Home Asymptotic relations for the products of elements of some positive sequences
Article Open Access

Asymptotic relations for the products of elements of some positive sequences

  • Agata Chmielowska , Michał Różański , Barbara Smoleń EMAIL logo , Ireneusz Sobstyl and Roman Wituła
Published/Copyright: August 4, 2020

Abstract

The aim of this study was to present a simple method for finding the asymptotic relations for products of elements of some positive real sequences. The main reason to carry out this study was the result obtained by Alzer and Sandor concerning an estimation of a sequence of the product of the first k primes.

MSC 2010: 41A60; 40A20; 40A25; 11A41

1 Introduction

Let p i be the ith prime number. Let us denote p k i = 1 k p i . Consider the sequence b k k 2 k p k . Alzer and Sándor [1] proved the following inequality:

exp k ( c 0 log log k ) b k exp k ( c 1 log log k )

for every k 5 , where constants c 0 and c 1 are equal to

c 0 = 1 5 log 23 + log log 5 1.10298 ,

c 1 = 1 192 log 36 864 192 + log log 192 1 192 log ( p 192 ) 2.04287 ,

respectively. In this study, another estimation of the sequence { b k } connected with the limit lim k f ( k ) = 2 will be shown, where

f ( k ) = 1 k log k 2 k + log log k 1 k θ ( p k ) , θ ( x ) p x log p ,

and p runs over all prime numbers less than or equal to x. The above limit was proven by Alzer and Sándor [1]. Nevertheless, we decided to obtain a new proof of this limit as the original proof was obtained in an over complicated way (in a certain sense). In consequence, we also found a new result (Theorem 1), which gives a simple and universal tool for generating asymptotic relations of many known sequences of real numbers, especially for the products of elements of certain sequences.

2 Main result

The discussion is based on the following well-known fact, which is connected to d′ Alembert’s ratio test.

Lemma 1

Suppose that { a k } k = 1 is a sequence of positive terms and there exists a finite limit lim k a k + 1 a k = g . If g < 1 , then lim k a k = 0 , and if g > 1 , then lim k a k = .

This result will be used for finding the estimation of sequence { b k } k = 1 in the following way. If we can find sequences { m k } k = 1 , { M k } k = 1 of positive real numbers such that

lim k b k + 1 m k + 1 b k m k 1 > 1 , lim k b k + 1 M k + 1 b k M k 1 < 1 ,

then lim k b k m k = , lim k b k M k = 0 , thereby m k b k M k for sufficiently large k.

Using Stirling’s approximation we can write

k 2 k = ( k 2 ) ! k ! ( k 2 k ) ! 1 2 π ( k 1 ) k 1 2 1 1 k k 2 1 2 π ( k e ) k 1 2 .

From the prime number theorem, we get p k k log k . Therefore, we have

b k + 1 b k = ( k + 1 ) 2 k + 1 p k k 2 k p k 1 1 p k + 1 ( k + 1 ) k + 1 2 e k + 1 2 k k 1 2 e k 1 2 e 2 log ( k + 1 ) .

If we denote c k ( t ) = e k t ( log k ) k , then we get c k ( t ) c k + 1 ( t ) e t log ( k + 1 ) , and thereby

b k + 1 c k + 1 ( t ) b k c k ( t ) 1 e 2 t ,

where e 2 t > 1 if t < 2 and e 2 t < 1 if t > 2 . Then, for every t 1 < 2 < t 2 and for sufficiently large k the following inequalities hold

e k t 1 ( log k ) k = c k ( t 1 ) b k c k ( t 2 ) = e k t 2 ( log k ) k ,

hence

exp [ k ( t 1 log log k ) ] k 2 k p k exp [ k ( t 2 log log k ) ] .

Corollary 1

We have (see [1])

lim k log k 2 k k log p k k + log log k = 2 ,

or equivalently

lim k k 2 k p k k log k = e 2 .

