CAMERON UNIVERSITY
DEPARTMENT OF MATHEMATICS
LAWTON, OKLAHOMA   73505-6377
U.S.A.


NAME:			IOANNIS K. ARGYROS
DATE-PLACE OF BIRTH:	20 February 1956,  Athens Greece
CITIZENSHIP:		U.S.A.

ADDRESS:	Cameron University
		Department of Mathematics
		Lawton, OK  73505  U.S.A.

E-MAIL:		ioannisa@cua.cameron.edu
TELEPHONE:	(405) 581-2908  or  (405) 581-2481  (Office)
		(405) 355-4504  (Home)


1.STUDIES

	(a)	1983-1984	:  Ph.D. in Mathematics.
                                   University of Georgia, Athens, GA.

	(b)	1982-1983	:  M.Sc. in Mathematics.
        			   University of Georgia, Athens, GA.

	(c)	1974-1979	:  B.Sc. in Mathematics.
 				   University of Athens, Greece.	

2.	ACADEMIC AND TEACHING EXPERIENCE

	(a)	1994-Present	:  Full Professor, Cameron University, U.S.A.
	(b)	1993-1994	:  Tenured Professor, Cameron University, U.S.A.
	(c)	1990-1993	:  Associate Professor, Cameron University, U.S.A.
	(d)	1986-1990	:  Assistant Professor, New Mexico State University, U.S.A.
	(e)	1984-1986	:  Assistant Professor, University of Iowa, U.S.A.
	(f)	1982-1984	:  Teaching-Research Assistant University of Georgia, U.S.A.
	(g)	1979-1982	:  Serving the Greek Army as Technical Consultant, GREECE.


COURSES TAUGHT
			GRADUATE

			(a)  Advanced Applied Analysis
			(b)  Numerical solution of Functional Equations
			(c)  The Finite Difference & the Finite-Element Method for 
			     O.D.E. & P.D.E.
			(d)  Advanced Numerical Analysis
			(e)  Thesis in Mathematics
			(f)  Special topics in Functional Analysis and
		 	     Numerical Functional Analysis.
			(g)  Optimization

			UNDERGRADUATE COURSES

			(a)  Calculus courses
			(b)  Differential equations
			(c)  Numerical Analysis
			(d)  Linear Algebra
			(e)  Real Analysis
			(f)  History of Mathematics
			(g)  Geometry
			(h)  Statistics
			(i)  Abstract Algebra
			(j)  Independent Study in Mathematics
			(k)  Matrix Algebra

3.	TEACHING EFFECTIVENESS

I believe that I have had some success in using computer softwares for some of the applied
math courses taught in the department.  Since my research area is applied mathematics it was
not difficult for me to use existing software as well as produce my own.  It has been
desirable for students to use computer softwares as a facilitating tool in many courses. 

I have been attending seminars and converences as well as constantly reviewing the
developments in my field in order to have a broad knowledge of Mathematical subjects.  I am
trying to be aware of its increasing relevance in our technological age, and be able to
stimulate my students to understand and possibly use some of these concepts in their future
careers. 

I am also concerned with the communication of these ideas to students.  Throughout the course
I try to make the concepts as understandable as possible by giving examples that help them
relate these ideas to topics in that course.  I have also provided opportunities to my
students in which they can express their views to the class to sharpen their skills in
discovering and communicating the concepts.  I have used my teaching effectiveness throughout
my teaching career. 

I have also produced a textbook (1993) (see (M) for details) to be used by students in
Mathematics, Economics, Physics, Engineering and the applied sciences.  A second textbook will
be published in (1996) and a third in (1998).  The books of course bear the Cameron University
name. 

I have also reviewed a Numerical Analysis textbook entitled "Introduction to Numerical
Analysis", by Kendall Atkinson, University of Iowa, published by Wiley and Jons (1992).  The
author in his preface recognizes and praises my talents in teaching and expresses his
gratitude for my contribution in the improvement of his book.  His textbook is considered to
be the best book in Numerical Analysis in this country. 

I have helped several students be accepted in graduate programs at the top universities in
this country. 

I have also helped them find jobs and still keep in contact with them and their careers after
they leave the University. 


The following Ph.D. students have obtained their Ph.D. degree under my supervision:

	(a)	Losta Mansor, Ph.D. dissertation title:  Numerical Methods for solving 
		singular perturbation problems appearing in elasticity and astrophysics, (1989).

	(b)	Joan Peeples, Ph.D. dissertation title:  Point to set mappings and oligopoly 
		theory, (1989).

