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The meaning of relativity in spacetimes of constant curvature
Nuclear Physics B (Proc. Suppl.) 6 (1989) 381-383 North-Holland, Amsterdam
381
T H E M E A N I N G O F R E L A T I V I T Y IN S P A C E T I M E S O F C O N S T A N T C U R V A T U R E Han-Ying G U O Institute of Theoretical Physics, Academia Sinica, P.O. Box 2735, Beijing, China We show that Einstein's principles of the special relativity can be realized not only on the Minkowskian spacetime but also on the spacetimes of non-zero constant curvature.
It is well-established principles
to realize Einstein's
flat Minkowskian
space-time.
group plays an extremely realization.
that these principles,
the speed of light, space-times
+ AnirnjsxrxS~-2(x,x)]dxidx j ,
The Poincar~
in addition,
i.e. the principle of
where A is the constant curvature of ~ A and (nlj} i,J = 0 ..... 3 = diag (I,-I,-i,-I).
of invariance of
can also be realized on the
of constant curvature on the same
footing with the one on the Minkowskian
space-
the fractionally
linear transformations
anti-de Sitter group S0(3,2) Sitter group S0(4,1)
Under of the
[for A < O, the de
(for A > 0), and the
Poincar~ group ISO(3,1)
(for A = 0):
This is, in fact, an analogy with the
well-known
realization
Riemannian
and Lobachevskian
this talk, we present realization.
x i ~ x~i = ¢ 1 / 2 ( a , a ) ¢ - l ( a , x
of the Euclidean, geometries.
,
the main results on this
Dji = L i i + An k aiakLj[¢(a,a ) + ¢I/2(a,a)]-I
Riemannian
L = ( L ~ ) i , j = O. . . . . 3 c SO(3.1) , the condition invariant.
Fundamental theorem: 4-dimensional
space-times
There e x i s t t h r e e
the principle
I and the metric II are
The coordinate
systems
{x i} are
inertial and the geodesics of DA are (projective)
~ A of constant
which satisfy necessarily
sufficiently
{III)
and Lobachevskian
geometries.
and
straight
lines which describe the
inertial motions of free particles.
the principle of relativity and
The causality between two events A(a i) and B(b i) can be classified by the quantity
of invariance of the speed of
They hold the condition A2(a,b)=[~i3¢-l(a,b)
¢(x,x)=l
D
It should be easy to prove them
the Euclidean,
curvature,
) (xiai)D
In
if it would be kept in mind the analogies among
light.
(II)
important role in this
We have found {I-4},
relativity and the principle
time.
ds 2 = [~ij¢-l(x,x)
of the special relativity on the
i i - Anijx x >0,
i,j=O ..... 3.
A ~irnjs a and have the Beltrami-Minkowskian
metric
0920-5632/89/$03.50 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
+
(I} r.s o ¢ -(a 'b} "l(a-b)i[a-bJ "" " " i
P
382
H.-E Guo
/ Relativity in spacetimes o f constant curvature
which is invariant under the transformation III.
x
o
~o
~ X
1/2,
= ~Z
,
ta, a;~
-1,
ta, x}x ° ,
A pair of points ACa i) and B(b i) are said
to be tlme-llke, space-llke or light- llke,
x~
~
x~~ =
~l/29a, a)~lca, x) Cx~
- a~)O~
,
according to A2(a,b) > O, < O, or = O, respectively.
~ + 1/2 -I o8 = R~~ + A ~ a a ~ a~R~[¢z(a'a) CZ (a,a)]
The proper interval between A(a i)
and B(b i} is the length of the geodesic segment AB, s(a,b) = I ds: AB
(R~)~,~=I,2, 3 e S0(3) where a
A
< o
Stime_llke(a,b)
Sspace_like(a,b)
IAl-1/2arctg
llxl 1/2^rth C¢1~1 IACa,b)l)
C¢l~lCa,b) l) = 0
A(a,b)
ilA{a,b) l
i
s a t i s f y the above conditions, and the
conditions, the metric, and the r a t i o
RZ(x) = cz(x,x)c-1(x.x)
are all invariant,
i.e. Z is transformed onto
itself. A-I/2Arth >o
C~l~(a,b)l
.FA-I/2arctg
Two events A(a i} and B(b £) are said to be
(wT~Ca,b)l)
simultaneous if they are on the same space-llke hypersurface Z and the proper distance element
In order to define the simultaneity and the
on Z is given by
proper distance, we consider the subgroup of dl2 = -dsZlz = R 2(x)d~ 2 .
