j-invariant

Template:Short description

File:KleinInvariantJ.jpg

In mathematics, Felix Klein's Template:Mvar-invariant or Template:Mvar function is a modular function of weight zero for the special linear group ${\displaystyle \mathrm{SL}(2,\mathbb{\mathbb{Z}})}$ defined on the upper half-plane of complex numbers. It is the unique such function that is holomorphic away from a simple pole at the cusp such that

${\displaystyle j\left(e^{2\pi i/3}\right)=0,j(i)=1728=12^3.}$

Rational functions of ${\displaystyle j}$ are modular, and in fact give all modular functions of weight 0. Classically, the ${\displaystyle j}$-invariant was studied as a parameterization of elliptic curves over ${\displaystyle \mathbb{ℂ}}$, but it also has surprising connections to the symmetries of the Monster group (this connection is referred to as monstrous moonshine).

Definition

File:J-inv-real.jpeg

File:J-inv-phase.jpeg

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The Template:Mvar-invariant can be defined as a function on the upper half-plane ${\displaystyle {\mathscr{H}}=\{\tau \in \mathbb{ℂ}\mid \mathrm{Im}(\tau )>0\}}$, by

${\displaystyle j(\tau )=1728\frac{g_2(\tau {)}^3}{\mathrm{\Delta }(\tau )}=1728\frac{g_2(\tau {)}^3}{g_2(\tau {)}^3-27g_3(\tau {)}^2}=1728\frac{g_2(\tau {)}^3}{(2\pi {)}^{12}{\eta }^{24}(\tau )}}$

with the third definition implying ${\displaystyle j(\tau )}$ can be expressed as a cube, also since 1728${\displaystyle }=12^3$. The function cannot be continued analytically beyond the upper half-plane due to the natural boundary at the real line.

The given functions are the modular discriminant ${\displaystyle \mathrm{\Delta }(\tau )=g_2(\tau {)}^3-27g_3(\tau {)}^2=(2\pi {)}^{12}{\eta }^{24}(\tau )}$, Dedekind eta function ${\displaystyle \eta (\tau )}$, and modular invariants,

${\displaystyle g_2(\tau )=60G_4(\tau )=60\sum _{(m,n)\ne (0,0)}{(m+n\tau )}^{-4}}$

${\displaystyle g_3(\tau )=140G_6(\tau )=140\sum _{(m,n)\ne (0,0)}{(m+n\tau )}^{-6}}$

where ${\displaystyle G_4(\tau )}$, ${\displaystyle G_6(\tau )}$ are Fourier series,

${\displaystyle \begin{array}{rl}{G}_4(\tau )& =\frac{{\pi }^4}{45}{E}_4(\tau )\\ G_6(\tau )& =\frac{2{\pi }^6}{945}{E}_6(\tau )\end{array}}$

and ${\displaystyle E_4(\tau )}$, ${\displaystyle E_6(\tau )}$ are Eisenstein series,

${\displaystyle \begin{array}{rl}{E}_4(\tau )& =1+240{\displaystyle \sum _{n=1}^{\mathrm{\infty }}}\frac{n^3{q}^n}{1-q^n}\\ E_6(\tau )& =1-504{\displaystyle \sum _{n=1}^{\mathrm{\infty }}}\frac{n^5{q}^n}{1-q^n}\end{array}}$

and ${\displaystyle q=e^{2\pi i\tau }}$ (the square of the nome). The Template:Mvar-invariant can then be directly expressed in terms of the Eisenstein series as,

${\displaystyle j(\tau )=1728\frac{E_4(\tau {)}^3}{E_4(\tau {)}^3-E_6(\tau {)}^2}}$

with no numerical factor other than 1728. This implies a third way to define the modular discriminant,^[1]

${\displaystyle \mathrm{\Delta }(\tau )=(2\pi {)}^{12}\frac{E_4(\tau {)}^3-E_6(\tau {)}^2}{1728}}$

For example, using the definitions above and ${\displaystyle \tau =2i}$, then the Dedekind eta function ${\displaystyle \eta (2i)}$ has the exact value,

${\displaystyle \eta (2i)=\frac{\mathrm{\Gamma }\left(\frac{1}{4}\right)}{2^{11/8}{\pi }^{3/4}}}$

implying the transcendental numbers,

${\displaystyle g_2(2i)=\frac{11\mathrm{\Gamma }{\left(\frac{1}{4}\right)}^8}{2^8{\pi }^2},g_3(2i)=\frac{7\mathrm{\Gamma }{\left(\frac{1}{4}\right)}^{12}}{2^{12}{\pi }^3}}$

but yielding the algebraic number (in fact, an integer),

${\displaystyle j(2i)=1728\frac{g_2(2i{)}^3}{g_2(2i{)}^3-27g_3(2i{)}^2}=66^3.}$

In general, this can be motivated by viewing each Template:Math as representing an isomorphism class of elliptic curves. Every elliptic curve Template:Mvar over Template:Math is a complex torus, and thus can be identified with a rank 2 lattice; that is, a two-dimensional lattice of Template:Math. This lattice can be rotated and scaled (operations that preserve the isomorphism class), so that it is generated by Template:Math and Template:MvarTemplate:Math. This lattice corresponds to the elliptic curve ${\displaystyle y^2=4x^3-g_2(\tau )x-g_3(\tau )}$ (see Weierstrass elliptic functions).

Note that Template:Mvar is defined everywhere in Template:Math as the modular discriminant is non-zero. This is due to the corresponding cubic polynomial having distinct roots.

The fundamental region

File:ModularGroup-FundamentalDomain.svg

It can be shown that Template:Math is a modular form of weight twelve, and Template:Math one of weight four, so that its third power is also of weight twelve. Thus their quotient, and therefore Template:Mvar, is a modular function of weight zero, in particular a holomorphic function Template:Math invariant under the action of Template:Math. Quotienting out by its centre Template:Math yields the modular group, which we may identify with the projective special linear group Template:Math.

By a suitable choice of transformation belonging to this group,

${\displaystyle \tau \mapsto \frac{a\tau +b}{c\tau +d},ad-bc=1,}$

we may reduce Template:Mvar to a value giving the same value for Template:Mvar, and lying in the fundamental region for Template:Mvar, which consists of values for Template:Mvar satisfying the conditions

${\displaystyle \begin{array}{rl}|\tau |& \ge 1\\ -\frac{1}{2}& <\mathfrak{\Re }(\tau )\le \frac{1}{2}\\ -\frac{1}{2}& <\mathfrak{\Re }(\tau )<0\Rightarrow |\tau |>1\end{array}}$

The function Template:Math when restricted to this region still takes on every value in the complex numbers Template:Math exactly once. In other words, for every Template:Mvar in Template:Math, there is a unique τ in the fundamental region such that Template:Math. Thus, Template:Mvar has the property of mapping the fundamental region to the entire complex plane.

Additionally two values Template:Math produce the same elliptic curve iff Template:Math for some Template:Math. This means Template:Math provides a bijection from the set of elliptic curves over Template:Math to the complex plane.^[2]

As a Riemann surface, the fundamental region has genus Template:Math, and every (level one) modular function is a rational function in Template:Mvar; and, conversely, every rational function in Template:Mvar is a modular function. In other words, the field of modular functions is Template:Math.

Class field theory and Template:Mvar

Script error: No such module "labelled list hatnote". The Template:Mvar-invariant has many remarkable properties:

• If Template:Mvar is any point of the upper half plane whose corresponding elliptic curve has complex multiplication (that is, if Template:Mvar is any element of an imaginary quadratic field with positive imaginary part, so that Template:Mvar is defined), then Template:Math is an algebraic integer.^[3] These special values are called singular moduli.
• The field extension Template:Math is abelian, that is, it has an abelian Galois group.
• Let Template:Math be the lattice in Template:Math generated by Template:Math It is easy to see that all of the elements of Template:Math which fix Template:Math under multiplication form a ring with units, called an order. The other lattices with generators Template:Math associated in like manner to the same order define the algebraic conjugates Template:Math of Template:Math over Template:Math. Ordered by inclusion, the unique maximal order in Template:Math is the ring of algebraic integers of Template:Math, and values of Template:Mvar having it as its associated order lead to unramified extensions of Template:Math.

These classical results are the starting point for the theory of complex multiplication.

Transcendence properties

In 1937 Theodor Schneider proved the aforementioned result that if Template:Mvar is a quadratic irrational number in the upper half plane then Template:Math is an algebraic integer. In addition he proved that if Template:Mvar is an algebraic number but not imaginary quadratic then Template:Math is transcendental.

The Template:Mvar function has numerous other transcendental properties. Kurt Mahler conjectured a particular transcendence result that is often referred to as Mahler's conjecture, though it was proved as a corollary of results by Yu. V. Nesterenko and Patrice Phillipon in the 1990s. Mahler's conjecture (now proven) is that, if Template:Mvar is in the upper half plane, then Template:Math and Template:Math are never both simultaneously algebraic. Stronger results are now known, for example if Template:Math is algebraic then the following three numbers are algebraically independent, and thus at least two of them transcendental:

${\displaystyle j(\tau ),\frac{j^{\prime }(\tau )}{\pi },\frac{j^{\prime \prime }(\tau )}{{\pi }^2}}$

The Template:Mvar-expansion and moonshine

Several remarkable properties of Template:Mvar have to do with its [[q-expansion|Template:Mvar-expansion]] (Fourier series expansion), written as a Laurent series in terms of Template:Math, which begins:

${\displaystyle j(\tau )=q^{-1}+744+196884q+21493760q^2+864299970q^3+20245856256q^4+\cdots }$

Note that Template:Mvar has a simple pole at the cusp, so its Template:Mvar-expansion has no terms below Template:Math.

All the Fourier coefficients are integers, which results in several almost integers, notably Ramanujan's constant:

${\displaystyle e^{\pi \sqrt{163}}\approx 640320^3+744}$.

The asymptotic formula for the coefficient of Template:Math is given by

${\displaystyle \frac{e^{4\pi \sqrt{n}}}{\sqrt{2}{n}^{3/4}}}$,

as can be proved by the Hardy–Littlewood circle method.^[4][5]

Moonshine

More remarkably, the Fourier coefficients for the positive exponents of Template:Mvar are the dimensions of the graded part of an infinite-dimensional graded algebra representation of the monster group called the moonshine module – specifically, the coefficient of Template:Math is the dimension of grade-Template:Mvar part of the moonshine module, the first example being the Griess algebra, which has dimension 196,884, corresponding to the term Template:Math. This startling observation, first made by John McKay, was the starting point for moonshine theory.

The study of the Moonshine conjecture led John Horton Conway and Simon P. Norton to look at the genus-zero modular functions. If they are normalized to have the form

${\displaystyle q^{-1}+O(q)}$

then John G. Thompson showed that there are only a finite number of such functions (of some finite level), and Chris J. Cummins later showed that there are exactly 6486 of them, 616 of which have integral coefficients.^[6]

Alternate expressions

We have

${\displaystyle j(\tau )=\frac{256{(1-x)}^3}{x^2}}$

where Template:Math and Template:Mvar is the modular lambda function

${\displaystyle \lambda (\tau )=\frac{{\theta }_2^4(e^{\pi i\tau })}{{\theta }_3^4(e^{\pi i\tau })}=k^2(\tau )}$

a ratio of Jacobi theta functions Template:Math, and is the square of the elliptic modulus Template:Math.^[7] The value of Template:Mvar is unchanged when Template:Mvar is replaced by any of the six values of the cross-ratio:^[8]

${\displaystyle \left\{\lambda ,\frac{1}{1-\lambda },\frac{\lambda -1}{\lambda },\frac{1}{\lambda },\frac{\lambda }{\lambda -1},1-\lambda \right\}}$

The branch points of Template:Mvar are at Template:Math, so that Template:Mvar is a Belyi function.^[9]

Expressions in terms of theta functions

Define the nome Template:Math and the Jacobi theta function,

${\displaystyle \vartheta (0;\tau )={\vartheta }_{00}(0;\tau )=1+2{\displaystyle \sum _{n=1}^{\mathrm{\infty }}}{\left(e^{\pi i\tau }\right)}^{n^2}={\displaystyle \sum _{n=-\mathrm{\infty }}^{\mathrm{\infty }}}{q}^{n^2}}$

from which one can derive the auxiliary theta functions, defined here. Let,

${\displaystyle \begin{array}{rl}a& ={\theta }_2(q)={\vartheta }_{10}(0;\tau )\\ b& ={\theta }_3(q)={\vartheta }_{00}(0;\tau )\\ c& ={\theta }_4(q)={\vartheta }_{01}(0;\tau )\end{array}}$

where Template:Math and Template:Math are alternative notations, and Template:Math. Then we have the for modular invariants Template:Math, Template:Math,

${\displaystyle \begin{array}{rl}{g}_2(\tau )& =\frac{2}{3}{\pi }^4(a^8+b^8+c^8)\\ g_3(\tau )& =\frac{4}{27}{\pi }^6\sqrt{\frac{{(a^8+b^8+c^8)}^3-54{\left(abc\right)}^8}{2}}\\ \end{array}}$

and modular discriminant,

${\displaystyle \mathrm{\Delta }=g_2^3-27g_3^2=(2\pi {)}^{12}{\left(\frac{1}{2}abc\right)}^8=(2\pi {)}^{12}\eta (\tau {)}^{24}}$

with Dedekind eta function Template:Math. The Template:Math can then be rapidly computed,

${\displaystyle j(\tau )=1728\frac{g_2^3}{g_2^3-27g_3^2}=32\frac{{(a^8+b^8+c^8)}^3}{{\left(abc\right)}^8}}$

Algebraic definition

So far we have been considering Template:Mvar as a function of a complex variable. However, as an invariant for isomorphism classes of elliptic curves, it can be defined purely algebraically.^[10] Let

${\displaystyle y^2+a_{1}xy+a_{3}y=x^3+a_2{x}^2+a_{4}x+a_6}$

be a plane elliptic curve over any field. Then we may perform successive transformations to get the above equation into the standard form Template:Math (note that this transformation can only be made when the characteristic of the field is not equal to 2 or 3). The resulting coefficients are:

${\displaystyle \begin{array}{rlrl}{b}_2& =a_1^2+4a_2,& b_4& =a_1{a}_3+2a_4,\\ b_6& =a_3^2+4a_6,& b_8& =a_1^2{a}_6-a_1{a}_3{a}_4+a_2{a}_3^2+4a_2{a}_6-a_4^2,\\ c_4& =b_2^2-24b_4,& c_6& =-b_2^3+36b_2{b}_4-216b_6,\end{array}}$

where Template:Math and Template:Math. We also have the discriminant

${\displaystyle \mathrm{\Delta }=-b_2^2{b}_8+9b_2{b}_4{b}_6-8b_4^3-27b_6^2.}$

The Template:Mvar-invariant for the elliptic curve may now be defined as

${\displaystyle j=\frac{c_4^3}{\mathrm{\Delta }}}$

In the case that the field over which the curve is defined has characteristic different from 2 or 3, this is equal to

${\displaystyle j=1728\frac{c_4^3}{c_4^3-c_6^2}.}$

Inverse function

The inverse function of the Template:Mvar-invariant can be expressed in terms of the hypergeometric function Template:Math (see also the article Picard–Fuchs equation). Explicitly, given a number Template:Mvar, to solve the equation Template:Math for Template:Mvar can be done in at least four ways.

Method 1: Solving the sextic in Template:Mvar,

${\displaystyle j(\tau )=\frac{256(1-\lambda (1-\lambda ){)}^3}{(\lambda (1-\lambda ){)}^2}=\frac{256{(1-x)}^3}{x^2}}$

where Template:Math, and Template:Mvar is the modular lambda function so the sextic can be solved as a cubic in Template:Mvar. Then,

${\displaystyle \tau =i\frac{{}_2{F}_1(\frac{1}{2},\frac{1}{2},1;1-\lambda )}{{}_2{F}_1(\frac{1}{2},\frac{1}{2},1;\lambda )}=i\frac{\mathrm{M}(1,\sqrt{1-\lambda })}{\mathrm{M}(1,\sqrt{\lambda })}}$

for any of the six values of Template:Mvar, where Template:Math is the arithmetic–geometric mean.^{[note 1]}

Method 2: Solving the quartic in Template:Mvar,

${\displaystyle j(\tau )=\frac{27{(1+8\gamma )}^3}{\gamma {(1-\gamma )}^3}}$

then for any of the four roots,

${\displaystyle \tau =\frac{i}{\sqrt{3}}\frac{{}_2{F}_1(\frac{1}{3},\frac{2}{3},1;1-\gamma )}{{}_2{F}_1(\frac{1}{3},\frac{2}{3},1;\gamma )}}$

Method 3: Solving the cubic in Template:Mvar,

${\displaystyle j(\tau )=\frac{64{(1+3\beta )}^3}{\beta {(1-\beta )}^2}}$

then for any of the three roots,

${\displaystyle \tau =\frac{i}{\sqrt{2}}\frac{{}_2{F}_1(\frac{1}{4},\frac{3}{4},1;1-\beta )}{{}_2{F}_1(\frac{1}{4},\frac{3}{4},1;\beta )}}$

Method 4: Solving the quadratic in Template:Mvar,

${\displaystyle j(\tau )=\frac{1728}{4\alpha (1-\alpha )}}$

then,

${\displaystyle \tau =i\frac{{}_2{F}_1(\frac{1}{6},\frac{5}{6},1;1-\alpha )}{{}_2{F}_1(\frac{1}{6},\frac{5}{6},1;\alpha )}}$

One root gives Template:Mvar, and the other gives Template:Math, but since Template:Math, it makes no difference which Template:Mvar is chosen. The latter three methods can be found in Ramanujan's theory of elliptic functions to alternative bases.

The inversion is applied in high-precision calculations of elliptic function periods even as their ratios become unbounded.Script error: No such module "Unsubst". A related result is the expressibility via quadratic radicals of the values of Template:Mvar at the points of the imaginary axis whose magnitudes are powers of 2 (thus permitting compass and straightedge constructions). The latter result is hardly evident since the modular equation for Template:Math of order 2 is cubic.^[11]

Pi formulas

The Chudnovsky brothers found in 1987,^[12]

${\displaystyle \frac{1}{\pi }=\frac{12}{640320^{3/2}}{\displaystyle \sum _{k=0}^{\mathrm{\infty }}}\frac{(6k)!(163\cdot 3344418k+13591409)}{(3k)!{(k!)}^3{(-640320)}^{3k}}}$

a proof of which uses the fact that

${\displaystyle j\left(\frac{1+\sqrt{-163}}{2}\right)=-640320^3.}$

For similar formulas, see the Ramanujan–Sato series.

Failure to classify elliptic curves over other fields

The

${\displaystyle j}$

-invariant is only sensitive to isomorphism classes of elliptic curves over the complex numbers, or more generally, an algebraically closed field. Over other fields there exist examples of elliptic curves whose

${\displaystyle j}$

-invariant is the same, but are non-isomorphic. For example, let

${\displaystyle E_1,E_2}$

be the elliptic curves associated to the polynomials

${\displaystyle \begin{array}{rl}{E}_1:& y^2=x^3-25x\\ E_2:& y^2=x^3-4x,\end{array}}$

both having

${\displaystyle j}$

-invariant

${\displaystyle 1728}$

. Then, the rational points of

${\displaystyle E_2}$

can be computed as:

${\displaystyle E_2(\mathbb{\mathbb{Q}})=\{\mathrm{\infty },(2,0),(-2,0),(0,0)\}}$

since

${\displaystyle x^3-4x=x(x^2-4)=x(x-2)(x+2).}$

There are no rational solutions with

${\displaystyle y=a\ne 0}$

. This can be shown using Cardano's formula to show that in that case the solutions to

${\displaystyle x^3-4x-a^2}$

are all irrational. On the other hand, on the set of points

${\displaystyle \{n(-4,6):n\in \mathbb{\mathbb{Z}}\}}$

the equation for

${\displaystyle E_1}$

becomes

${\displaystyle 36n^2=-64n^3+100n}$

. Dividing by

${\displaystyle 4n}$

to eliminate the

${\displaystyle (0,0)}$

solution, the quadratic formula gives the rational solutions:

${\displaystyle n=\frac{-9\pm \sqrt{81-4\cdot 16\cdot (-25)}}{2\cdot 16}=\frac{-9\pm 41}{32}.}$

If these curves are considered over

${\displaystyle \mathbb{\mathbb{Q}}(\sqrt{10})}$

, there is an isomorphism

${\displaystyle E_1(\mathbb{\mathbb{Q}}(\sqrt{10}))\cong E_2(\mathbb{\mathbb{Q}}(\sqrt{10}))}$

sending

${\displaystyle (x,y)\mapsto ({\mu }^{2}x,{\mu }^{3}y)\text{ where }\mu =\frac{\sqrt{10}}{2}.}$

References

Notes

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Other

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• Script error: No such module "citation/CS1".. Provides a very readable introduction and various interesting identities.
  • Script error: No such module "citation/CS1".
• Script error: No such module "citation/CS1".. Provides a variety of interesting algebraic identities, including the inverse as a hypergeometric series.
• Script error: No such module "citation/CS1". Introduces the j-invariant and discusses the related class field theory.
• Script error: No such module "citation/CS1".. Includes a list of the 175 genus-zero modular functions.
• Script error: No such module "citation/CS1".. Provides a short review in the context of modular forms.
• Script error: No such module "citation/CS1"..

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