Current Topics In Analytic Function TheoryShigeyoshi Owa, Hari M Srivastava World Scientific, 1992年12月31日 - 472 頁 This volume is a collection of research-and-survey articles by eminent and active workers around the world on the various areas of current research in the theory of analytic functions.Many of these articles emerged essentially from the proceedings of, and various deliberations at, three recent conferences in Japan and Korea: An International Seminar on Current Topics in Univalent Functions and Their Applications which was held in August 1990, in conjunction with the International Congress of Mathematicians at Kyoto, at Kinki University in Osaka; An International Seminar on Univalent Functions, Fractional Calculus, and Their Applications which was held in October 1990 at Fukuoka University; and also the Japan-Korea Symposium on Univalent Functions which was held in January 1991 at Gyeongsang National University in Chinju. |
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第 1 到 5 筆結果,共 85 筆
第 頁
... Defined by Ruscheweyh Derivatives 0. P- Ahuja Constraint Coefficient Problems for Subclasses of Univalent Functions H. S. Al-Amiri and D. Bshouty A New Subclass of Analytic Functions with Negative Coefficients 0. AUinta§ and Y. Eriekin ...
... Defined by Ruscheweyh Derivatives 0. P- Ahuja Constraint Coefficient Problems for Subclasses of Univalent Functions H. S. Al-Amiri and D. Bshouty A New Subclass of Analytic Functions with Negative Coefficients 0. AUinta§ and Y. Eriekin ...
第 2 頁
... defined on a domain D of Cwill be called a logharmonic mapping. Since the Jacobian determinant is Jy = |/z|2(l — |a|2), we conclude that / is orientation-preserving if and only if \a\ < 1 on D. In this case, / can be expressed as a ...
... defined on a domain D of Cwill be called a logharmonic mapping. Since the Jacobian determinant is Jy = |/z|2(l — |a|2), we conclude that / is orientation-preserving if and only if \a\ < 1 on D. In this case, / can be expressed as a ...
第 3 頁
... definition. Definition 1. Let D be the unit disk U or the annulus A(r, 1), rG (0,1) and suppose that f* is a continuous function defined on dD.We say that f is a logharmonic solution of the Dirichlet problem if (a) / is of the form (3); ...
... definition. Definition 1. Let D be the unit disk U or the annulus A(r, 1), rG (0,1) and suppose that f* is a continuous function defined on dD.We say that f is a logharmonic solution of the Dirichlet problem if (a) / is of the form (3); ...
第 4 頁
... Define h = ehl and g = e91. Then Lemma 1 follows. An analogous result holds also for ring domains. Lemma 2. Let f be a nonvanishing continuous function defined on the boundary dA(r,l) of the annulus A(r,l). Then there exists for each /3 ...
... Define h = ehl and g = e91. Then Lemma 1 follows. An analogous result holds also for ring domains. Lemma 2. Let f be a nonvanishing continuous function defined on the boundary dA(r,l) of the annulus A(r,l). Then there exists for each /3 ...
第 5 頁
... defined in (2). Lemma 3. Let f(z) = z\z\2f3hg~ be a logharmonic mapping defined on a domain D containing the origin z = 0. // |a(z0)| = 1 for some z0 G D, then f is at least two-valent in any neighbourhood V(z0) of z0. Proof. Define F ...
... defined in (2). Lemma 3. Let f(z) = z\z\2f3hg~ be a logharmonic mapping defined on a domain D containing the origin z = 0. // |a(z0)| = 1 for some z0 G D, then f is at least two-valent in any neighbourhood V(z0) of z0. Proof. Define F ...
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Amer analytic functions Bergman spaces bounded class of functions close-to-convex completes the proof complex plane convex functions convex sets Corollary defined denote the class Department of Mathematics derivative differential equation domains of univalence entire function euclidean extremal functions Fatou set Fractional Calculus function f(z functions with negative given H. M. Srivastava half-plane Hence holomorphic functions hyperbolic hypergeometric functions implies integral operator Julia set Lemma Little Picard Theorem locally schlicht logharmonic mapping Math meromorphic functions normal Nunokawa obtain p-valently starlike P. T. Mocanu problem Proc proof of Theorem properties radius Re(z real number Remark Rep(z result is sharp Ruscheweyh Saigo sharp for functions spherical linear invariance spherically convex starlike and convex starlike functions strictly increasing subclass Suppose TA(o unit disk Univ univalence for F(K univalent functions zero divisor zero set