1. Introduction
Definition 1. For every coordinate system, there is no immediate reason for pre- ferring certain systems of co-ordinates to others.
Definition 2. I named 
“Binary Law”.
Definition 3. 
is established.
Definition 4. 
is established.
Definition 5. 
is established.
Definition 6. Convariant and contravariant tensor of the first rank 
satisfied 
[1] .
Definition 7. Tensor of rank zero 
satisfied 
[1] .
Definition 8. If tensor 
satisfied
, this tensor 
was named sym- metric tensor [1] .
Definition 9. Convariant differentiation for Convariant Bector 
satisfied 
[1] .
Definition 10. 
and ![]()
are establishment [2] .
Definition 11. Convariant differentiation for contravariant bector ![]()
satisfied ![]()
[2] .
Definition 12. Convariant differentiation for Scalar ![]()
satisfied ![]()
[2] .
2. About Reason to Take Binary Law into Consideration
We will have to receive existence of the absolute coordinate system if Definition 1 is not established. Therefore, we must accept establishment of Definition 1.
Proposition 1. Definition 1 is not established for all coordinate systems ![]()
Proof: All coordinate systems ![]()
thinks about ![]()
in a standard and can divide it into two next groups.
![]()
![]()
(1)
I think that I change the coordinate systems of the standard ![]()
of (1) for all coordi- nate systems ![]()
sequentially now. By the way, the difference cannot occur between each conclusion to be provided here if Definition 1 is established. This reason is that all coordinate systems ![]()
has a privilege of the equality each other if Definition 1 is established. At first (1) gets an invariable conclusion for ![]()
exchange. Therefore, at least (1) must get an invariable conclusion for the next ![]()
exchange if Definition 1 is established. Here, I get
![]()
![]()
(2)
by ![]()
exchange from (1). Therefore, (2) must be equal with (1) if Definition 1 is established. By the way, ![]()
of (1) is equal with ![]()
of (2), but ![]()
of (1) is not equal with ![]()
of (2). In other words, (2) is not equal with (1). Therefore, Definition 1 is not established for all coor- dinate systems![]()
.
-End Proof
Establishment of Proposition 1 is a problem in thinking that Definition 1 must be established. Therefore, I aim at getting establishment of Definition 1 for all coordinate systems![]()
.
Proposition 2. If all coordinate systems ![]()
satisfies ![]()
, Definition 1 is established for all coordinate systems![]()
.
Proof: I get
![]()
![]()
(3)
![]()
![]()
(4)
from (1), (2) if all coordinate systems ![]()
satisfies
![]()
(5)
(3) is equal with (4) here. In other words, (2) is equal with (1) if all coordinate sys- tems ![]()
satisfies (5). Therefore, Definition 1 is established for all coordi- nate systems ![]()
if all coordinate systems ![]()
satisfies (5).
-End Proof
Proposition 3. If all coordinate systems ![]()
satisfies ![]()
, all coordinate systems ![]()
shifts to only two of ![]()
Proof: If all coordinate systems ![]()
satisfies (5), I get ![]()
than all coordinate systems![]()
.
-End Proof
Proposition 4. If ![]()
is established, ![]()
is esta- blished.
Proof: I get
![]()
(6)
from (5), (7) if I assume establishment of
![]()
(7)
when (5) is established. Because (6) includes contradiction,
![]()
(8)
is established when (5) is established.
-End Proof
Proposition 5. If ![]()
is established, ![]()
are established.
Proof: When (5) is established, (8) is established from Proposition 4. Therefore, I get
![]()
(9)
from (8), (10) if I assume establishment of ![]()
when (5) is established. I can rewrite ![]()
as
![]()
(10)
here. When (5) is established, I get
![]()
(11)
from Definition 3. Because (9) includes contradiction for (11),
![]()
(12)
is established when (5) is established.
Similary, I get
![]()
(13)
from (8), (14) if I assume establishment of ![]()
when (5) is established. I can rewrite ![]()
as
![]()
(14)
here. When (5) is established, I get
![]()
(15)
from Definition 4. Because (13) includes contradiction for (15),
![]()
(16)
is established when (5) is established.
Similary, I get
![]()
(17)
from (8), (18) if I assume establishment of ![]()
when (5) is established. I can rewrite ![]()
as
![]()
(18)
here. When (5) is established, I get
![]()
(19)
from Definition 5. Because (17) includes contradiction for (19),
![]()
(20)
is established when (5) is established. And, I get
![]()
(21)
from (12), (16), (20).
-End Proof
3. About the Tensor Which Satisfied Binary Law
We will have to think about adaptation of the establishment of Binary Law for the coordinate systems ![]()
in the tensor if we think about establishment of Binary Law for all coordinate systems![]()
. Therefore, I decided to report Tensor when all coordinate systems ![]()
satisfied Binary Law.
Proposition 6. If all coordinate systems ![]()
satisfied ![]()
, Convariant and Contravariant Tensor of the first rank does not change the form of the equation.
Proof: I get
![]()
(22)
from Definition 6 if all coordinate systems ![]()
satisfies (5). Definition 6 and (22) are equal here. Therefore, if all coordinate systems ![]()
satisfied (5), Convariant and Contravariant Tensor of the first rank does not change the form of the equation.
-End Proof
Proposition 7. Tensor of the second rank becomes Symmetric Tensor if all coor- dinate systems ![]()
satisfies ![]()
Proof: I get
![]()
(23)
from Definition 7 if all coordinate systems ![]()
satisfies (5). Definition 7 and (23) are equal here. We can use (12), (16), (20), (21) for (23) by considering Pro- position 5 here. And we can rewrite (23) by using (12), (16) for
![]()
(24)
Then, I get
![]()
(25)
from (23),(24). And we can rewrite (23) by using (20), (21) for
![]()
(26)
Then, I get
![]()
(27)
from (26). Therefore, Tensor of the second rank becomes Symmetric Tensor than consideration of Definition 8 when all coordinate systems ![]()
satisfies (5).
-End Proof
Proposition 8. If all coordinate systems ![]()
satisfied ![]()
, The distance of two points be able to change oneself in connection with the metric of space.
Proof: I get
![]()
(28)
from Definition 10 if all coordinate systems ![]()
satisfies (5). I get
![]()
![]()
(29)
![]()
(30)
![]()
(31)
from Definition 9 if all coordinate systems ![]()
satisfies (5). By the way, we cannot handle (30), (31) according to Proposition 3. We can use (12), (16), (20), (21) for (29) by considering Proposition 5 here. And we must rewrite (29) by using (16) for
![]()
(32)
![]()
(33)
I decide not to handle (33) by consideration of (28) here. Well, I get conclution from (32) that if all coordinate systems ![]()
satisfied (5), Scalar quantity be able to change oneself in connection with the metric of space. Here, This Scalar quantity expressed the all of quantity expressed as Scalar. Therefore, I get conclution that the distance of two points be able to change oneself in connection with the metric of space.
-End Proof
Proposition 9. If all coordinate systems ![]()
satisfied ![]()
, convariant differentiation for Contravariant Bector ![]()
behave like a convariant differentiation for Scalar ![]()
Proof: I get
![]()
![]()
(34)
![]()
(35)
![]()
(36)
from Definition 11 if all coordinate systems ![]()
satisfies (5). By the way, we cannot handle (35), (36) according to Proposition 3. We can use (12), (16), (20), (21) for (34) by considering Proposition 5 here. And we must rewrite (34) by using (21) for
![]()
![]()
(37)
And, I can get
![]()
(38)
from (37) for consideration of (28). And we can rewrite (38) by using (21) for
![]()
(39)
Because the second term of the right side of (38) does not exist here, we may adopt (38) and (39) description form of which. Well, I get conclution from (39), Definition 12 that if all coordinate systems ![]()
satisfied (5), Convariant differentiation for Contravariant Bector ![]()
behave like a Convariant differentiation for Scalar![]()
.
-End Proof
4. Discussion
About Definition 2:
I named (5) “Binary Law” by Proposition 3.
About Proposition 6:
Convariant and contravariant tensor of the first rank don’t change the formula whether it’s satisfied (5) or not.
About Proposition 8:
In (32), we can think that ![]()
expressed the distance of two points in ![]()
is
establishment and this is constant. And, ![]()
expresses the distance of two points in general and this is not constant.
About Proposition 9:
In (39), we can handle ![]()
as tensor similarly![]()
.