Further Riccati Differential Equations with Elliptic Coefficients and Meromorphic Solutions

Adolfo Guillot

doi:10.1080/14029251.2018.1494775

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Volume 25, Issue 3, July 2018, Pages 497 - 508

Further Riccati Differential Equations with Elliptic Coefficients and Meromorphic Solutions

Authors

Adolfo Guillot

Instituto de Matemáticas, Universidad Nacional Autónoma de México Ciudad Universitaria, 04510, Ciudad de México, Mexico,adolfo.guillot@im.unam.mx

Received 4 November 2017, Accepted 12 April 2018, Available Online 6 January 2021.

DOI: 10.1080/14029251.2018.1494775 How to use a DOI?
Keywords: differential equations in the complex domain; Riccati equation; Lamé equation; meromorphic solutions
Abstract: We exhibit some families of Riccati differential equations in the complex domain having elliptic coefficients and study the problem of understanding the cases where there are no multivalued solutions. We give criteria ensuring that all the solutions to these equations are meromorphic functions defined in the whole complex plane, and highlight some cases where all solutions are, furthermore, doubly periodic.
Copyright: © 2018 The Authors. Published by Atlantis and Taylor & Francis
Open Access: This is an open access article distributed under the CC BY-NC 4.0 license (http://creativecommons.org/licenses/by-nc/4.0/).

1. Introduction

In the study of ordinary differential equations in the complex domain, a central problem is to determine and understand those, within a given class, which do not have multivalued solutions. Algebraic differential equations (including equations whose coefficients satisfy a differential equation with algebraic coefficients) give a natural setting for this problem. We will study it for some particular families of Riccati differential equations having elliptic (doubly periodic) coefficients. An instance of such a family is given by the equations

y′(t)=y2(t)+14(1−p2)℘(t),(1.1)

with p ∈ Z and ℘ a Weierstraß elliptic function (satisfying (℘′)² = 4℘³ −g₂℘−g₃ for some g₂, g₃ ∈ C). The above equation is closely related to the reduced Chazy XI equation [4, p. 337]

w′″=1−p22ww″+(1−p22+6)(w′)2−3(1−p2)w2w′+3(1−p2)28w4,(1.2)

appearing in Chazy’s program [4] to extend Painlevé’s analysis of second-order equations [9] to third-order ones. Eq. (1.2) has the first integral g₃ = 4z³ − (z′)² for z=w′−14(1−p2)w2 and thus, if y is a solution to (1.1) for the particular case g₂ = 0, the function w defined by y=14(1−p2)w is a solution to (1.2). As for the instances of equations (1.1) that have only single-valued (univalent) solutions, we have that if p is odd, all the solutions to (1.1) are meromorphic functions defined in the whole complex plane. This follows from the fact that if y is a solution to (1.1) and y = −u′/u, then u is a solution to the linear Lamé equation u″(t) − n(n + 1)℘(t)u(t) = 0 for n=12(p−1), which is known to have meromorphic solutions when n is a positive integer [6, §15.62].

As observed in [7], there are not many concrete examples of Riccati equations having strictly meromorphic elliptic coefficients and such that all of their solutions are meromorphic functions defined in the whole plane (in particular, without multivalued solutions). Our aim is to exhibit some explicit two- and three-parameter families of equations and to give, for each family, conditions guaranteeing that all the solutions of a given equation are meromorphic.

The families of equations that we consider are:

y′=y2+14(1−p2)℘−14(1−q2)g3℘2,(I)

y′=y2−g316(3−2p2−2r2+q2)1℘2+−g38(p2−r2)℘′℘2+116(1−q2)(℘′℘)2,(II)

y′=y2+g324(1−q2)1(℘℘′)2+g34(4+4q2+r2−9p2)℘(℘′)2+(1−r2)(℘2℘′)2,(III)

y′=y2+116(1−p2)[cn(t)+idn(t)]2+116(1−q2)[cn(t)−idn(t)]2,(IV)

y′=y2+18(q2+r2−2)sn2(t)+18(q2−r2)isn′(t)+14(1−p2)sn−2(t).(V)

In equations I–III, ℘ is the Weierstraß elliptic function satisfying (℘′)² = 4℘³ −g₃, for g₃ ∈ C\{0} (the actual value of g₃ is irrelevant); in equations IV–V, the coefficients are Jacobi elliptic functions with modulus k² = −1. In all of them, p, q and r are integers. Our results may be summarized as follows:

Theorem 1.1.

