Theta function

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Jacobi's original theta function θ1 with u = iπz and with nome q = eiπτ = 0.1e0.1iπ. Conventions are (Mathematica): θ1(u;q)=2q14n=0(1)nqn(n+1)sin(2n+1)u=n=(1)n12q(n+12)2e(2n+1)iu

In mathematics, theta functions are special functions of several complex variables. They are important in many areas, including the theories of Abelian varieties and moduli spaces, and of quadratic forms. They have also been applied to soliton theory. When generalized to a Grassmann algebra, they also appear in quantum field theory.[1]

The most common form of theta function is that occurring in the theory of elliptic functions. With respect to one of the complex variables (conventionally called z), a theta function has a property expressing its behavior with respect to the addition of a period of the associated elliptic functions, making it a quasiperiodic function. In the abstract theory this comes from a line bundle condition of descent.

Jacobi theta function

Jacobi theta 1
Jacobi theta 2
Jacobi theta 3
Jacobi theta 4

There are several closely related functions called Jacobi theta functions, and many different and incompatible systems of notation for them. One Jacobi theta function (named after Carl Gustav Jacob Jacobi) is a function defined for two complex variables z and τ, where z can be any complex number and τ is the half-period ratio, confined to the upper half-plane, which means it has positive imaginary part. It is given by the formula

ϑ(z;τ)=n=exp(πin2τ+2πinz)=1+2n=1(eπiτ)n2cos(2πnz)=n=qn2ηn

where q = exp(π) is the nome and η = exp(2πiz). It is a Jacobi form. At fixed τ, this is a Fourier series for a 1-periodic entire function of z. Accordingly, the theta function is 1-periodic in z:

ϑ(z+1;τ)=ϑ(z;τ).

It also turns out to be τ-quasiperiodic in z, with

ϑ(z+τ;τ)=exp[πi(τ+2z)]ϑ(z;τ).

Thus, in general,

ϑ(z+a+bτ;τ)=exp(πib2τ2πibz)ϑ(z;τ)

for any integers a and b.

Theta function θ1 with different nome q = eiπτ. The black dot in the right-hand picture indicates how q changes with τ.
Theta function θ1 with different nome q = eiπτ. The black dot in the right-hand picture indicates how q changes with τ.

Auxiliary functions

The Jacobi theta function defined above is sometimes considered along with three auxiliary theta functions, in which case it is written with a double 0 subscript:

ϑ00(z;τ)=ϑ(z;τ)

The auxiliary (or half-period) functions are defined by

ϑ01(z;τ)=ϑ(z+12;τ)ϑ10(z;τ)=exp(14πiτ+πiz)ϑ(z+12τ;τ)ϑ11(z;τ)=exp(14πiτ+πi(z+12))ϑ(z+12τ+12;τ).

This notation follows Riemann and Mumford; Jacobi's original formulation was in terms of the nome q = eiπτ rather than τ. In Jacobi's notation the θ-functions are written:

θ1(z;q)=ϑ11(z;τ)θ2(z;q)=ϑ10(z;τ)θ3(z;q)=ϑ00(z;τ)θ4(z;q)=ϑ01(z;τ)

The above definitions of the Jacobi theta functions are by no means unique. See Jacobi theta functions (notational variations) for further discussion.

If we set z = 0 in the above theta functions, we obtain four functions of τ only, defined on the upper half-plane (sometimes called theta constants.) These can be used to define a variety of modular forms, and to parametrize certain curves; in particular, the Jacobi identity is

ϑ00(0;τ)4=ϑ01(0;τ)4+ϑ10(0;τ)4

which is the Fermat curve of degree four.

Jacobi identities

Jacobi's identities describe how theta functions transform under the modular group, which is generated by ττ + 1 and τ ↦ −1/τ. Equations for the first transform are easily found since adding one to τ in the exponent has the same effect as adding 1/2 to z (nn2 mod 2). For the second, let

α=(iτ)12exp(πτiz2).