In a similar way, we may find the estimation of sequence p k k = 1 . We have

p k + 1 p k = p k + 1 ( k + 1 ) log ( k + 1 ) .

Let us choose the sequence d k ( e t k log k ) k . Then, d k + 1 ( t ) d k ( t ) e t + 1 ( k + 1 ) log ( k + 1 ) and

p k + 1 d k + 1 ( t ) p k d k ( t ) 1 e t 1 ,

where e t 1 > 1 if t < 1 and e t 1 < 1 if t > 1 . Therefore, we obtain

exp k ( t 3 + log k + log log k ) p k exp k ( t 4 + log k + log log k )

for any t 3 < 1 < t 4 and for sufficiently large k. Moreover, we also have

lim k log p k k log k log log k = 1 ,

i.e.,

lim k p k k k log k = 1 e .

The last result reminds another known limit

(1) lim k k ! k k = 1 e ,

which is not an incident and comes from the general relationship presented in Theorem 1.

From now on we will use the symbol x k to denote product i = 1 k x i , where { x i } i = 1 is any real sequence. Now, we will prove our main result.

Theorem 1

Let { f k } k = 1 be an increasing sequence of positive reals. Suppose that there exists r , w and a polynomial p [ k ] such that

f k e r k p ( k ) log w k .

Then, for every pair t 1 , t 2 of real numbers satisfying the condition t 1 < r p ( 0 ) < t 2 , the following inequality holds

( e t 1 k p ( 0 ) log w k ) k f k k p ( k ) p ( 0 ) ( e t 2 k p ( 0 ) log w k ) k ,

for all sufficiently large k, which implies the relation

lim k log f k k p ( k ) p ( 0 ) k p ( 0 ) log k log ( log w k ) = r p ( 0 ) ,

or the equivalent one

(2) lim k f k k p ( k ) p ( 0 ) k k p ( 0 ) log w k = e r p ( 0 ) .

Proof

Let us set g k e t k k k p ( 0 ) log k w k . Then, we obtain

g k g k + 1 = e t 1 + 1 k k p ( 0 ) ( k + 1 ) p ( 0 ) 1 + log 1 + 1 k log k k w log w ( k + 1 ) e t p ( 0 ) ( k + 1 ) p ( 0 ) log w ( k + 1 )

and

f k + 1 ( k + 1 ) p ( k + 1 ) p ( 0 ) k p ( k ) p ( 0 ) f k g k g k + 1 = f k + 1 ( k + 1 ) p ( k + 1 ) p ( 0 ) g k g k + 1 e t + r p ( 0 ) ,

where e t + r p ( 0 ) > 1 if t < r p ( 0 ) and e t + r p ( 0 ) < 1 if t > r p ( 0 ) , which finishes the proof.□

Corollary 2

Let { f k } k = 1 be an increasing sequence of positive reals. Suppose that the sequence f k k k = 1 is also increasing and there exist r , s , w such that

f k k e r s k s log w k .

Then, we have

(3) lim k f k k k k s log w k = e r 2 s .

Remark 1

Note that identity (2) can be n-times iterated for all n if we make additional assumptions about monotonicity of the corresponding sequences.

3 Applications

Some applications of Theorem 1 are given as follows.

(3.1) Let f k = k . Then, lim k k ! k k = 1 e .

(3.2) Let f k = 1 i = 1 k 1 1 p i . Then, f k e γ log k (see [2,3]) and

lim k f k k log k = lim k i = 1 k 1 1 p i k + i 1 k log k = e γ ,

where γ denotes Euler’s constant. Let α > 0 . If we replace f k by

f k ( α ) = 1 i = i 0 k 1 α p i

for k i 0 , where i 0 min { i : p i > α } , then f k ( α ) e log ( c ( α ) ) log α k for some c ( α ) > 0 (see [2,4,5]), and consequently

lim k f k ( α ) k log α k = 1 c ( α ) .

For example, c ( 2 ) 0.832429065662 .