space-like transformations which transform
0
space coordinates onto themselves. Such a Z may be called the simultaneous spaceTheorem:
In the ~)A' there exists a kind
like hypersurface. The proper time of an ideal clock located
of space-like hypersurfaces Z characterized by
at a point on Z can be calculated.
the following conditions
It turns
out to be x°~-I/2(x,x) = const. IAI -I/2 arc sin(~r~[~-i/2(x,x)xO), ~E(x,x) = I - Anc~sx=x ~ > 0 ,
A < 0 ,
=,~=1,2,3 T=
where (~}~8)~=i,2,3 = diag(-l,-l,-l}.
x
0
h=O
On the
Z, the metric of ~)A is reduced to
A -I/2 Arsh(v~cr-I/2(x,x)x°) ,
A > 0 .
dsZlz = ~-l(x,x)~Z(x,x)d~oz , This proper time may be chosen to parameterize the family of the simultaneous space-like d~Zo 12o = -[W~8~Z l(x'x) +
hypersurfaces,
Z z.
Then the metric on D A
gives rise to the metric on E : + k ~ f n ~ x ~ x ° ~ Z (X, X) ]dx~dx B.
Under the transformations of the space-like subgroup S0(3,1)
(for A O)
and ISO[3) (for A = 0):
,
T
H.-Y. Guo / Relativity in spacetimes of constant curvature
dsZlX
dz2-R2(T)d~ ,
=
hypersurfaces,
383
ZT, for A = 0 shows a plcture of
expandlng universe, whlch may play some role in R2(T)
= cos2Vr[X'FT
(A < 0)
, the very early stage of our universe.
=
z
(x
=
o)
,
= ch2~A T (X>0)
. I.
O. K. Lu, unpublished (1970); O. K. Lu, Z. L. Zhou and H. Y. Guo, Acta Physlca Slnlca 23, 225 (1970).
2.
H. Y. Guo, Kexue Tongbao 22, 487 (1977).
3.
Z. L. Zhou, J. S. Chen, P. HuanE, L. N. ZhanE, and H. Y. Guo, Sclentia Sinica 6, 588 (1979).
4.
G. Y. Li and H. Y. Guo, Acta Physica Sinica 3_!I, 1501 (1982).
Obviously, for the case of A = O, all these results are well-known in special relativity so that the cases of A ~ 0 may be taken as the special relativities of Rlemannlan and Lobachevskian version respectively.
In
addition, the family of simultaneous space-like
381
T H E M E A N I N G O F R E L A T I V I T Y IN S P A C E T I M E S O F C O N S T A N T C U R V A T U R E Han-Ying G U O Institute of Theoretical Physics, Academia Sinica, P.O. Box 2735, Beijing, China We show that Einstein's principles of the special relativity can be realized not only on the Minkowskian spacetime but also on the spacetimes of non-zero constant curvature.
It is well-established principles
to realize Einstein's
flat Minkowskian
space-time.
group plays an extremely realization.
that these principles,
the speed of light, space-times
+ AnirnjsxrxS~-2(x,x)]dxidx j ,
The Poincar~
in addition,
i.e. the principle of
where A is the constant curvature of ~ A and (nlj} i,J = 0 ..... 3 = diag (I,-I,-i,-I).
of invariance of
can also be realized on the
of constant curvature on the same
footing with the one on the Minkowskian
space-
the fractionally
linear transformations
anti-de Sitter group S0(3,2) Sitter group S0(4,1)
Under of the
[for A < O, the de
(for A > 0), and the
Poincar~ group ISO(3,1)
(for A = 0):
This is, in fact, an analogy with the
well-known
realization
Riemannian
and Lobachevskian
this talk, we present realization.
x i ~ x~i = ¢ 1 / 2 ( a , a ) ¢ - l ( a , x
of the Euclidean, geometries.
,
the main results on this
Dji = L i i + An k aiakLj[¢(a,a ) + ¢I/2(a,a)]-I
Riemannian
L = ( L ~ ) i , j = O. . . . . 3 c SO(3.1) , the condition invariant.
Fundamental theorem: 4-dimensional
space-times
There e x i s t t h r e e
the principle
I and the metric II are
The coordinate
systems
{x i} are
inertial and the geodesics of DA are (projective)
~ A of constant
which satisfy necessarily
sufficiently
{III)
and Lobachevskian
geometries.
and
straight
lines which describe the
inertial motions of free particles.
the principle of relativity and
The causality between two events A(a i) and B(b i) can be classified by the quantity
of invariance of the speed of
They hold the condition A2(a,b)=[~i3¢-l(a,b)
¢(x,x)=l
D
It should be easy to prove them
the Euclidean,
curvature,
) (xiai)D
In
if it would be kept in mind the analogies among
light.