Then

ϑ00(zτ;1τ)=αϑ00(z;τ)ϑ01(zτ;1τ)=αϑ10(z;τ)ϑ10(zτ;1τ)=αϑ01(z;τ)ϑ11(zτ;1τ)=iαϑ11(z;τ).

Theta functions in terms of the nome

Instead of expressing the Theta functions in terms of z and τ, we may express them in terms of arguments w and the nome q, where w = eπiz and q = eπ. In this form, the functions become

ϑ00(w,q)=n=(w2)nqn2ϑ01(w,q)=n=(1)n(w2)nqn2ϑ10(w,q)=n=(w2)n+12q(n+12)2ϑ11(w,q)=in=(1)n(w2)n+12q(n+12)2.

We see that the theta functions can also be defined in terms of w and q, without a direct reference to the exponential function. These formulas can, therefore, be used to define the Theta functions over other fields where the exponential function might not be everywhere defined, such as fields of p-adic numbers.

Product representations

The Jacobi triple product (a special case of the Macdonald identities) tells us that for complex numbers w and q with |q| < 1 and w ≠ 0 we have

m=1(1q2m)(1+w2q2m1)(1+w2q2m1)=n=w2nqn2.

It can be proven by elementary means, as for instance in Hardy and Wright's An Introduction to the Theory of Numbers.

If we express the theta function in terms of the nome q = eπ (noting some authors instead set q = e) and take w = eπiz then

ϑ(z;τ)=n=exp(πiτn2)exp(2πizn)=n=w2nqn2.

We therefore obtain a product formula for the theta function in the form

ϑ(z;τ)=m=1(1exp(2mπiτ))(1+exp((2m1)πiτ+2πiz))(1+exp((2m1)πiτ2πiz)).

In terms of w and q:

ϑ(z;τ)=m=1(1q2m)(1+q2m1w2)(1+q2m1w2)=(q2;q2)(w2q;q2)(qw2;q2)=(q2;q2)θ(w2q;q2)

where (  ;  ) is the q-Pochhammer symbol and θ(  ;  ) is the q-theta function. Expanding terms out, the Jacobi triple product can also be written

m=1(1q2m)(1+(w2+w2)q2m1+q4m2),

which we may also write as

ϑ(zq)=m=1(1q2m)(1+2cos(2πz)q2m1+q4m2).

This form is valid in general but clearly is of particular interest when z is real. Similar product formulas for the auxiliary theta functions are

ϑ01(zq)=m=1(1q2m)(12cos(2πz)q2m1+q4m2),ϑ10(zq)=2q14cos(πz)m=1(1q2m)(1+2cos(2πz)q2m+q4m),ϑ11(zq)=2q14sin(πz)m=1(1q2m)(12cos(2πz)q2m+q4m).

Integral representations

The Jacobi theta functions have the following integral representations:

ϑ00(z;τ)=iii+eiπτu2cos(2uz+πu)sin(πu)du;ϑ01(z;τ)=iii+eiπτu2cos(2uz)sin(πu)du;ϑ10(z;τ)=ieiz+14iπτii+eiπτu2cos(2uz+πu+πτu)sin(πu)du;ϑ11(z;τ)=eiz+14iπτii+eiπτu2cos(2uz+πτu)sin(πu)du.

Explicit values

See Yi (2004).[2][3]

φ(eπx)=ϑ(0;ix)=θ3(0;eπx)=n=exπn2φ(eπ)=π4Γ(34)φ(e2π)=π4Γ(34)6+4242φ(e3π)=π4Γ(34)27+18343φ(e4π)=π4Γ(34)84+24φ(e5π)=π4Γ(34)225+100545φ(e6π)=32+334+23274+1728443243π2861+6236Γ(34)=π4Γ(34)14+34+44+9417288φ(e7π)=π4Γ(34)13+7+7+3714288=π4Γ(34)7+47+5284+1372447φ(e8π)=π4Γ(34)1288+2+24φ(e9π)=π4Γ(34)(1+(1+3)233)3φ(e10π)=π4Γ(34)20+450+500+1020410φ(e12π)=π4Γ(34)14+24+34+44+94+184+24421088φ(e16π)=π4Γ(34)(4+1284+102484+1024244)16

Some series identities

The next two series identities were proved by István Mező:[4]

ϑ42(q)=iq14k=q2k2kϑ1(2k12ilnq,q),ϑ42(q)=k=q2k2ϑ4(klnqi,q).

