:: by Yatsuka Nakamura and Andrzej Trybulec

::

:: Received September 11, 2002

:: Copyright (c) 2002-2019 Association of Mizar Users

theorem Th1: :: TOPMETR3:1

for X being non empty MetrSpace

for S being sequence of X

for F being Subset of (TopSpaceMetr X) st S is convergent & ( for n being Nat holds S . n in F ) & F is closed holds

lim S in F

for S being sequence of X

for F being Subset of (TopSpaceMetr X) st S is convergent & ( for n being Nat holds S . n in F ) & F is closed holds

lim S in F

proof end;

theorem Th2: :: TOPMETR3:2

for X, Y being non empty MetrSpace

for f being Function of (TopSpaceMetr X),(TopSpaceMetr Y)

for S being sequence of X holds f * S is sequence of Y

for f being Function of (TopSpaceMetr X),(TopSpaceMetr Y)

for S being sequence of X holds f * S is sequence of Y

proof end;

theorem Th3: :: TOPMETR3:3

for X, Y being non empty MetrSpace

for f being Function of (TopSpaceMetr X),(TopSpaceMetr Y)

for S being sequence of X

for T being sequence of Y st S is convergent & T = f * S & f is continuous holds

T is convergent

for f being Function of (TopSpaceMetr X),(TopSpaceMetr Y)

for S being sequence of X

for T being sequence of Y st S is convergent & T = f * S & f is continuous holds

T is convergent

proof end;

theorem Th4: :: TOPMETR3:4

for s being Real_Sequence

for S being sequence of RealSpace st s = S holds

( ( s is convergent implies S is convergent ) & ( S is convergent implies s is convergent ) & ( s is convergent implies lim s = lim S ) )

for S being sequence of RealSpace st s = S holds

( ( s is convergent implies S is convergent ) & ( S is convergent implies s is convergent ) & ( s is convergent implies lim s = lim S ) )

proof end;

theorem Th5: :: TOPMETR3:5

for a, b being Real

for s being Real_Sequence st rng s c= [.a,b.] holds

s is sequence of (Closed-Interval-MSpace (a,b))

for s being Real_Sequence st rng s c= [.a,b.] holds

s is sequence of (Closed-Interval-MSpace (a,b))

proof end;

theorem Th6: :: TOPMETR3:6

for a, b being Real

for S being sequence of (Closed-Interval-MSpace (a,b)) st a <= b holds

S is sequence of RealSpace

for S being sequence of (Closed-Interval-MSpace (a,b)) st a <= b holds

S is sequence of RealSpace

proof end;

theorem Th7: :: TOPMETR3:7

for a, b being Real

for S1 being sequence of (Closed-Interval-MSpace (a,b))

for S being sequence of RealSpace st S = S1 & a <= b holds

( ( S is convergent implies S1 is convergent ) & ( S1 is convergent implies S is convergent ) & ( S is convergent implies lim S = lim S1 ) )

for S1 being sequence of (Closed-Interval-MSpace (a,b))

for S being sequence of RealSpace st S = S1 & a <= b holds

( ( S is convergent implies S1 is convergent ) & ( S1 is convergent implies S is convergent ) & ( S is convergent implies lim S = lim S1 ) )

proof end;

theorem Th8: :: TOPMETR3:8

for a, b being Real

for s being Real_Sequence

for S being sequence of (Closed-Interval-MSpace (a,b)) st S = s & a <= b & s is convergent holds

( S is convergent & lim s = lim S )

for s being Real_Sequence

for S being sequence of (Closed-Interval-MSpace (a,b)) st S = s & a <= b & s is convergent holds

( S is convergent & lim s = lim S )

proof end;

theorem :: TOPMETR3:9

for a, b being Real

for s being Real_Sequence

for S being sequence of (Closed-Interval-MSpace (a,b)) st S = s & a <= b & s is non-decreasing holds

S is convergent

for s being Real_Sequence

for S being sequence of (Closed-Interval-MSpace (a,b)) st S = s & a <= b & s is non-decreasing holds

S is convergent

proof end;

theorem :: TOPMETR3:10

for a, b being Real

for s being Real_Sequence

for S being sequence of (Closed-Interval-MSpace (a,b)) st S = s & a <= b & s is non-increasing holds

S is convergent

for s being Real_Sequence

for S being sequence of (Closed-Interval-MSpace (a,b)) st S = s & a <= b & s is non-increasing holds

S is convergent

proof end;

theorem Th11: :: TOPMETR3:11

for R being non empty Subset of REAL st R is bounded_above holds

ex s being Real_Sequence st

( s is non-decreasing & s is convergent & rng s c= R & lim s = upper_bound R )

ex s being Real_Sequence st

( s is non-decreasing & s is convergent & rng s c= R & lim s = upper_bound R )

proof end;

theorem Th12: :: TOPMETR3:12

for R being non empty Subset of REAL st R is bounded_below holds

ex s being Real_Sequence st

( s is non-increasing & s is convergent & rng s c= R & lim s = lower_bound R )

ex s being Real_Sequence st

( s is non-increasing & s is convergent & rng s c= R & lim s = lower_bound R )

proof end;

theorem Th13: :: TOPMETR3:13

for X being non empty MetrSpace

for f being Function of I[01],(TopSpaceMetr X)

for F1, F2 being Subset of (TopSpaceMetr X)

for r1, r2 being Real st 0 <= r1 & r2 <= 1 & r1 <= r2 & f . r1 in F1 & f . r2 in F2 & F1 is closed & F2 is closed & f is continuous & F1 \/ F2 = the carrier of X holds

ex r being Real st

( r1 <= r & r <= r2 & f . r in F1 /\ F2 )

for f being Function of I[01],(TopSpaceMetr X)

for F1, F2 being Subset of (TopSpaceMetr X)

for r1, r2 being Real st 0 <= r1 & r2 <= 1 & r1 <= r2 & f . r1 in F1 & f . r2 in F2 & F1 is closed & F2 is closed & f is continuous & F1 \/ F2 = the carrier of X holds

ex r being Real st

( r1 <= r & r <= r2 & f . r in F1 /\ F2 )

proof end;

theorem Th14: :: TOPMETR3:14

for n being Nat

for p1, p2 being Point of (TOP-REAL n)

for P, P1 being non empty Subset of (TOP-REAL n) st P is_an_arc_of p1,p2 & P1 is_an_arc_of p2,p1 & P1 c= P holds

P1 = P

for p1, p2 being Point of (TOP-REAL n)

for P, P1 being non empty Subset of (TOP-REAL n) st P is_an_arc_of p1,p2 & P1 is_an_arc_of p2,p1 & P1 c= P holds

P1 = P

proof end;

theorem :: TOPMETR3:15

for P, P1 being non empty compact Subset of (TOP-REAL 2) st P is being_simple_closed_curve & P1 is_an_arc_of W-min P, E-max P & P1 c= P & not P1 = Upper_Arc P holds

P1 = Lower_Arc P

P1 = Lower_Arc P

proof end;