For the above equations, the following conditions guarantee that all the solutions are meromorphic:

for (I), 6 ∤ p and 3 ∤ q;
for (II), in the special cases
- — p² = r², 3 ∤ r and 6 ∤ q;
- — q² = p², 3 ∤ p and 6 ∤ r;
- — r² = q², 3 ∤ q and 6 ∤ p;
in general, 3 ∤ p, 3 ∤ q and 3 ∤ r;
for (III), 6 ∤ r, 3 ∤ q and 2 ∤ p;
for (IV), in the special case p² = q², 4 ∤ q; in general, p and q are both odd;
for (V), in the special case q² = r², r is odd and 4 ∤ p; in general, p, q and r are all odd.

When the previous conditions are satisfied, all the solutions are doubly periodic (but not necessarily with the same periods as the coefficients)

in (I), when p is even;
in (II), when p + q + r is even;
in (III), when r is even;
in (V), in the special case q² = r², when p is even.

In [7], Ishizaki, Laine, Shimomura and Tohge studied Eq. (1.1) in the special case g₂ = 0, which is equation I for q = 1. They proved that if k is not divisible by 6 then all solutions are meromorphic (a fact already observed by Chazy [4, §11, p. 344]), established that there are always doubly periodic solutions, and proved that that if k is even, all the solutions are doubly periodic. They also exhibit explicit doubly periodic solutions in many cases when k is odd. In [8], they obtained similar results for the case g₃ = 0 of Eq. (1.1), which is equation V for q = 1 and r = 1 (the Weierstraß elliptic function ℘ such that ℘′ = 4℘³ −4℘ and sn⁻²(t) are the same function). Our results partially extend theirs to the larger families.

The families of Riccati equations here presented appear in our study of quadratic homogeneous systems of differential equations in three variables, of which we hope to soon give an account.

Many of the ideas for the proofs already appear in Chazy’s analysis of Eq. (1.2); they may also be found, for instance, in [7]. We present them in Section 3, after recalling some facts about Riccati equations in Section 2. Theorem 1.1 will be proved in the last two sections.

2. Riccati equations

For the classical theory of Riccati differential equations in the complex domain, we refer the reader to Ince’s and Hille’s treatises [6, §12.51], [5, Chapter 4]. For a more geometric approach to the subject, including the birational point of view, we refer the reader to the first section in Chapter 4 of Brunella’s text [3].

2.1. Generalities

Riccati equations are ordinary differential equations of the form

y′=A(t)y2+B(t)y+C(t),(2.1)

where A, B and C are meromorphic functions defined in some domain U ⊂ C. These equations may be compactified in the direction of the independent variable by adding a point {y = ∞} for each value of t: in the variable z = 1/y, the equation reads z′ = −Cz² − Bz − A, which is again a Riccati equation, holomorphic at the values of t where the original equation is holomorphic. The equation is thus naturally defined in U × CP¹. This implies that for the initial condition y₀, going from time t₀ to time t₁ following a solution to the equation (say, along a path γ : [0, 1] → U) is given by a projective (Möbius, fractional linear) transformation y₀ ↦(ay₀ + b)/(cy₀ + d). Locally, the general solution to a Riccati equation may be written as

y(t)=a(t)y0+b(t)c(t)y0+d(t)

for some functions a, b, c, d such that ad − bc ≡ 1.

If U^* ⊂ U is the domain where the coefficients of the equation are holomorphic, we have a monodromy representation μ : p₁(U^*) → PSL(2, C) into the group of projective transformations. The global fixed points of the action of monodromy of a Riccati equation on CP¹ are in correspondence with the solutions of the equation that do not present multivaluedness. The absence of multivalued solutions is equivalent to the triviality of the monodromy. Also, if there are three single-valued solutions, every solution is single-valued (for the only element of PSL(2, C) having three fixed points is the identity). We may also consider the lifted monodromy μ˜:π1(U*)→SL(2,C), obtained by lifting paths in PSL(2, C) to SL(2, C).

2.2. A Poincaré-Dulac normal form

A Riccati equation of the form (2.1) is said to be nondegenerate at t = 0 if its coefficients A, B, C have at most simple poles at 0 and may be written as ty′ = P(t, y) with P a quadratic polynomial in y holomorphic in t. Such an equation is said to have simple singularities at t = 0 if the quadratic polynomial P(0, y) has two different roots in CP¹. We have a local (in time) and global (in space) normal form for such Riccati equations [3, Chapter 4, Section 1]:

Proposition 2.1.