These relations hold for all 0 < q < 1. Specializing the values of q, we have the next parameter free sums

πeπ21Γ2(34)=ik=eπ(k2k2)ϑ1(iπ2(2k1),eπ),π21Γ2(34)=k=ϑ4(ikπ,eπ)e2πk2

Zeros of the Jacobi theta functions

All zeros of the Jacobi theta functions are simple zeros and are given by the following:

ϑ(z,τ)=ϑ3(z,τ)=0z=m+nτ+12+τ2ϑ1(z,τ)=0z=m+nτϑ2(z,τ)=0z=m+nτ+12ϑ4(z,τ)=0z=m+nτ+τ2

where m, n are arbitrary integers.

Relation to the Riemann zeta function

The relation

ϑ(0;1τ)=(iτ)12ϑ(0;τ)

was used by Riemann to prove the functional equation for the Riemann zeta function, by means of the Mellin transform

Γ(s2)πs2ζ(s)=120(ϑ(0;it)1)ts2dtt

which can be shown to be invariant under substitution of s by 1 − s. The corresponding integral for z ≠ 0 is given in the article on the Hurwitz zeta function.

Relation to the Weierstrass elliptic function

The theta function was used by Jacobi to construct (in a form adapted to easy calculation) his elliptic functions as the quotients of the above four theta functions, and could have been used by him to construct Weierstrass's elliptic functions also, since

(z;τ)=(logϑ11(z;τ))+c

where the second derivative is with respect to z and the constant c is defined so that the Laurent expansion of ℘(z) at z = 0 has zero constant term.

Relation to the q-gamma function

The fourth theta function – and thus the others too – is intimately connected to the Jackson q-gamma function via the relation[5]

(Γq2(x)Γq2(1x))1=q2x(1x)(q2;q2)3(q21)ϑ4(12i(12x)logq,1q).

Relations to Dedekind eta function

Let η(τ) be the Dedekind eta function, and the argument of the theta function as the nome q = eπ. Then,

θ2(0,q)=ϑ10(0;τ)=2η2(2τ)η(τ),θ3(0,q)=ϑ00(0;τ)=η5(τ)η2(12τ)η2(2τ)=η2(12(τ+1))η(τ+1),θ4(0,q)=ϑ01(0;τ)=η2(12τ)η(τ),

and,

θ2(0,q)θ3(0,q)θ4(0,q)=2η3(τ).

See also the Weber modular functions.

Elliptic modulus

The elliptic modulus is

k(τ)=ϑ10(0,τ)2ϑ00(0,τ)2

and the complementary elliptic modulus is

k(τ)=ϑ01(0,τ)2ϑ00(0,τ)2

A solution to the heat equation

The Jacobi theta function is the fundamental solution of the one-dimensional heat equation with spatially periodic boundary conditions.[6] Taking z = x to be real and τ = it with t real and positive, we can write

ϑ(x,it)=1+2n=1exp(πn2t)cos(2πnx)

which solves the heat equation

tϑ(x,it)=14π2x2ϑ(x,it).

This theta-function solution is 1-periodic in x, and as t → 0 it approaches the periodic delta function, or Dirac comb, in the sense of distributions

limt0ϑ(x,it)=n=δ(xn).

General solutions of the spatially periodic initial value problem for the heat equation may be obtained by convolving the initial data at t = 0 with the theta function.

Relation to the Heisenberg group

The Jacobi theta function is invariant under the action of a discrete subgroup of the Heisenberg group. This invariance is presented in the article on the theta representation of the Heisenberg group.