Writer and Grader for the Funct-Num. Analysis, comprehensive examination 

	(a)	January 87, 88, 89
	(b)	August 87, 88

I prepared the Ph.D.  Comprehensive Examination Guide in Fun. Analysis.

	(a)	Chair, Master's Examination Committee,
	(b)	Mitra Ashan, Spring, 1987.
	(c)	Christopher Stuart, Spring, 1988.
	(d)	Anis Shahrour, Fall, 1988.

Member, Master's Examination Committee,

	(a)	Juji Hiratsuka, Spring, 1987. (Dean's Representative, Art Department).
	(b)	Alice Lynn Bertini, Spring, 1988.
	(c)	Daniel Patrick Eshner, Summer, 1989. (Dean's Representative, Computer Sci.).

Chair, Doctoral Oral Examination Committee,

	(a)	Losta, Mansor, Fall 1987 and Summer 1989 (Final Defense).
	(b)	Joan Peeples, Spring 1989 and Summer 1989 (Final Defense).

Member, Doctoral Oral Examination Committee,

	(a)	Aomar Ibenbrahim, Spring 1987.
	(b)	Maragoudakis Christos, Spring 1988.

(Dean's Representative for both, Electrical Engineering Department).

4.	SCIENTIFIC ACTIVITY

    (A)  Fields of interest:

	(a)  Applied Analysis.
	(b)  Numerical Functional Analysis.
	(c)  Numerical Analysis, Numerical methods.
	(d)  Optimization.
	(e)  Parallel computing.
	(f)  Differential-Integral Equations.
	(g)  Fixed point theory.
	(h)  Statistics.

Most of my research falls into three categories, Applied Analysis, Numerical Analysis (Mainly
Numerical Methods, Prediction Theory, Error Analysis, Numerical Functional Analysis),
Optimization and Statistics. 

    (B)  APPLIED ANALYSIS

The so-called polynomial operators are a natural generalization of linear operators. 
Equations in such operators are the linear space analog of ordinary polynomials in one or
several variables over the fields of real or complex numbers.  Such equations encompass a
broad spectrum of applied problems including all linear equations.  Often the polynomial
nature of many non-linear problems goes unrecognized by researchers.  This is most likely due
to the fact that unlike polynomials in a single variable, polynomial operators have received
little attention.  Whether this situation is due to an inherent intractability of these
operators or to simple oversight remains to be seen.  Hopefully, one should be able to exploit
their semi-linear character to wrest more extensive results for these equations than one can
obtain in the general non-linear setting. 

Examples of equations involving polynomial operators can be found in the literature.  My
contribution in this area can be found in papers #3, 4, 6-12, 16, 22, 23, 25, 35, 84.  Many of
the equations of elasticity theory are of this type #3,4.  The problem discussed there
pertains to the buckling of a thin shallow spherical shell clamped at the edge and under
uniform external pressure. 

Some equations in heat transfer, kinetic theory of gases and neutron transport, including the
famous Chandrasekhar (Nobel in Physics, 1983) integral equation are of quadratic type. 
Numerical methods for finding small or large solutions of the above equations and their
variations as well as results on the number of solutions of the above equations can be found
in papers #1-4, 21, 24, 37, 55, 85, 99. 

Some pursuit and bending of beams problems can be formulated as polynomial equations.  My
investigations on such equations can be found in paper #6. 

Paper #11, contains results on the study of feedback systems containing an arbitrary finite
number of time-varying amplifiers and the study of electromechanical networks containing an
arbitrary number of time-varying nonlinear dissipative elements. 

Scientists that have worked in this area, agree that much work both of theoretical and
computational nature remains to be done on polynomials in a normed linear space.  A summary of
some of the remaining problems can be found in my third book entitled The Solution of
Polynomial Operator Equations in Abstract Spaces and Applications". 

It must certainly be mentioned that the existence theory is far from complete and what little
is there it is confined to local small solutions in neighborhoods which are often of very
small radius #1-5, 7-9, 13, 14, 17, 26, 30, 33.  In my papers #5, 6, 8, 10, 23, 30, 33, 34,
37, 42, 69, 72, I have provided numerical methods for approximating distinct solutions of
polynomial equations under various hypotheses. 

As far as I know the above mentioned authors are the only researchers that have worked on
global existence theorems not related with contractions.  My contribution in this area is
contained in papers #7, 14, 23, 34, 35, 44, 69. 

Moreover for those of a qualitative rather than computational frame of mind, it has been
suggested that polynomial operators should carry a Galois theory.  Such a theory, should it
exist, may be very limited, but nonetheless, interesting.  The pessimistic note is prompted by
the fact that a complete general spectral theory does not exist for polynomial operators.  In
an attempt to produce such a theory at least the way an analyst understands it, I wrote the
relevant papers #18, 23, 34, 35, 45. 