For the nondegenerate Riccati equation ty′ = P(t, y) with simple singularities at t = 0, there exists S(t) ∈ PSL(2, C), defined in a neighborhood of t = 0, such that in the coordinate z = S(t)y, the equation is either tz′ = kz for some k ∈ C \ {0} or tz′ = kz + ct^k, for some k ∈ Z, k > 0, and some c ∈ C.

We include here a proof in the aim of making this article slightly more self-contained.

Proof.

Up to a constant projective transformation, suppose that the roots of P(0, y) are 0 and ∞. Let k = ∂P/∂y|_(0,0) and notice that, by the simplicity of the singularities, k ≠ 0. Suppose that k is not a negative integer (otherwise consider the variable 1/y in which k is replaced by −k). In the variable w = 1/y the equation reads tw′ = w²P(t, w⁻¹) = Q(t, w). We have that ∂Q/∂w|_(0,0) = −k. Since −k is not a positive integer, by Briot and Bouquet’s theorem [6, §12.6], there is a local solution w₀(t) to this equation with w₀(0) = 0. In the variable w − w₀(t) we have that the constant 0 is a solution. Thus, in the coordinate y = (w − w₀(t))⁻¹, the equation reads ty′ = B(t)y +C(t) for some holomorphic functions B and C. Up to replacing y by fy for f a function such that tf′ = (B(0) − B(t))f, we may suppose that B ≡ k. In the variable y = z − h(t), h(0) = 0, the equation reads tz′ = kz + (th′ − kh +C). If h=∑ihiti and C=∑iciti, it becomes

th′−kh+C=∑i([i−k]hi+ci)ti.

By conveniently choosing h_i we obtain the desired result.

In the normal form, the equations are easily integrated. For the first case, the equation tz′ = kz, the solutions are given by z₀t^k and are not meromorphic in general (except those corresponding to z₀ = 0 and z₀ = ∞); the monodromy is z ↦e²^iπkz. Thus, if all the solutions in the neighborhood of t = 0 are meromorphic, k is an integer. For the second case, the equation wz′ = kz + ct^k, the solutions are z(t) = (clog(t) + c₀)z^k, and are not meromorphic at t = 0 unless c = 0. If c ≠ 0, we do not have formal solutions vanishing at t = 0; actually, not even formal solutions up to order k exist.

2.3. Transformations of Riccati equations

There are some natural transformations between Riccati equations which leave the independent variable unchanged. The first ones, which we may call holomorphic, are given by time-dependent projective transformations: for a solution y(t) of the Riccati equation (2.1) defined in a neighborhood of t = 0, if a, b, c and d are holomorphic functions such that ad − bc ≡ 1, a(t)y(t)+b(t)c(t)y(t)+d(t) is a solution to a Riccati equation which is independent of the chosen solution y [5, Chapter 5]. Other ones are given by elementary transformations (called flips by Brunella), the transformation

y↦y/t(2.2)

and all those which are conjugate to it by a holomorphic one. (See [3, Chapter 4] for an intrinsic description in terms of the birational geometry of surfaces.) Notice that, for fixed t, (2.2) is a projective transformation for t ≠ 0 but not for t = 0. Notice also that the elementary transformation obtained by conjugating it by the projective transformation y ↦1/y is its inverse. Elementary transformations preserve the class of Riccati equations: for instance, under (2.2), for z = y/t, Eq. (2.1) is transformed into z′ = (tA)z² +(B−1/t)z+C/t (an elementary transformation may create or destroy singularities of the equation).

Let us describe the effect of an elementary transformation upon the lifted monodromy of a Riccati equation (holomorphic transformations do not change neither the local monodromy nor its lift). In a disk Δ^* punctured at t = 0 consider a Riccati equation of the form (2.1). The general solution of the Riccati equation may be given by y(t)=a(t)y0+b(t)c(t)y0+d(t) for N(t)=(a(t)b(t)c(t)d(t)), a multivalued function in Δ^* taking values in SL(2, C). Let γ : [0, 1] → Δ^* be a closed path around t = 0 starting at t₀. The lifted monodromy M around γ is given by N|_γ(1)(N|_γ(0))⁻¹. After the elementary transformation (2.2), the solutions are given by z(t)=(1t)a(t)y0+b(t)c(t)y0+d(t), which corresponds to the path N^(t)=σ(t)N(t) for σ(t)=(t−1/200t1/2). After the elementary transformation, the lift of the monodromy is given by

N^|γ(1)(N^|γ(0))−1=σ|γ(1)N|γ(1)(σ|γ(0)N|γ(0))−1=σ|γ(1)M(σ|γ(0))−1.

Since σ|_γ(1) = −σ|_γ(0), this monodromy is conjugate to −M, which has the same image than M in PSL(2, C): the monodromy is unchanged, but its lift is not.

3. Integrability criteria

Theorem 1.1 will be proved in the next two Sections (in Section 4 for equations I–III; in Section 5 for equations IV–V). All of the equations under consideration are of the form

y′=y2+E(t),(3.1)

with E an elliptic function all of whose singularities are double poles. We will say that E has index k at t = t₀ if E=14(1−k2)(t−t0)−2+⋯. We will present two criteria: Lemma 3.1, which will prove the first part of Theorem 1.1. and Theorem 3.1. which will prove the second one.

3.1. A criterion ensuring the existence of meromorphic solutions

We have the following result, present, in one way or another, in most approaches to the subject.

Lemma 3.1.

If ρ is a primitive n-th root of unity and h(ρt) = ρⁿ⁻²h(t), then if k is an integer that does not divide n, all the solutions to

y′=y2+14(1−k2)h(t), h(t)=t−2+⋯(3.2)

in the neighborhood of t = 0 are meromorphic.

Proof.

In the variable

z=ty+12(1−k),(3.3)

obtained after composing an elementary and a holomorphic transformation,

tz′=w2+kw+14(1−k2)(t2h−1).(3.4)

Let f(t) = t²h(t) − 1. Since f(ρt) = f(t), there exists a function F such that f(t) = F(tⁿ). Since f(0) = 0, F(0) = 0. At t = 0 the above equation is nondegenerate and has simple singularities. According to the results in Section 2.2, if the equation has meromorphic solutions, up to a change of coordinates, the equation is of the form tz′ = kz + ct^k, k ∈ Z, k > 0. In order to prove that c = 0 (which implies that all the solutions are meromorphic), it is sufficient to give a local solution to Eq. (3.4) vanishing at 0. Set τ = tⁿ. From Eq. (3.4),

nτdzdτ=z2+kz+14F(τ).

According to Briot and Bouquet’s theorem [6, §12.6], since F(τ) is a holomorphic function vanishing at 0 and, by hypothesis, k/n is not a positive integer, there is a local holomorphic solution to the above equation vanishing at 0, from which one can obtain a local holomorphic solution for (3.4) vanishing at 0.

3.2. Klein’s four-group and periodic solutions

The following result will allow us to guarantee that some of our equations have exclusively periodic solutions.

Theorem 3.1.

Suppose that in Eq. (2.1) all solutions are meromorphic, and that all the singular points are of the form (3.2) for integral indices. If there is an odd number of singularities with even indices in a fundamental domain of E then all the solutions are doubly periodic. In such a case there are three solutions with period lattices Λ′ such that Λ ⊂ Λ′ ⊂ 2Λ, [Λ′ : Λ] = 2 (one for each of the three lattices Λ′ satisfying these conditions), and all the other solutions have 2Λ as their period lattice.

This result appears in [7, Theorem 3.1] and, with the present generality, in [10, Theorem 2.2] (however, these only mention two of the three special solutions).

Proof.

If we start with an equation of the form (3.2) with k ∈ Z, k > 1 and we assume that all the solutions are meromorphic in a neighborhood of t = 0, it takes k + 1 elementary transformations to transform the equation into the nonsingular one y′ = 0: the elementary transformation (3.3), and then k more elementary transformations—under (2.2), equation ty′ = ky becomes ty′ = (k − 1)y. In the nonsingular situation (k = 0) the lifted monodromy is the identity I. Thus, as discussed in Section 2.3, the lifted monodromy for the original equation around t = 0 is (−1)^k+1I.

Suppose that, in Eq. (2.1), all the singular points are of the form (3.2) for integral indices and that all solutions are meromorphic. The lifted monodromy around each one of the fixed points is either I or −I according to the parity of the index. In all cases, it belongs to the center of SL(2, C). Let γ₁ and γ₂ be generators of π₁(C/Λ) and let M₁ and M₂ in SL(2, C) be the corresponding lifted monodromies. If there are p singularities with even indices in C/Λ then [M₁, M₂] = (−1)^p I.

It is not difficult to classify the pairs of commuting elements of PSL(2, C). They

are simultaneously conjugate to elements of the form z ↦αz;
are simultaneously conjugate to elements of the form z ↦z + τ; or
generate a group conjugate to Klein’s four-group
V={z↦z,z↦−z,z↦1z,z↦−1z}.

In particular, two commuting elements such that the commutator of (any) two of their lifts to SL(2, C) is −I generate a group conjugate to Klein’s four-group (see also [7, Lemma 3.2]). In particular, this group is finite. All the solutions are periodic with respect to the sublattice of Λ associated to the kernel of the monodromy. The three special solutions correspond to the three orbits (for the action of this group on CP¹) having nontrivial stabilizer.

Since all pairs of commuting elements in PSL(2, C) generate a group having at least one finite orbit in CP¹, if all the solutions to a Riccati equation with elliptic coefficients are meromorphic, there is at least one doubly periodic solution.

4. The equianharmonic cases

We will now prove Theorem 1.1 for equations I–III. The coefficients of these equations belong to the function field generated by the Weierstraß elliptic function ℘ such that

(℘′)2=4℘3−g3,(4.1)

and its derivative ℘′. Their module of periods Λ is invariant under multiplication by a primitive third root of unity ω (is equianharmonic). For the standard facts about Weierstraß elliptic functions that we will use we refer the reader to [1, Chapter 7]. The meromorphic maps that ℘ and ℘′ induce from C/Λ to CP¹ have, respectively, degrees two and three. The meromorphic functions E we will consider have at most double poles at the points where ℘ and ℘′ have either zeros or poles, and are holomorphic at all other points.

Poles of ℘, ℘′. The origin is the only pole of ℘ and the only pole of ℘′ in C/Λ, ℘(t) = t⁻² + ··· and ℘′(t) = −2t⁻³ + ···. We have that ℘ is even, ℘′ is odd, and

℘(ωt)=ω℘(t), ℘′(ωt)=℘′(t).(4.2)

Zeros of ℘. There are two simple ones in C/Λ. Let θ be such that ℘(θ) = 0. By (4.2), ℘(ωθ) = 0, and since ω³ = 1, the two zeros of ℘ must be fixed under multiplication by ω and are thus located, when Λ is generated by 1 and ω, at the thirds-of-a-period θ=13ω+23 and −θ. From (4.1), (℘′(±θ ))² = −g₃. Since the sum of the residues of ℘⁻¹(t)dt in C/Λ is zero, the values of ℘′ at θ and −θ have opposite signs. From the addition formula for Weierstraß functions,

℘(±θ+t)=(℘′(t)−℘′(±θ))24℘(t)2−℘(t),

and from this and (4.2),

℘(±θ+ωt)=ω℘(±θ+t), ℘′(±θ+ωt)=℘′(±θ+t).(4.3)

Zeros of ℘′. There are three simple ones in C/Λ, located at the three half-periods η_i. From the addition formula for Weierstraß functions,

℘(ηi+t)=14(℘′(t)℘(t)−ei)2−℘(t)−ei,

where e_i = ℘(η_i). Thus, since ℘ is even and ℘′ is odd,

℘(ηi−t)=℘(ηi+t), ℘′(ηi−t)=−℘(ηi+t).(4.4)

Table 1 gives the leading term of the Taylor development at the double poles of the summands of E. All the data in it follows from the previous discussion except the one concerning the zeros of ℘′, which follows from ℘3(ηi)=14g3, obtained from (4.1) and ℘″ = 6℘², this last equality obtained by derivating (4.1).

	℘	℘⁻²	℘⁻²℘′	℘⁻²℘′²	℘⁻²℘′⁻²	℘℘′⁻²	℘⁴℘′⁻²
poles of ℘, ℘′	1	×	×	4	×	×	14
zeros of ℘	×	−g3−1	±ig3−1/2	1	g3−2	×	×
zeros of ℘′	×	×	×	×	49g3−2	19g3−1	136

Table 1.

Coefficients of the leading term of the Taylor developments at the double poles.

4.1. Equation I

It is Eq. (3.1) for

E=14(1−p2)℘−14(1−q2)g3℘2.

It has three poles in C/Λ, all of them double, one at the pole of ℘ and one at each zero of ℘. At 0, pole of ℘, E(t)=14(1−p2)t−2+⋯. For ρ a primitive sixth root of unity (say ρ = −ω), E(ρt) = ρ⁴E(t) and thus, from Lemma 3.1, in the neighborhood of the poles of ℘, all the solutions to the Riccati equation are meromorphic if 6 ∤ p. At the two zeros of ℘, E(t)=14(1−q2)(t∓θ)−2+⋯. By (4.3), E(±θ + ωt) = ωE(±θ + t). Hence, by Lemma 3.1, in the neighborhood of these zeros, the solutions of the Riccati equation are meromorphic whenever 3 ∤ q.

The hypothesis of Theorem 3.1 are fulfilled when p is even.

4.2. Equation II

It is Eq. (3.1) for

E=−g316(3−2p2−2r2+q2)1℘2+−g38(p2−r2)℘′℘2+116(1−q2)(℘′℘)2,

which has three poles in C/Λ, all double, one at the pole of ℘ and one at each one of its zeros. At 0, pole of ℘, E(t)=14(1−q2)t−2+⋯ and E(ωt) = ωE(t), so by Lemma 3.1 the solutions are meromorphic in the neighborhood of t = 0 if 3 ∤ q. For the two zeros θ_i of ℘, E(t)=14(1−r2)(t−θ1)−2+⋯ and E(t)=14(1−p2)(t−θ2)−2+⋯. From (4.3), since E(θ_i + ωt) = ωE(θ_i + t), by Lemma 3.1, all the solutions are meromorphic if 3 ∤ p and 3 ∤ r.

The hypothesis of Theorem 3.1 are fulfilled when p + q + r is even (when we have an odd number of even indices).

4.2.1. The special case p² = r²

In this case we further have that E(ρt) = ρ⁴E(t); the solutions are meromorphic in the neighborhood of t = 0 if 6 ∤ q.

4.2.2. Symmetries and the other special cases

The coefficient E is symmetric in p and r, which can be exchanged via the involution t ↦ −t. The order three transformation t ↦t + θ induces a cyclic permutation of the parameters of E: q is replaced by r, r by p and p by q, but the equation remains otherwise unchanged. This can be checked directly using the relation

℘(t+θ)=[℘′(t)−℘′(θ)]24℘2(t)−℘(t).

In this way the parameter space is symmetric under the full group of permutations of the three variables (this implies Theorem 1.1 for the other two special cases).

4.3. Equation III

It corresponds to Eq. (3.1) for

E=g324(1−q2)1(℘℘′)2+g34(4+4q2+r2−9p2)℘(℘′)2+(1−r2)(℘2℘′)2,

which has six double poles in C/Λ: one at the pole of ℘, one at each zero of ℘ and one at each zero of ℘′. At 0, pole of ℘, E=14(1−r2)t−2+⋯, and E(ρt) = ρ⁴E(t). By Lemma 3.1, all the solutions are meromorphic if 6 ∤ r. At the zeros of ℘, E(t)=14(1−q2)(t∓θ)−2+⋯. According to (4.3), E(±θ + ωt) = ωE(±θ + t), and by Lemma 3.1 the solutions are meromorphic if 3 ∤ q. At all of the three zeros η_i of ℘′, E=14(1−p2)(t−ηi)−2+⋯. From (4.4), E(η_i − t) = E(η_i + t) and thus, by Lemma 3.1, the solutions are meromorphic if p is odd.

The hypothesis of Theorem 3.1 are fulfilled when r is even.

5. The lemniscatic cases

For all the standard facts about Jacobi elliptic functions that will be used in this Section, we refer to [2, Chapter 4]. The three principal Jacobi elliptic functions sn(k, t), cn(k, t), dn(k, t) are meromorphic elliptic functions in C, where k ∈ C is a fixed parameter (the modulus). We will be exclusively concerned with the case where k² = −1, and we will simply write sn(t), cn(t), dn(t). In this case the principal Jacobi elliptic functions are doubly periodic with respect to the lattice L generated by 4K and 4iK′, where K=∫01(1−t4)−1/2dtTable inline, K′ = (1 − i)K. This module of periods is invariant under multiplication by i (is lemniscatic).

