x in(3","5]=2x-4","x in(3","5]]:}\begin{aligned} F_{1}(x) & =2 x-1, x \in[-2,1] \text { and } & F_{2}(x) & =-2 x+3, x \in[-2,1] \\ & =f(x), x \in(1,3] & & =f(x), x \in(1,3] \\ & =-2 x+8, x \in(3,5] & & =2 x-4, x \in(3,5] \end{aligned}F1(x)=2x1,x[2,1] and F2(x)=2x+3,x[2,1]=f(x),x(1,3]=f(x),x(1,3]=2x+8,x(3,5]=2x4,x(3,5]
Every function F E L ( f ) F E L ( f ) F inE_(L)(f)F \in E_{L}(f)FEL(f) verifies the inequalities
F 1 ( x ) F ( x ) F 2 ( x ) , x [ 2 , 5 ] . F 1 ( x ) F ( x ) F 2 ( x ) , x [ 2 , 5 ] . F_(1)(x) <= F(x) <= F_(2)(x),quad x in[-2,5].F_{1}(x) \leqslant F(x) \leqslant F_{2}(x), \quad x \in[-2,5] .F1(x)F(x)F2(x),x[2,5].
implying that
T ( F 1 ) T ( F ) T ( F 2 ) . T F 1 T F T F 2 . T(F_(1)) <= T(F^(')) <= T(F_(2)).T\left(F_{1}\right) \leqslant T\left(F^{\prime}\right) \leqslant T\left(F_{2}\right) .T(F1)T(F)T(F2).
We have T ( F 2 ) ( x ) = F ¯ 2 ( x ) = 2 , x [ 2 , 1 / 2 ] T F 2 ( x ) = F ¯ 2 ( x ) = 2 , x [ 2 , 1 / 2 ] T(F_(2))(x)= bar(F)_(2)(x)=2,quad x in[-2,1//2]T\left(F_{2}\right)(x)=\bar{F}_{2}(x)=2, \quad x \in[-2,1 / 2]T(F2)(x)=F¯2(x)=2,x[2,1/2]
= 2 x + 3 , x ( 1 / 2 , 1 ) = f ( x ) , x [ 1 , 3 ] = 2 , x ( 3 , 5 ] . = 2 x + 3 ,      x ( 1 / 2 , 1 ) = f ( x ) ,      x [ 1 , 3 ] = 2 ,      x ( 3 , 5 ] . {:[=-2x+3",",x(1//2","1)],[=f(x)",",x in[1","3]],[=2",",x in(3","5].]:}\begin{array}{ll} =-2 x+3, & x(1 / 2,1) \\ =f(x), & x \in[1,3] \\ =2, & x \in(3,5] . \end{array}=2x+3,x(1/2,1)=f(x),x[1,3]=2,x(3,5].
Let
H ( x ) = 2 , x [ 2 , 3 / 4 ] = 4 x + 5 , x ( 3 / 4 , 1 ] = F ¯ 2 ( x ) , x ( 1 , 5 ] . H ( x ) = 2 , x [ 2 , 3 / 4 ] = 4 x + 5 , x ( 3 / 4 , 1 ] = F ¯ 2 ( x ) , x ( 1 , 5 ] . {:[H(x)=2","x in[-2","3//4]],[=-4x+5","x in(3//4","1]],[= bar(F)_(2)(x)","x in(1","5].]:}\begin{aligned} H(x) & =2, & & x \in[-2,3 / 4] \\ & =-4 x+5, & & x \in(3 / 4,1] \\ & =\bar{F}_{2}(x), & & x \in(1,5] . \end{aligned}H(x)=2,x[2,3/4]=4x+5,x(3/4,1]=F¯2(x),x(1,5].
Then H L = 4 H L = 4 ||H||_(L)=4\|H\|_{L}=4HL=4 and H u = 2 H u = 2 ||H||_(u)=2\|H\|_{u}=2Hu=2 so that H T ( E L ( f ) ) H T E L ( f ) H!in T(E_(L)(f))H \notin T\left(E_{L}(f)\right)HT(EL(f)) but H E u ( f ) H E u ( f ) H inE_(u)(f)H \in E_{u}(f)HEu(f). This example shows that the inclusion (11) can be strict.
Also
Y = { G Lip 0 [ 2 , 5 ] : G | [ 1 , 3 ] = 0 } . Y = G Lip 0 [ 2 , 5 ] : G [ 1 , 3 ] = 0 . Y^(_|_)={G inLip_(0)[-2,5]:G|_([1,3])=0}.Y^{\perp}=\left\{G \in \operatorname{Lip}_{0}[-2,5]:\left.G\right|_{[1,3]}=0\right\} .Y={GLip0[2,5]:G|[1,3]=0}.
If F Lip ) 0 [ 2 , 5 ] F Lip ) 0 [ 2 , 5 ] F in Lip)_(0)[-2,5]F \in \operatorname{Lip})_{0}[-2,5]FLip)0[2,5] is such that F | [ 1 , 3 ] = f F [ 1 , 3 ] = f F|_([1,3])=f\left.F\right|_{[1,3]}=fF|[1,3]=f then F | Y L = F | Y L F Y L = F Y L ||F|_(Y)||_(L)=||F|_(Y)||_(L)\left\|\left.F\right|_{Y}\right\|_{L}=\left\|\left.F\right|_{Y}\right\|_{L}F|YL=F|YL and, consequently,
d L ( F , Y ) = d n ( F , Y ) = 2 , d L F , Y = d n F , Y = 2 , d_(L)(F^('),Y^(_|_))=d_(n)(F^('),Y^(_|_))=2,d_{L}\left(F^{\prime}, \boldsymbol{Y}^{\perp}\right)=d_{n}\left(F^{\prime}, \boldsymbol{Y}^{\perp}\right)=2,dL(F,Y)=dn(F,Y)=2,
showing that condition (23) from Corollary 1 is fulfilled.

REFERENCES

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Receined 4.V. 1993

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1993

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