Finally papers #15, 41, 45, 47, 83 deal with the related area of fixed point theory.

    (C)  NUMERICAL ANALYSIS, NUMERICAL METHODS, PREDICTION THEORY, OPTIMIZATION

The most important iterative procedures for solving nonlinear equations in a Banach space are
undoubtedly the so called Newton-Like methods.  Indeed, L.V. Kantorovich has given sufficient
conditions for the quadratic convergence of Newton's iteration to a locally unique solution of
the abstract nonlinear equation in Banach space.  His conditions are in some sense the best
possible.  For the scalar case these conditions coincide with those given earlier by A. I. 
Ostrowski.  Simple sharp apriori estimates were given independently (by different methods) by

W. B. Gragg and R. A. Tapia.  The method of nondiscrete mathematical induction was used later
by V. Ptak, F. Potra, X. Chen, T. Yamamoto, P. Zabrejko, D. Ngyen, I. Moret et. al.; this
method yields not only sharp apriori estimates but also convergence proofs through the
induction theorem.  This method, in which the rate of convergence is now a function and not a
number, is closely related with the closed graph theorem.  My contribution in this area can be
found in the papers #19, 20, 31, 40, 44, 47, 50, 51, 57, 60, 61, 63, 65, 68, 70, 81, 82,
83,89, 90, 92, 95, 96, 97, 101, 125, 129, 145. 

One of the basic assumptions for the use of Newton's method is the condition that the Frechet
derivative of the nonlinear operator involved be Frechet-differentiable.  There are however
interesting differential equations and singular integral equations (see for example the work
of Etzio Venturino) where the nonlinear operator is only Holder continuous.  It turns out that
the error analysis of Newton-Like methods changes dramatically and the results obtained by the
above authors do not hold in this setting.  My contribution in this area can be found in the
papers #19, 20, 31, 32, 38, 63, 68, 71, 100. 

Papers #65, 73, 104, 106 deal with the solutions of nonlinear operator equations containing a
nondifferentiable term. 

Papers #61, 80, 89, 101, 104, 113  deal with the approximation of implicit functions.

Papers #60, 66, 79, 81, 95, 104 deal with projection methods for the approximate solution of
nonlinear equations. 

Papers #64, 125, 143 deal with iterative procedures for the solution of nonlinear equations in
generalized Banach spaces. 

Papers #88, 114, 128, 130, 152 deal with inexact iterative procedures. 

Papers #54, 56, 67, 98, 124 deal with the solution of nonlinear operator equations and their
discretizations in relation with the mesh-independence principle. 

Papers #82, 105, 116 deal with the solution of linear and nonlinear perturbed two-point
boundary value problems with left, right and interior boundary layers. 

I have applied the above numerical methods, in particular Newton's and its variations to
concrete integral equations arising in radiative transfer.  See for example papers #21, 37. 
Since the numerical solution of integral equations is closely related to compact operators, I
tried in the papers #28, 39, 53, 74 to find some results relating numerical methods and
compactness.  Work on this subject has already been conducted (see e.g. the work of P.
Anselone & K. Atkinson), but the results so obtained are too general or too particular to be
used for my purposes. 

Papers #91, 121, 131, 132, 133, 138, 140, 149, 153-218 deal with the convergence and error
analysis of multipoint iterative methods in Banach spaces. 

Paper #103 deals with the introduction of an optimization algorithm based on the gradient
projection technique and the Karmarkar's projective scaling method for linear programming. 

Papers 214-218 involve perturbed nondifferentiable operator equations on generalized Banach
spaces with a convergence structure and Newton methods. 

    (D)  STATISTICS

Paper #123 deals with t-estimates of parameters of general nonlinear models in finite
dimensional spaces.  The method is highly insensitive to outliers.  It can also be applied to
solve a system of nonlinear equations. 

    (E)  ECONOMY

Papers #62, 74, 76, 93, 94, 107, 134, 139 deal with the convergence of iteration schemes
generated by the recursive application of a point-to-set mapping.  Our results have been
applied to solve dynamic economic as well as input-output systems. 

    (F)  SEMINARS

At the University of Iowa I gave eight seminars per academic year in Numerical and Functional
Analysis.  I continue doing so at New Mexico State and Cameron University.  During my talks I
either explain my current work or I go through some papers of areas mentioned in (A)-(E). 

    (G)  PAPERS PRESENTED

(1) University of Berkeley.  International Summer Institute on Nonlinear Functional Analysis
and Applications. (1983).  Title :  "On a contraction theorem and applications". 