We will now prove Theorem 1.1 for equations IV and V, whose coefficients belong to the elliptic function field generated by the principal Jacobi elliptic functions. Each one of the principal Jacobi elliptic functions has an extra period of its own: 2iK′ for sn, 2K + 2iK′ for cn and 2K for dn. The function sn is odd, while cn and dn are even. Their derivatives may be expressed in terms of the same functions; for example,

sn′(t)=cn(t)dn(t)(5.1)

The three principal functions have simple poles at iK′, iK′ +2K, 3iK′, 3iK′ +2K. The corresponding residues, that may be obtained through the formulae in Table 2, appear in Table 3.

u	iK′	3iK′	iK′ + 2K	3iK′ + 2K
cn(t + u)	−dn(t)sn(t)	dn(t)sn(t)	dn(t)sn(t)	−dn(t)sn(t)
dn(t + u)	−icn(t)sn(t)	icn(t)sn(t)	−icn(t)sn(t)	icn(t)sn(t)
sn(t + u)	−isn(t)	−isn(t)	isn(t)	isn(t)

Table 2.

Behavior at the poles.

u	iK′	3iK′	iK′ + 2K	3iK′ + 2K
Res(cn, u)	−1	1	1	−1
Res(dn, u)	−i	i	−i	i
Res(sn, u)	−i	−i	i	i

Table 3.

Residues at the poles.

5.1. Equation IV

It corresponds to

E=116(1−p2)[cn(t)+idn(t)]2+116(1−q2)[cn(t)+idn(t)]2.

It has four double poles in C/Λ, located at the poles of cn and dn. According to Table 3, for u equal to iK′ or 3iK′, E(t)=14(1−q2)(t−u)2+⋯; for u equal to iK′ + 2K or 3iK′ + 2K, E(t)=14(1−p2)(t−u)2+⋯. From the data in Table 2 and from the fact that cn and dn are both even while sn is odd, for each pole u of E we have that E(u − t) = E(u + t). Thus, by Lemma 3.1, in the neighborhood of the poles of E, all the solutions are meromorphic if both q and p are odd.

Since all the indices at the poles come by pairs, there is no situation where Theorem 3.1 can be applied.

5.1.1. The special case p² = q²

In this case E=−18(1−q2)sn(t)2. From the analysis of equation V that will follow (particularly the details given in Section 5.2.1), the equation will have meromorphic solutions as soon as 4 ∤ q.

5.2. Equation V

In this case

E(t)=18(q2+r2−2)sn2(t)+18(q2−r2)isn′(t)+14(1−p2)sn−2(t).

It has the module of periods Λ′, Λ ⊂ Λ′, [Λ′ : Λ] = 2 (sn has the extra period 2iK′). The function E has double poles at the poles and zeros of sn.

In C/Λ′, the poles of sn are simple and located at iK′ and iK′ + 2K. In particular sn² has double poles at these points. The coefficient of the leading term of the Taylor development of E at them is −1; the function sn′ has double poles at the poles of sn; the coefficients of the leading term of the Taylor development of E at these points, that may be obtained through Eq. (5.1) and Table 3, appear in Table 4. We have that E(t)=14(1−r2)(t−iK′)−2+⋯, E(t)=14(1−q2)(t−[iK′+2K])−2+⋯. From Table 2 and from the fact that sn is even and sn′ is odd, we have that for each pole u of E, E(u − t) = E(u + t) and thus in the neighborhood of the poles of E the solutions to the Riccati equation are meromorphic if q and r are odd.

	isn′	sn²	sn⁻²
iK′	−1	−1	×
iK′ + 2K	1	−1	×
0	×	×	1
2K	×	×	1

Table 4.

Coefficients of the leading term of the Taylor developments at the double poles.

In C/Λ′, the zeros of sn are simple and located at 0 and 2K; we have that sn′(0) = 1 and, since sn(2K + t) = −sn(t), sn′(2K + t) = −sn′(t) and sn′(2K) = −1. We have that E(t)=14(1−p2)t−2+⋯. Since sn(−t) = −sn(t) and sn′(−t) = sn′(t), E(−t) = E(t). Thus, by Lemma 3.1, in a neighborhood of t = 0 we have meromorphic solutions if p is odd. We have that E(t)=14(1−p2)(t−2K)−2+⋯. Since sn(2K − t) = −sn(−t) = sn(t) = −sn(2K + t) and sn′(2K − t) = sn′(2K + t), E(2K − t) = E(2K + t). Thus, in a neighborhood of t = 2K, we have meromorphic solutions if p is odd.

All indices must be odd; the hypothesis of Theorem 3.1 are never satisfied.

5.2.1. The special case q² = r²

In this case E has the extra period 2K, for sn(t +2K) = −sn(t). Since sn(it) = isn(t) (both functions give solutions to (y′)² = y⁴ − 1 vanishing at 0), E(it) = −E(t) and thus, in a neighborhood of t = 0, we have meromorphic solutions as soon as 4 ∤ p. If p is even, the hypothesis of Theorem 3.1 are satisfied.

Acknowledgments

This work was funded by PAPIIT-UNAM IN102518 (Mexico).

References

[1]L. V. Ahlfors, Complex analysis, third ed., McGraw-Hill Book Co., New York, 1978.

[2]P. Appel and E. Lacour, Principes de la théorie des fonctions elliptiques et applications, Gauthier-Villars et fils, Paris, 1897.

[3]M. Brunella. Birational geometry of foliations, Publicações Matemáticas do IMPA, Instituto de Matemática Pura e Aplicada (IMPA), Rio de Janeiro, 2004

[4]J. Chazy, Sur les équations différentielles du troisième ordre et d’ordre supérieur dont l’intégrale générale a ses points critiques fixes, Acta Math., Vol. 34, No. 1, 1911, pp. 317-385.

[5]E. Hille, Ordinary differential equations in the complex domain, Dover Publications, Inc., Mineola, NY, 1997. Reprint of the 1976 original

[6]E. L. Ince, Ordinary Differential Equations, Dover Publications, New York, 1944.

[7]K. Ishizaki, I. Laine, S. Shimomura, and K. Tohge, Riccati differential equations with elliptic coefficients, Results Math., Vol. 38, No. 1–2, 2000, pp. 58-71.

[8]K. Ishizaki, I. Laine, S. Shimomura, and K. Tohge, Riccati differential equations with elliptic coefficients. II, Tohoku Math. J., Vol. 55, No. 1, 2003, pp. 99-108. (2)

[9]P. Painlevé, Sur les équations différentielles du second ordre et d’ordre supérieur dont l’intégrale générale est uniforme, Acta Math, Vol. 25, No. 1, 1902, pp. 1-85.

[10]S. Shimomura, Meromorphic solutions of a Riccati differential equation with a doubly periodic coefficient, J. Math. Anal. Appl., Vol. 304, No. 2, 2005, pp. 644-651.

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Journal: Journal of Nonlinear Mathematical Physics
Volume-Issue: 25 - 3
Pages: 497 - 508
Publication Date: 2021/01/06
ISSN (Online): 1776-0852
ISSN (Print): 1402-9251
DOI: 10.1080/14029251.2018.1494775 How to use a DOI?
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TY  - JOUR
AU  - Adolfo Guillot
PY  - 2021
DA  - 2021/01/06
TI  - Further Riccati Differential Equations with Elliptic Coefficients and Meromorphic Solutions
JO  - Journal of Nonlinear Mathematical Physics
SP  - 497
EP  - 508
VL  - 25
IS  - 3
SN  - 1776-0852
UR  - https://doi.org/10.1080/14029251.2018.1494775
DO  - 10.1080/14029251.2018.1494775
ID  - Guillot2021
ER  -

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Journal of Nonlinear Mathematical Physics

Further Riccati Differential Equations with Elliptic Coefficients and Meromorphic Solutions

1. Introduction

Theorem 1.1.

2. Riccati equations

2.1. Generalities

2.2. A Poincaré-Dulac normal form

Proposition 2.1.

Proof.

2.3. Transformations of Riccati equations

3. Integrability criteria

3.1. A criterion ensuring the existence of meromorphic solutions

Lemma 3.1.

Proof.

3.2. Klein’s four-group and periodic solutions

Theorem 3.1.

Proof.

4. The equianharmonic cases

4.1. Equation I

4.2. Equation II

4.2.1. The special case p2 = r2

4.2.2. Symmetries and the other special cases

4.3. Equation III

5. The lemniscatic cases

5.1. Equation IV

5.1.1. The special case p2 = q2

5.2. Equation V

5.2.1. The special case q2 = r2

Acknowledgments

References

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4.2.1. The special case p² = r²

5.1.1. The special case p² = q²

5.2.1. The special case q² = r²