(II)
important role in this
We have found {I-4},
relativity and the principle
time.
ds 2 = [~ij¢-l(x,x)
of the special relativity on the
i i - Anijx x >0,
i,j=O ..... 3.
A ~irnjs a and have the Beltrami-Minkowskian
metric
0920-5632/89/$03.50 © Elsevier Science Publishers B.V. (North-Holland Physics Publishing Division)
+
(I} r.s o ¢ -(a 'b} "l(a-b)i[a-bJ "" " " i
P
382
H.-E Guo
/ Relativity in spacetimes o f constant curvature
which is invariant under the transformation III.
x
o
~o
~ X
1/2,
= ~Z
,
ta, a;~
-1,
ta, x}x ° ,
A pair of points ACa i) and B(b i) are said
to be tlme-llke, space-llke or light- llke,
x~
~
x~~ =
~l/29a, a)~lca, x) Cx~
- a~)O~
,
according to A2(a,b) > O, < O, or = O, respectively.
~ + 1/2 -I o8 = R~~ + A ~ a a ~ a~R~[¢z(a'a) CZ (a,a)]
The proper interval between A(a i)
and B(b i} is the length of the geodesic segment AB, s(a,b) = I ds: AB
(R~)~,~=I,2, 3 e S0(3) where a
A
< o
Stime_llke(a,b)
Sspace_like(a,b)
IAl-1/2arctg
llxl 1/2^rth C¢1~1 IACa,b)l)
C¢l~lCa,b) l) = 0
A(a,b)
ilA{a,b) l
i
s a t i s f y the above conditions, and the
conditions, the metric, and the r a t i o
RZ(x) = cz(x,x)c-1(x.x)
are all invariant,
i.e. Z is transformed onto
itself. A-I/2Arth >o
C~l~(a,b)l
.FA-I/2arctg
Two events A(a i} and B(b £) are said to be
(wT~Ca,b)l)
simultaneous if they are on the same space-llke hypersurface Z and the proper distance element
In order to define the simultaneity and the
on Z is given by
proper distance, we consider the subgroup of dl2 = -dsZlz = R 2(x)d~ 2 .
space-like transformations which transform
0
space coordinates onto themselves. Such a Z may be called the simultaneous spaceTheorem:
In the ~)A' there exists a kind
like hypersurface. The proper time of an ideal clock located
of space-like hypersurfaces Z characterized by
at a point on Z can be calculated.
the following conditions
It turns
out to be x°~-I/2(x,x) = const. IAI -I/2 arc sin(~r~[~-i/2(x,x)xO), ~E(x,x) = I - Anc~sx=x ~ > 0 ,
A < 0 ,
=,~=1,2,3 T=
where (~}~8)~=i,2,3 = diag(-l,-l,-l}.
x
0
h=O
On the
Z, the metric of ~)A is reduced to
A -I/2 Arsh(v~cr-I/2(x,x)x°) ,
A > 0 .
dsZlz = ~-l(x,x)~Z(x,x)d~oz , This proper time may be chosen to parameterize the family of the simultaneous space-like d~Zo 12o = -[W~8~Z l(x'x) +
hypersurfaces,
Z z.
Then the metric on D A
gives rise to the metric on E : + k ~ f n ~ x ~ x ° ~ Z (X, X) ]dx~dx B.
Under the transformations of the space-like subgroup S0(3,1)
(for A
and ISO[3) (for A = 0):
,
T
H.-Y. Guo / Relativity in spacetimes of constant curvature
dsZlX
dz2-R2(T)d~ ,
=
hypersurfaces,
383
ZT, for A = 0 shows a plcture of
expandlng universe, whlch may play some role in R2(T)
= cos2Vr[X'FT
(A < 0)
, the very early stage of our universe.
=
z
(x
=
o)
,
= ch2~A T (X>0)
. I.
O. K. Lu, unpublished (1970); O. K. Lu, Z. L. Zhou and H. Y. Guo, Acta Physlca Slnlca 23, 225 (1970).
2.
H. Y. Guo, Kexue Tongbao 22, 487 (1977).
3.
Z. L. Zhou, J. S. Chen, P. HuanE, L. N. ZhanE, and H. Y. Guo, Sclentia Sinica 6, 588 (1979).
4.
G. Y. Li and H. Y. Guo, Acta Physica Sinica 3_!I, 1501 (1982).
Obviously, for the case of A = O, all these results are well-known in special relativity so that the cases of A ~ 0 may be taken as the special relativities of Rlemannlan and Lobachevskian version respectively.
In
addition, the family of simultaneous space-like