(2) Los Alamos Laboratories (organizers).  Conference on Invariant Imbedding, transport 
theory, and Integral Equations.  Eldorado Hotel, Santa Fe, N.M. (1988).  Title:  "On a class of 
nonlinear equations arising in neutron transport."

(3) Annual meeting of the American Mathematical Society #863.  San Francisco, California June
16-19, 1991. Title: "On the convergence of Algorithmic models" (Chairman of the Numerical
Analysis Session (#516), 7:00 p.m. - 9:55 p.m. Thursday Jan. 17, 1991). 

(4) Mathematical Association of America, Oklahoma-Arkansas Section, Spring 1991.  Title: 
"Improved bounds for the zeros of polynomials". 

(5) Annual meeting of the American Mathematical Society #871.  Baltimore, Maryland Jan.  8-11,
1992.  Title:  "On the midpoint iterative method for solving nonlinear operator equations in
Banach spaces". 

(6) CAM 92, Edmond, OK, March 27, 1992.  University of Central Oklahoma, Title:  "On the
secant method under weak assumptions" 

(7) CAM 93, Edmond, OK, February 5, 1993.  University of Central Oklahoma, Title: "On a
two-point Newton method in Banach spaces of order four and applications". 

(8) As in (7), Title:  "Sufficient convergence conditions for itertions schemes modeled by
point-to-set mappings". 

(9) As in (7), Title:  "On a two-point Newton method in Banach spaces and the Ptak error
estimates". 

(10) CAM 94, Edmond, OK, February 4, 1994. University of Central Oklahoma, Title:  "On the
monotone convergence of fast iterative methods in partially ordered topological spaces". 

(11) CAM 94, Edmond, OK, February 4, 1994. University of Central Oklahoma, Title:  "On a
multistep Newton method in Banach spaces and the Ptak error estimates". 

(12) 56th Annual Meeting of the Oklahoma-Arkansas session of the Mathematical Association of
America, March 24, 1994.  Title:  "On an inequality from applied analysis".  (Analysis
section).  It was held at the University of Searcy, Searcy, Arkansas. 

(13) CAM 95, Edmond, OK, February 10, 1995, University of Central Oklahoma.  "A mesh
independence principle for nonlinear equations in Banach spaces and their discretizations. 

(14) 57th Annuale Meeting of the Oklahoma-Arkansas session of the Mathematical Association of
America, March 1995.  Title: "On the discretization of Newton-like methods", Southwestern
Oklahoma State University, Weatherford, Oklahoma. 

    (H)  SELECTED LECTURES PRESENTED

		University of Georgia, 1982-1984
		University of Iowa, 1984-1986
		State University of Iowa, 1985
		Northern University of Virginia, 1986, 1988
		New Mexico State University, 1986-1990
		University of Ohio, 1986
		University of Iowa, 1986, 1988
		University of New York, 1986-1988
		University of Texas at El-Paso, 1987-1990
		University of Arizona, I.E.D., 1989, 1990
		Portland State University, 1990
		Cameron University, 1990
		University of Central Oklahoma, 1992, 1993
		University of Cyprus, Nicosia Cyprus, 1993

    (I)  OTHER MEETINGS ATTENDED

(1) American Mathematical Society/Mathematical Association of America annual meetings, Denver,
Colorado, 1983, & Phoenix, Arizona, 1989. 

(2) SIAM Mathematical meetings, Des Moines, Iowa, 1985. 

(3) International Conference on Theory and Applications of Differential Equations, Ohio
University, Athens, Ohio, 1988. 

(4) Annual research conferences of the Bureau of the Cencus, Arlington , Virginia, March 21-
24, 1993 and 1995. 

    (J)  COMPUTING EXPERIENCE IN

	(a) 	Fortran
	(b)  	Pascal
	(c)     Cobol
	(d)  	Basic
	(e)  	Parallel computing.

	(K)  GRANTS RECEIVED

	(a)  	New Mexico State University Grant, (1986), #1-3-43841, RC #87-01.
	(b)  	New Mexico State University International Grant, (1987), #1-3-44770.
	(c) 	U.S.A. Army, (1988-1990), #DAEA, 26-87-R-0013 (F.M.)ARMY jointly the 
                Mechanical Engineering Department (N.M.S.U.).
	(d)	Cameron University, research support July, (1992) - June, (1994).

    (L)  RESEARCH ARTICLES

The scientific papers listed below have been published in the following continents and at the
top refereed journals in the following countries repeatedly: 

America:  U.S.A., Canada, Chile.