(3.3) Let α , 0 α < 1 . Then (see [6])

f k = e k k i = 1 k ( i α ) 2 π Γ ( 1 α ) k 1 2 α ,

which implies the relation

lim k f k k k 1 2 α = 2 π Γ ( 1 α ) e α 1 2 .

(3.4) Let us set f n = i = 1 n i n . Then (see [6,14,15]), we have f n e e 1 n n , which implies (see also final remark 2)

lim n f n n n n = e e 1 ,

i.e.,

lim n f n n ( n + 1 ) n = 1 e 1 .

(3.5) Next, we set f n = k = 1 n k k n 2 2 . By the definition of the Glaischer-Kinkelin constant (see [6,7,8])

A = lim n k = 1 n k k n n 2 2 + n 2 + 1 12 e n 2 4 ,

we also have

A = 2 5 36 π 1 6 exp 2 3 0 1 2 log Γ ( t ) d t = exp 1 12 ζ ( 1 ) 1.2824271291 ,

(see [7,9,10,11]) we obtain f n e 1 2 n and

f n k = 1 n k k i = k n 1 i 2 2 ,

which by Theorem 1 gives us the relation

lim n f n n n = e 3 2 .

(3.6) At last, if we set

f n = e n 2 4 k = 1 n k k ,

then f n A n n ( n + 1 ) 2 + 1 12 , where A denotes the Glaisher-Kinkelin constant. Therefore, we get

lim n f n n n ( n + 1 ) 2 n n 12 = A e 1 12 .

Now we present an application of Corollary 2.

(3.7) In [7, Problem 1.5], it was proved that

(4) f k = e k 2 i = 1 k k i k e 1 ln 2 π k 1 2 .

Hence, by Theorem 1, we get

lim k k f k k = e 3 2 ln 2 π

and by Corollary 2

lim k k f k k k = e 2 ln 2 π .

We note that from (4) we obtain the solution of Problem 51, p. 45 from Pólya and Szegő [12]:

lim k i = 1 k k i k 2 = e .

Note also that, applying Corollary 2, monotonicity of sequences { f k } k = 1 and f k k k = 1 is not important at all, because the following lemma holds.

Lemma 2

Let { a k } k = 1 be a sequence of positive reals. If lim k a k = α , then there exists an increasing sequence { A k } k = 1 such that lim k A k = α and lim k A k a k = 1 . We may assume that the sequence ( A k ) k k = 1 is increasing as well.

(3.8) Also from [7, Problem 1.14] we get

lim k Γ 1 k k k = e 1 ,

which by Corollary 2 implies

lim k 1 k Γ 1 k k k = e 2 .

4 Final remarks

  1. Using the other asymptotic expansions, especially the ones given in the study of Kellner [6] (e.g., for product of Bernoulli numbers, for products of the special values of gamma function, etc.), we can generate many new relations that are omitted here. Other relations were published recently in [13] as well.

  2. In the history of the following asymptotic relation (see [14,15,16])

n n k = 1 n k n = e e 1 e ( e + 1 ) 2 n ( e 1 ) 3 + o ( n 1 ) ,

one thread – Dutch connection is missing. The above relationship was found by the last author as one of the problems in the problem section of the known Dutch journal Nieuw Archief voor Wiskunde but in the equivalent form:

( n + 1 ) n k = 1 n k n = 1 e 1 e ( 3 e ) 2 n ( e 1 ) 3 + o ( n 1 ) .

It is interesting that in both proofs of these equalities (from Nieuw Archief voor Wiskunde and by Lampret – see [15]) Tannery’s theorem was used.

  1. Another estimation for a number of primes is discussed by Meštrović in [17].

5 Problems

The natural question about asymptoticity of the following expressions:

f k k p ( k ) p ( 0 ) k k p ( 0 ) log w k e r p ( 0 )

and

f k k k k s log w k e r 2 s

arises from (1) and (2). For now, this question remains unanswered. The following formula (see [18,19])

e ( 1 ) n n e 1 4 e 1 3 e 1 2 e 1 ( 1 + x ) 1 x 1 x 1 x 1 x 1 x 1 x 1 x x 0 e ( 1 ) n n + 1

is an inspiration for solving this problem.

