# Starting tensor indices at 0

Some time ago I wrote a package for tensor calculus in General Relativity. In order to make it easily accessible for others it should be slightly modified.

There are functions like i.e. Christoffel for calculation of Christoffel symbol :

Christoffel[g_, xx_] :=
Block[{ig, res, n},
n = 4;
ig = Simplify[Inverse[g]];
res = Table[(1/2)*Sum[ig[[i,s]]*(-D[g[[j,k]], xx[[s]]] + D[g[[j,s]], xx[[k]]]
+ D[g[[s,k]], xx[[j]]]), {s, 1, n}], {i, 1, n}, {j, 1, n}, {k, 1, n}];
res
]

where g and xx are metric tensor and coordinates respectively, which I define in a Mathematica session after uploading the package in a straightforward way putting for example an ansatz for a static spherically symmetric spacetime : This way involves drawbacks since index ranges are {1, 2, 3, 4} while the common practice in relativistic physics suggests to put {0, 1, 2, 3} where 0 stands for timelike coordinate, and {1, 2, 3} stand for spacelike ones.
To ilustrate the problem let's define a table where indices start from 0 , i.e.

V = Table[i - j, {i, 0, 3}, {j, 0, 3}]
{{0, -1, -2, -3}, {1, 0, -1, -2}, {2, 1, 0, -1}, {3, 2, 1, 0}}

but when I evaluate V[[0, 0]] I get Symbol - the head of V,
while for V[[1, 2]] I get -1 as it should be.

My questions are :

1. How could I redefine V in order be able to evaluate "table" component [0, 0] ?
2. What would be the most convenient way to introduce matrix g with its indices starting at 0?
3. Since I have to give up using Part to access tensor components 0,0 how to introduce in a package a freedom of choice of index ranges of other objects like Christoffel (let's say by default index ranges - {0, 1, 2, 3} or if one prefers - {1, 2, 3, 4}) ?

Although these questions seem trivial at first sight but any comprehensive answers are welcome. Anyone using a package shouldn't bother his head about Mathematica subtleties.

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Can you simplify this question to its essence? Try removing a lot of the physics, and the extraneous information. –  Matt Fenwick Nov 10 '11 at 23:38
You're probably best of not using Part at all. Define tensor objects which take indices, so T[m,-n] can display as T^m_n but if you give an index in the appropriate range, then it will look at the appropriate DownValues to see if there is anything associated with it. E.g. T[0,0] = f[r] is the energy density. Look at how the xCoba part of xAct deals with components. (Most abstract matrix and tensor implementations work this way...) –  Simon Nov 11 '11 at 1:50
This very useful article, Using zero based arrays and lists in Mathematica by Nasser M. Abbasi, who cleverly uses the Notation package to do something similar, might be of interest. It is available here (Nasser's Website). [I am sure Nasser has an answer on SO about this, but I cannot locate it] –  TomD Nov 11 '11 at 7:17
@Simon, Thanks for an alternative to tackle the problem. I knew about xAct bundle, but I thought there was a more straigthforward solution. –  Artes Nov 11 '11 at 9:34
@TomD, Thanks for a reference to Nasser M.Abbasi's article –  Artes Nov 11 '11 at 9:37

(1) Mathematica list indexing, via Part ( [[]] in more common notation) starts at 1. The 0 part is the head of the expression.

(2) Can define a "function" that takes the indices you want and adds 1 to each.

xx = {t, x, \[Theta], \[Phi]};
g = {{-E^(2*\[Nu][x]), 0, 0, 0}, {0, E^(2*\[Lambda][x]), 0, 0}, {0,
0, x^2, 0}, {0, 0, 0, x^2*Sin[\[Theta]]^2}};

gg[indices___] := g[[Sequence @@ ({indices} + 1)]]

Examples:

In[121]:= gg[0]
Out[121]= {-E^(2*\[Nu][x]), 0, 0, 0}

In[123]:= gg[2, 2]
Out[123]= x^2

(3) See (2) for a possible approach. See (1) to understand that Part is NOT the direct way to go.

Daniel Lichtblau

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But according to documentation of Table it says: Table[expr,{i,Subscript[i, min],Subscript[i, max]}] starts with i=Subscript[i, min]. So there seems no reason not to start i at 0. –  Artes Nov 11 '11 at 0:08
You can create Table with any set of indices. But you cannot index via Part that way. The elements begin at part 1, etc. –  Daniel Lichtblau Nov 11 '11 at 0:19
@Harmon I believe you are confusing the index used to create the expression V and the index of the parts of the expression itself. One can write a = Table[i^2, {i, -4, 5}] which starts with (-4)^2 but the resulting list is just a list. If you want to preserve a different correlation, you could use something like b = Table[i -> i^2, {i, -4, 5}] and then extract your part with -4 /. b which yields 16. –  Mr.Wizard Nov 11 '11 at 0:19

It is not my intention to be trivial or flippant about your concern, however I am having some trouble understanding the significance of your dilemma. Mathematica, or more specifically Part indexes from one, and that is simply the way it is. I am tempted to say use e.g. V[[n+1]] but I have to suppose you have already considered this.

Index 0 is reserved for the head of the expression. While it is far from standard, the flexibility of Mathematica syntax actually allows for this construct:

V = 0[-1, -2, -3][{1, 0, -1, -2}, {2, 1, 0, -1}, {3, 2, 1, 0}];

V[[0,2]]
-2

In specific answer to your first question, and for explanation of the trick above, you must be familiar with Mathematica heads. Every expression conceptually has a head. In the expression a + b the head is Plus. In {1, 2, 3} it is List. You can see these written out by using FullForm. Other types also have conceptual heads, even if they are not explicit in FullForm. You can determine these using Head. For example:

Head /@ {"abc", 1, Pi, 3.14, 1/2}
{String, Integer, Symbol, Real, Rational}

The Part syntax [[0, 0]] asks for the head of the head. In the case of your array, which is a list of lists, the head is List, and the head of List itself is Symbol, which defines its type.

In reply to your second question, I would define a new Part function that indexes from zero.

myPart[x_, spec__] := Part[x, ##] & @@ ({spec} /. n_Integer :> n + 1)

V = {{1, 2, 3}, {4, 5, 6}, {7, 8, 9}};

myPart[V, 0, 0]
1

This also works with Span:

myPart[V, All, 0 ;; 1]
{{1, 2}, {4, 5}, {7, 8}}
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