Europe:  U.K., Sweeden, Belgium, Holland, Spain, Germany, Austria, Hungary, Chechoslovakia,
Romania, Poland, Yugoslavia, Italy. 

Asia:  Peoples Republic of China, Republic of China, India, Pakistan, Japan, Saudi Arabia.

Australia: Australia.

A 7% of the scientific papers listed below have been published jointly with professors
Mohammad Tabatabai (Cameron, U.S.A.) Dong Chen (University of Arkansas, U.S.A.), Ferenc
Szidarovszky (University of Arizona, U.S.A.) and Losta Mansor (Saudi Arabia). 

Finally 68% of the papers are published with the name of Cameron University. 

1. A contribution to the theory of nonlinear operator equations in Banach space, Master of
Science Dissertation, (1983). 

2. Quadratic equations in Banach space, perturbation techniques and applications to
Chandrasekhar's and related equations, Doctor of Philosophy Dissertation, (1984). 

3. Quadratic equations and applications to Chandrasekhar's and related equations, Bull. 
Austral. Math. Soc. Vol. 32, 2, (1985), 275-292;  Not. Amer. Math. Soc. 85T-46-142; 
Z.F.M.6074063 (1987); Math. Rev.87d:  47077, Gerard Lebourg (Paris). 

4. On a contraction theorem and applications, Proc. Amer. Math. Soc., Symposium on Nonlinear
Functional Analysis and Applications, 45, 1, (1986) 51-53; Math. Rev. 87h:  65108, Sh.Singh,
Z.F.M.6224077 (1988). 

5. Iterations converging to distinct solutions of some nonlinear equations in Banach space,
Internat. J. Math. & Math. Sci. Vol. 9 No. 3 (1986), 583-587; Z.F.M.61447044 (1986); Math.
Rev. 87j47097, P.P. Zabrejko (Minsk). 

6. On the cardinality of solutions of multilinear differential equations and applications,
Internat. J. Math. & Math. Sci. Vol. 9 No. 4 (1986), 757-766.  Math. Rev. 88e34017, Achmadjon
Soleev (Samarkand); Z.F.M.66334008 (89), A. Soleev. 

7. Uniqueness-Existence of solutions of polynomial equations in linear space, P.U.J.M., Vol.
XIX, (1986), 39-57; Z.F.M.62547050 (1988); Math. Rev. 88g47116 B.G. Pachpatte (6-Mara). 

8. On a theorem for finding "large" solutions of multilinear equations in Banach space,
P.U.J.M., Vol. XIX, (1986), 29-37; Z.F.M.62547051 (1988); Math. Rev. 88g47115, B.G.  Pachpatte
(6-Mara). 

9. On the approximation of some nonlinear equations, Aequationes Mathematicae 32, (1987),
87-95; Z.F.M.61447043 (1986); Math. Rev. 88g47124, P.P. Zabrejko (Minsk). 

10. An Improved condition for solving multilinear equations, P.U.J.M., Vol. XX, (1987), 43-46;
Math. Rev. 89c47075; Z.F.M.64747015, (1989). 

11. On a class of nonlinear equations, Tamkang J. Math. Vol. 18 No 2, (1987), 19-25;  Math.
Rev. 89f47091, Ramendra Krishna Bose (1-SUNYF); Z.F.M.65347042, (1989), J.  Appel. 

12. On polynomial equations in Banach space, perturbations techniques and applications,
Internat. J. Math. & Math. Sci. Vol. 10 No. 1, (1987), 69-78; Math. Rev. 88c47123, Heinrich
Steinlein (Munich); Z.F.M.61747038, (1987). 

13. A note on quadratic equations in Banach space, P.U.J.M., Vol. XX, (1987), 47-50;  Math.
Rev. 89c47076; Z.F.M.64747016, (1989). 

14. Quadratic finite rank operator equations in Banach space, Tamkang J. Math. Vol. 18 No 4.
(1987), 8-19; Z.F.M.66247011(89); Math. Rev. 89k47100, Nicole Brillouet- Belluot, (Nantes). 

15. On some Theorems of Mishra Ciric and Iseki, Mat. Vesnik, Vol. 39, (1987), 377- 380; Math.
Rev. 89c54083; Z.F.M.64854035, (1989). 

16. An iterative solution of the polynomial equation in Banach space, Bull. Inst. Math.  Acad.
Sin. Vol. 15, No. 4. (1987), 403-410, (Not. in Math. Rev. 89) 47H17, 46G99, 58C15. 

17. A survey on the ideals of the space of bounded linear operators on a separable Hilbert
space, