Abstract:
We will introduce new means of Cauchy's type Mr,ls(f, ) defined, for example, as Mr,ls(f, )=((l(l ￠ ’s)/r(r ￠ ’s))(Mrr(f, ) ￠ ’Msr(f, )/Mll(f, ) ￠ ’Msl(f, )))1/(r ￠ ’l), in the case when l ￠ € ‰ ￠ ‰ ￠ € ‰r ￠ € ‰ ￠ ‰ ￠ € ‰s, ￠ € ‰l,r ￠ € ‰ ￠ ‰ ￠ € ‰0. We will show that this new Cauchy's mean is monotonic, that is, the following result. Theorem. Let t,r,u,v ￠ ￠ , such that t ￠ ‰ ¤v, r ￠ ‰ ¤u. Then for Mr,ls(f, ), one has Mt,rs ￠ ‰ ¤Mv,us. We will also give some related comparison results.

Abstract:
We will introduce new means of Cauchy's type defined, for example, as in the case when , . We will show that this new Cauchy's mean is monotonic, that is, the following result. Theorem. Let , such that , . Then for , one has . We will also give some related comparison results.

Abstract:
We give some further consideration about logarithmic convexity for differences of power sums inequality as well as related mean value theorems. Also we define quasiarithmetic sum and give some related results.

Abstract:
We consider families of general four-point quadrature formulae using a generalization of the Montgomery identity via Taylor’s formula. The results are applied to obtain some sharp inequalities for functions whose derivatives belong to spaces. Generalizations of Simpson’s 3/8 formula and the Lobatto four-point formula with related inequalities are considered as special cases. 1. Introduction The most elementary quadrature rules in four nodes are Simpson’s rule based on the following four point formula where , and Lobatto rule based on the following four point formula where . Formula (1.1) is valid for any function with a continuous fourth derivative on and formula (1.2) is valid for any function with a continuous sixth derivative on . Let be differentiable on and integrable on . Then the Montgomery identity holds (see [1]) where the Peano kernel is In [2], Pe？ari？ proved the following weighted Montgomery identity where is some probability density function, that is, integrable function, satisfying , and for , for and for and is the weighted Peano kernel defined by Now, let us suppose that is an open interval in , , is such that is absolutely continuous for some , is a probability density function. Then the following generalization of the weighted Montgomery identity via Taylor’s formula states (given by Agli？ Aljinovi？ and Pe？ari？ in [3]) where and If we take , , equality (1.7) reduces to where and For , (1.9) reduces to the Montgomery identity (1.3). In this paper, we generalize the results from [4]. Namely, we use identities (1.7) and (1.9) to establish for each number a general four-point quadrature formula of the type where is the remainder and is a real function. The obtained formula is used to prove a number of inequalities which give error estimates for the general four-point formula for functions whose derivatives are from -spaces. These inequalities are generally sharp. As special cases of the general non-weighted four-point quadrature formula, we obtain generalizations of the well-known Simpson’s 3/8 formula and Lobatto four-point formula with related inequalities. 2. General Weighted Four-Point Formula Let be such that exists on for some . We introduce the following notation for each : In the next theorem we establish the general weighted four-point formula. Theorem 2.1. Let be an open interval in , , and let be some probability density function. Let be such that is absolutely continuous for some . Then for each the following identity holds Proof. We put and in (1.7) to obtain four new formulae. After multiplying these four formulae by ,

Abstract:
Matrix convexity of the Moore-Penrose inverse was considered in the recent literature. Here we give some converse inequalities as well as further generalizations.