Generalizations

If F is a quadratic form in n variables, then the theta function associated with F is

θF(z)=mne2πizF(m)

with the sum extending over the lattice of integers n. This theta function is a modular form of weight n/2 (on an appropriately defined subgroup) of the modular group. In the Fourier expansion,

θ^F(z)=k=0RF(k)e2πikz,

the numbers RF(k) are called the representation numbers of the form.

Theta series of a Dirichlet character

For χ a primitive Dirichlet character modulo q and ν=1χ(1)2 then

θχ(z)=12n=χ(n)nνe2iπn2z

is a weight 12+ν modular form of level 4q2 and character χ(d)(1d)ν, which means

θχ(az+bcz+d)=χ(d)(1d)ν(θ1(az+bcz+d)θ1(z))1+2νθχ(z)

whenever

a,b,c,d4,adbc=1,c0mod4q2.[7]

Ramanujan theta function

Riemann theta function

Let

n={FM(n,)|F=FT,F>0}

the set of symmetric square matrices whose imaginary part is positive definite. n is called the Siegel upper half-space and is the multi-dimensional analog of the upper half-plane. The n-dimensional analogue of the modular group is the symplectic group Sp(2n,); for n = 1, Sp(2,)=SL(2,). The n-dimensional analogue of the congruence subgroups is played by

ker{Sp(2n,)Sp(2n,/k)}.

Then, given τn, the Riemann theta function is defined as

θ(z,τ)=mnexp(2πi(12mTτm+mTz)).

Here, zn is an n-dimensional complex vector, and the superscript T denotes the transpose. The Jacobi theta function is then a special case, with n = 1 and τ where is the upper half-plane. One major application of the Riemann theta function is that it allows one to give explicit formulas for meromorphic functions on compact Riemann surfaces, as well as other auxiliary objects that figure prominently in their function theory, by taking τ to be the period matrix with respect to a canonical basis for its first homology group.

The Riemann theta converges absolutely and uniformly on compact subsets of n×n.

The functional equation is

θ(z+a+τb,τ)=exp2πi(bTz12bTτb)θ(z,τ)

which holds for all vectors a,bn, and for all zn and τn.

Poincaré series

The Poincaré series generalizes the theta series to automorphic forms with respect to arbitrary Fuchsian groups.

Notes

  1. Tyurin, Andrey N. (30 October 2002). "Quantization, Classical and Quantum Field Theory and Theta-Functions". arXiv:math/0210466v1.
  2. Yi, Jinhee (2004). "Theta-function identities and the explicit formulas for theta-function and their applications". Journal of Mathematical Analysis and Applications. 292 (2): 381–400. doi:10.1016/j.jmaa.2003.12.009.
  3. Proper credit for these results goes to Ramanujan. See Ramanujan's lost notebook and a relevant reference at Euler function. The Ramanujan results quoted at Euler function plus a few elementary operations give the results below, so the results below are either in Ramanujan's lost notebook or follow immediately from it.
  4. Mező, István (2013), "Duplication formulae involving Jacobi theta functions and Gosper's q-trigonometric functions", Proceedings of the American Mathematical Society, 141 (7): 2401–2410, doi:10.1090/s0002-9939-2013-11576-5
  5. Mező, István (2012). "A q-Raabe formula and an integral of the fourth Jacobi theta function". Journal of Number Theory. 133 (2): 692–704. doi:10.1016/j.jnt.2012.08.025.
  6. Ohyama, Yousuke (1995). "Differential relations of theta functions". Osaka Journal of Mathematics. 32 (2): 431–450. ISSN 0030-6126.
  7. Shimura, On modular forms of half integral weight

References

Further reading

Harry Rauch with Hershel M. Farkas: Theta functions with applications to Riemann Surfaces, Williams and Wilkins, Baltimore MD 1974, ISBN 0-683-07196-3.

External links

This article incorporates material from Integral representations of Jacobi theta functions on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.