Acknowledgments

The authors would like to thank reviewers for invaluable comments which help to improve the presentation of this study.

References

[1] H. Alzer and J. Sándor, On a binomial coefficient and a product of prime numbers, Appl. Anal. Discrete Math. 5 (2011), no. 1, 87–92, 10.2298/AADM110206008A.Search in Google Scholar

[2] D. S. Mitrinović, J. Sandor, and B. Crstici, Handbook of Number Theory, Kluwer, Dordrecht, 1996.Search in Google Scholar

[3] E. Trost, Primzahlen, Basel, Birkhäuser, Stuttgart, 1953.Search in Google Scholar

[4] D. S. Mitrinović and M. S. Popadić, Inequalities in Number Theory, Univ. Niš Press, Niš, 1978.Search in Google Scholar

[5] J. B. Rosser and L. Schoenfeld, Approximate formulas for some functions of prime number, Illinois J. Math. 6 (1962), 64–94, 10.1215/ijm/1255631807.Search in Google Scholar

[6] B. C. Kellner, On asymptotic constants related to products of Bernoulli numbers and factorials, Integers 9 (2009), 83–106, 10.1515/INTEG.2009.009.Search in Google Scholar

[7] O. Furdui, Limits, Series, and Fractional Parts, Springer, New York, 2013.10.1007/978-1-4614-6762-5Search in Google Scholar

[8] A. Lupaş and L. Lupaş, On certain special functions, Semin. Itin. Ec. Funct. Aprox. Convex, 1980, Timişoara, 55–68 (in Romanian).Search in Google Scholar

[9] P. T. Bateman and H. G. Diamond, Analytic Number Theory, World Scientific, New Jersey, 2004.10.1142/5605Search in Google Scholar

[10] S. Rabsztyn, D. Słota, and R. Wituła, Gamma and Beta functions. Tom 1, Silesian University of Technology Press, Gliwice, 2012 (in Polish).Search in Google Scholar

[11] S. Rabsztyn, D. Słota, and R. Wituła, Gamma and Beta functions. Tom 2, Silesian University of Technology Press, Gliwice, 2012 (in Polish).Search in Google Scholar

[12] G. Pólya and G. Szegö, Aufgaben und Lehrsätze aus der Analysis, vol. 1, Springer, Berlin, 1964.10.1007/978-3-662-11200-7_1Search in Google Scholar

[13] A. C. L. Ashton and A. S. Fokas, Relations among the Riemann Zeta and Hurwitz Zeta functions, as well as their products, Symmetry 11 (2019), 754, 10.3390/sym11060754.Search in Google Scholar

[14] F. Holland, limm→∞∑k=0m(km)m=ee−1 , Math. Mag. 83 (2010), no. 1, 51–54, 10.4169/002557010X485111.Search in Google Scholar

[15] V. Lampret, A sharp double inequality for sums of powers, J. Inequal. Appl. 2011 (2011), 721827, 10.1155/2011/721827.Search in Google Scholar

[16] Z. Spivey, The Euler-Maclaurin formula and sums of powers, Math. Mag. 79 (2006), no. 1, 61–65, 10.1080/0025570X.2006.11953378.Search in Google Scholar

[17] R. Meštrović, An elementary proof of an estimate for a number of primes less than the product of the first n primes, 2012, arXiv:1211.4571.Search in Google Scholar

[18] M. Adam, B. Bajorska-Harapińska, E. Hetmaniok, J. J. Ludew, M. Pleszczyński, M. Różański, et al. Number series in mathematical analysis and number theory, Silesian University of Technology Press, Gliwice, 2020 (in Polish, in press).Search in Google Scholar

