A generalization of the Gołąb-Schinzel functional equation

For every fixed real p, the continuous real valued functions f defined on a linear topological space and satisfying the functional equation $$f\left( p[f(y)x+y]+(1-p)[f(x)y+x]\right) =f(x)f(y)$$ are determined. For p = 0 or p = 1 this equation coincides with the classical Go??b-Schinzel equation.     

Semigroup-valued solutions of the Gołąb-Schinzel type functional equation

Let (S, o) be a semigroup. We determine all solutions of the functional equation

Stability problem for the Go?a?b-Schinzel type functional equations

Let X be a vector space over a field K of real or complex numbers, n∈N and λ∈K?{0}. We study the stability problem for the Go?a?b-Schinzel type functional equations

f(x+fn(x)y)=λf(x)f(y)     

Subgroups of the groupZ n and a generalization of the Gołąb-Schinzel functional equation

Letn be a positive integer and letX be a linear space over a commutative fieldK. In the set = (K\{0}) × X we define a binary operation ·: × by

Continuous on rays solutions of an equation of the Go?a?b-Schinzel type

Let X be a real linear space. We characterize continuous on rays solutions f,g:X→R of the equation f(x+g(x)y)=f(x)f(y). Our result refers to papers of J. Chudziak (2006) [14] and J. Brzd?k (2003) [11].     

On solutions of a common generalization of the Go?a?b-Schinzel equation and of the addition formulae

Under some additional assumptions we determine solutions of the equation

f(x+M(f(x))y)=f(x)○f(y),     

On a conditional Gołab-Schinzel equation

Let We show that for every function satisfying the conditional equation

The Cosine–Sine functional equation on a semigroup with an involutive automorphism

We determine the complex-valued solutions of the following extension of the Cosine–Sine functional equation

$$\begin{aligned} f(x\sigma (y))=f(x)g(y)+g(x)f(y)+h(x)h(y),\quad x,y\in S, \end{aligned}$$

where S is a semigroup generated by its squares and \(\sigma \) is an involutive automorphism of S. We express the solutions in terms of multiplicative and additive functions.

     

The Kac–Bernstein functional equation on Abelian groups

Aequationes mathematicae - We consider the Kac–Bernstein functional equation $$\begin{aligned} f(x+y)g(x-y)=f(x)f(y)g(x)g(-y), \quad x, y\in X, \end{aligned}$$ on an arbitrary Abelian group...     

On some functional equations of Goląb-Schinzel type

Summary LetE be a real Hausdorff topological vector space. We consider the following binary law * on ·E:(, ) * (, ) = (, ^k + ) for(, ), (, ) × E where is a nonnegative real number,k andl are integers.In order to find all subgroupoids of ( ·E, *) which depend faithfully on a set of parameters, we have to solve the following functional equation:f(f(y) ^k x +f(x) ^l y) =f(x)f(y) (x, y E). (1)In this paper, all solutionsf: of (1) which are in the Baire class I and have the Darboux property are obtained. We obtain also all continuous solutionsf: E of (1). The subgroupoids of (^* ·E, *) which dapend faithfully and continuously on a set of parameters are then determined in different cases. We also deduce from this that the only subsemigroup ofL _n ¹ of the form {(F(x ₂,x ₃, ,x _n ),x ₂,x ₃, ,x _n ); (x ₂, ,x _n ) ^{n – 1} }, where the mappingF: ^{n – 1 *} has some regularity property, is {1} × ^{n – 1} .We may noitice that the Gob-Schinzel functional equation is a particular case of equation (1)(k = 0, l = 1, = 1). So we can say that (1) is of Gob—Schinzel type. More generally, whenE is a real algebra, we shall say that a functional equation is of Gob—Schinzel type if it is of the form:f(f(y) ^k x +f(x) ^l y) =F(x,y,f(x),f(y),f(xy)) wherek andl are integers andF is a given function in five variables. In this category of functional equations, we study here the equation:f(f(y) ^k x +f(x) ^l y) =f(xy) (x, y f: ). (4)This paper extends the results obtained by N. Brillouët and J. Dhombres in [3] and completes some results obtained by P. Urban in his Ph.D. thesis [11] (this work has not yet been published).Dedicated to the memory of Alexander M. Ostrowski on the occasion of the 100th anniversary of his birth     

Goła̧b–Schinzel equation on cylinders

We determine continuous solutions of the Go?a?b–Schinzel functional equation on cylinders.     

On a Jensen-cubic functional equation and its Hyers–Ulam stability

In this paper, we obtain the general solution and stability of the Jensen-cubic functional equation f((x₁+x₂)/2, 2y₁+y₂)+f((x₁+x₂)/2, 2y₁-y₂) = f(x₁, y₁+y₂)+f(x₁, y₁-y₂)+6f(x₁, y₁)+f(x₂, y₁+y₂)+f(x₂, y₁-y₂)+6f(x₂, y₁).     

The Cavalcante-Tenenblat equation - Does the equation admits physical significance?

The main purpose of the given paper is to analyze a less studied third order non-linear partial differential equation, the so-called Cavalcante-Tenenblat equation (CTE) in the following form: .Since general class of solutions are of basic interest a complete characterization of the group properties is given. The traveling wave ‘ansatz’ restricts the solution manifold to special class of solutions and hence, a generalize algorithm is necessary.We determine the Lie point symmetry vector fields and calculate similarity ‘ansätze’. Further, we also derive a few non-linear transformations and some similarity solutions are obtained explicitly. Due to the complexity of some similarity solutions a numerical procedure is of advantage.Moreover, the non-classical case (potential symmetries) is studied to the first time and further, we show how the CTE leads to approximate symmetries and we apply the method to the first time. We call the disturbed equation the CTE-ε equation and we show how to derive new class of solutions.Finally, the equation does not pass the Painlevé-test and is therefore not soluble by the Inverse Scattering Transform Method (IST).Hence, suitable alternative (algebraic) approaches are necessary to derive class of solutions explicitly.