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The Weierstrass invariants  have the following values at infinities:
The Weierstrass  function values at half-periods  can be evaluated at closed forms for some values of arguments  ,  :
The Weierstrass zeta function values at half-periods  can also be evaluated at closed forms for some values of arguments  ,  :
The Weierstrass half‐periods  , the Weierstrass  function values at half-periods  , and the Weierstrass zeta function values at half-periods  are vector‐valued functions of  and  that are analytic in each vector component, and they are defined over  .
The Weierstrass invariants  is a vector‐valued function of  and  that is analytic in each vector component, and it is defined over  (for  ).
The Weierstrass invariants  with  is a periodic function with period  :
The other Weierstrass utility functions  ,  , and  are not periodic functions.
The Weierstrass half‐periods  and Weierstrass zeta function values at half-periods  have mirror symmetry:
The Weierstrass invariants  and the Weierstrass  function values at half-periods  have standard mirror symmetry:
The Weierstrass invariants  have permutation symmetry and are homogeneous:
The Weierstrass invariants  are the invariants under the change of variables  and  with integers  ,  ,  , and  , satisfying the restriction  (modular transformations):
This property leads to similar properties of the Weierstrass  function values at half-periods  and the Weierstrass zeta function values at half-periods  :
The Weierstrass half‐periods  and invariants  have the following double series expansions:
where  is a Klein invariant modular function.
The last double series can be rewritten in the following forms:
The Weierstrass invariants  , the Weierstrass  function values at half-periods  , and the Weierstrass zeta function values at half-periods  have numerous q‐series representations, for example:
where  .
The following rational function of  and  is a modular function if considered as a function of  :
The Weierstrass utilities have some other forms of series expansions, for example:
where  is the divisor sigma function.
The Weierstrass half‐periods  and invariants  have the following integral representations:
The Weierstrass utilities can have product representations. For example, the Weierstrass  function values at half-periods  can be expressed through the following products:
where  .
The Weierstrass utilities satisfy numerous identities, for example:
The first derivatives of Weierstrass half‐periods  and the Weierstrass  and zeta function values at half-periods  and  with respect to variable  and  have the following representations:
where  are the values of the derivative of the Weierstrass elliptic  function  at half-period points  .
The first derivatives of Weierstrass invariants  with respect to the variables  and  can be represented in different forms:
The  -order derivatives of Weierstrass invariants  with respect to the variables  and  have the following representations:
The indefinite integrals of Weierstrass invariants  with respect to the variable  have the following representations:
The Weierstrass half‐periods  satisfy the following differential equations:
The Weierstrass invariants  satisfy the following differential equations:
The Weierstrass zeta function values at half-periods  satisfy the following differential equations:
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