[19] R. Wituła and D. Słota, Intriguing limit, College Math. J. 42 (2011) 328. (available only on paper).Search in Google Scholar

Received: 2019-12-02
Revised: 2020-06-03
Accepted: 2020-06-12
Published Online: 2020-08-04

© 2020 Agata Chmielowska et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

Articles in the same Issue

  1. Regular Articles
  2. Non-occurrence of the Lavrentiev phenomenon for a class of convex nonautonomous Lagrangians
  3. Strong and weak convergence of Ishikawa iterations for best proximity pairs
  4. Curve and surface construction based on the generalized toric-Bernstein basis functions
  5. The non-negative spectrum of a digraph
  6. Bounds on F-index of tricyclic graphs with fixed pendant vertices
  7. Crank-Nicolson orthogonal spline collocation method combined with WSGI difference scheme for the two-dimensional time-fractional diffusion-wave equation
  8. Hardy’s inequalities and integral operators on Herz-Morrey spaces
  9. The 2-pebbling property of squares of paths and Graham’s conjecture
  10. Existence conditions for periodic solutions of second-order neutral delay differential equations with piecewise constant arguments
  11. Orthogonal polynomials for exponential weights x2α(1 – x2)2ρe–2Q(x) on [0, 1)
  12. Rough sets based on fuzzy ideals in distributive lattices
  13. On more general forms of proportional fractional operators
  14. The hyperbolic polygons of type (ϵ, n) and Möbius transformations
  15. Tripled best proximity point in complete metric spaces
  16. Metric completions, the Heine-Borel property, and approachability
  17. Functional identities on upper triangular matrix rings
  18. Uniqueness on entire functions and their nth order exact differences with two shared values
  19. The adaptive finite element method for the Steklov eigenvalue problem in inverse scattering
  20. Existence of a common solution to systems of integral equations via fixed point results
  21. Fixed point results for multivalued mappings of Ćirić type via F-contractions on quasi metric spaces
  22. Some inequalities on the spectral radius of nonnegative tensors
  23. Some results in cone metric spaces with applications in homotopy theory
  24. On the Malcev products of some classes of epigroups, I
  25. Self-injectivity of semigroup algebras
  26. Cauchy matrix and Liouville formula of quaternion impulsive dynamic equations on time scales
  27. On the symmetrized s-divergence
  28. On multivalued Suzuki-type θ-contractions and related applications
  29. Approximation operators based on preconcepts
  30. Two types of hypergeometric degenerate Cauchy numbers
  31. The molecular characterization of anisotropic Herz-type Hardy spaces with two variable exponents
  32. Discussions on the almost 𝒵-contraction
  33. On a predator-prey system interaction under fluctuating water level with nonselective harvesting
  34. On split involutive regular BiHom-Lie superalgebras
  35. Weighted CBMO estimates for commutators of matrix Hausdorff operator on the Heisenberg group
  36. Inverse Sturm-Liouville problem with analytical functions in the boundary condition
  37. The L-ordered L-semihypergroups
  38. Global structure of sign-changing solutions for discrete Dirichlet problems
  39. Analysis of F-contractions in function weighted metric spaces with an application
  40. On finite dual Cayley graphs
  41. Left and right inverse eigenpairs problem with a submatrix constraint for the generalized centrosymmetric matrix
  42. Controllability of fractional stochastic evolution equations with nonlocal conditions and noncompact semigroups
  43. Levinson-type inequalities via new Green functions and Montgomery identity
  44. The core inverse and constrained matrix approximation problem
  45. A pair of equations in unlike powers of primes and powers of 2
  46. Miscellaneous equalities for idempotent matrices with applications
  47. B-maximal commutators, commutators of B-singular integral operators and B-Riesz potentials on B-Morrey spaces
  48. Rate of convergence of uniform transport processes to a Brownian sheet
  49. Curves in the Lorentz-Minkowski plane with curvature depending on their position
  50. Sequential change-point detection in a multinomial logistic regression model
  51. Tiny zero-sum sequences over some special groups
  52. A boundedness result for Marcinkiewicz integral operator
  53. On a functional equation that has the quadratic-multiplicative property
  54. The spectrum generated by s-numbers and pre-quasi normed Orlicz-Cesáro mean sequence spaces
  55. Positive coincidence points for a class of nonlinear operators and their applications to matrix equations
  56. Asymptotic relations for the products of elements of some positive sequences
  57. Jordan {g,h}-derivations on triangular algebras
  58. A systolic inequality with remainder in the real projective plane
  59. A new characterization of L2(p2)
  60. Nonlinear boundary value problems for mixed-type fractional equations and Ulam-Hyers stability
  61. Asymptotic normality and mean consistency of LS estimators in the errors-in-variables model with dependent errors
  62. Some non-commuting solutions of the Yang-Baxter-like matrix equation
  63. General (p,q)-mixed projection bodies
  64. An extension of the method of brackets. Part 2
  65. A new approach in the context of ordered incomplete partial b-metric spaces
  66. Sharper existence and uniqueness results for solutions to fourth-order boundary value problems and elastic beam analysis
  67. Remark on subgroup intersection graph of finite abelian groups
  68. Detectable sensation of a stochastic smoking model
  69. Almost Kenmotsu 3-h-manifolds with transversely Killing-type Ricci operators
  70. Some inequalities for star duality of the radial Blaschke-Minkowski homomorphisms
  71. Results on nonlocal stochastic integro-differential equations driven by a fractional Brownian motion
  72. On surrounding quasi-contractions on non-triangular metric spaces
  73. SEMT valuation and strength of subdivided star of K 1,4
  74. Weak solutions and optimal controls of stochastic fractional reaction-diffusion systems
  75. Gradient estimates for a weighted nonlinear parabolic equation and applications
  76. On the equivalence of three-dimensional differential systems
  77. Free nonunitary Rota-Baxter family algebras and typed leaf-spaced decorated planar rooted forests
  78. The prime and maximal spectra and the reticulation of residuated lattices with applications to De Morgan residuated lattices
  79. Explicit determinantal formula for a class of banded matrices
  80. Dynamics of a diffusive delayed competition and cooperation system
  81. Error term of the mean value theorem for binary Egyptian fractions
  82. The integral part of a nonlinear form with a square, a cube and a biquadrate
  83. Meromorphic solutions of certain nonlinear difference equations
  84. Characterizations for the potential operators on Carleson curves in local generalized Morrey spaces
  85. Some integral curves with a new frame
  86. Meromorphic exact solutions of the (2 + 1)-dimensional generalized Calogero-Bogoyavlenskii-Schiff equation
  87. Towards a homological generalization of the direct summand theorem
  88. A standard form in (some) free fields: How to construct minimal linear representations
  89. On the determination of the number of positive and negative polynomial zeros and their isolation
  90. Perturbation of the one-dimensional time-independent Schrödinger equation with a rectangular potential barrier
  91. Simply connected topological spaces of weighted composition operators
  92. Generalized derivatives and optimization problems for n-dimensional fuzzy-number-valued functions
  93. A study of uniformities on the space of uniformly continuous mappings
  94. The strong nil-cleanness of semigroup rings
  95. On an equivalence between regular ordered Γ-semigroups and regular ordered semigroups
  96. Evolution of the first eigenvalue of the Laplace operator and the p-Laplace operator under a forced mean curvature flow
  97. Noetherian properties in composite generalized power series rings
  98. Inequalities for the generalized trigonometric and hyperbolic functions
  99. Blow-up analyses in nonlocal reaction diffusion equations with time-dependent coefficients under Neumann boundary conditions
  100. A new characterization of a proper type B semigroup
  101. Constructions of pseudorandom binary lattices using cyclotomic classes in finite fields
  102. Estimates of entropy numbers in probabilistic setting
  103. Ramsey numbers of partial order graphs (comparability graphs) and implications in ring theory
  104. S-shaped connected component of positive solutions for second-order discrete Neumann boundary value problems
  105. The logarithmic mean of two convex functionals
  106. A modified Tikhonov regularization method based on Hermite expansion for solving the Cauchy problem of the Laplace equation
  107. Approximation properties of tensor norms and operator ideals for Banach spaces
  108. A multi-power and multi-splitting inner-outer iteration for PageRank computation
  109. The edge-regular complete maps
  110. Ramanujan’s function k(τ)=r(τ)r2(2τ) and its modularity
  111. Finite groups with some weakly pronormal subgroups
  112. A new refinement of Jensen’s inequality with applications in information theory
  113. Skew-symmetric and essentially unitary operators via Berezin symbols
  114. The limit Riemann solutions to nonisentropic Chaplygin Euler equations
  115. On singularities of real algebraic sets and applications to kinematics
  116. Results on analytic functions defined by Laplace-Stieltjes transforms with perfect ϕ-type
  117. New (p, q)-estimates for different types of integral inequalities via (α, m)-convex mappings
  118. Boundary value problems of Hilfer-type fractional integro-differential equations and inclusions with nonlocal integro-multipoint boundary conditions
  119. Boundary layer analysis for a 2-D Keller-Segel model
  120. On some extensions of Gauss’ work and applications
  121. A study on strongly convex hyper S-subposets in hyper S-posets
  122. On the Gevrey ultradifferentiability of weak solutions of an abstract evolution equation with a scalar type spectral operator on the real axis
  123. Special Issue on Graph Theory (GWGT 2019), Part II
  124. On applications of bipartite graph associated with algebraic structures
  125. Further new results on strong resolving partitions for graphs
  126. The second out-neighborhood for local tournaments
  127. On the N-spectrum of oriented graphs
  128. The H-force sets of the graphs satisfying the condition of Ore’s theorem
  129. Bipartite graphs with close domination and k-domination numbers
  130. On the sandpile model of modified wheels II
  131. Connected even factors in k-tree
  132. On triangular matroids induced by n3-configurations
  133. The domination number of round digraphs
  134. Special Issue on Variational/Hemivariational Inequalities
  135. A new blow-up criterion for the Nabc family of Camassa-Holm type equation with both dissipation and dispersion
  136. On the finite approximate controllability for Hilfer fractional evolution systems with nonlocal conditions
  137. On the well-posedness of differential quasi-variational-hemivariational inequalities
  138. An efficient approach for the numerical solution of fifth-order KdV equations
  139. Generalized fractional integral inequalities of Hermite-Hadamard-type for a convex function
  140. Karush-Kuhn-Tucker optimality conditions for a class of robust optimization problems with an interval-valued objective function
  141. An equivalent quasinorm for the Lipschitz space of noncommutative martingales
  142. Optimal control of a viscous generalized θ-type dispersive equation with weak dissipation
  143. Special Issue on Problems, Methods and Applications of Nonlinear analysis
  144. Generalized Picone inequalities and their applications to (p,q)-Laplace equations
  145. Positive solutions for parametric (p(z),q(z))-equations
  146. Revisiting the sub- and super-solution method for the classical radial solutions of the mean curvature equation
  147. (p,Q) systems with critical singular exponential nonlinearities in the Heisenberg group
  148. Quasilinear Dirichlet problems with competing operators and convection
  149. Hyers-Ulam-Rassias stability of (m, n)-Jordan derivations
  150. Special Issue on Evolution Equations, Theory and Applications
  151. Instantaneous blow-up of solutions to the Cauchy problem for the fractional Khokhlov-Zabolotskaya equation
  152. Three classes of decomposable distributions
Downloaded on 29.10.2025 from https://www.degruyterbrill.com/document/doi/10.1515/math-2020-0029/html
Scroll to top button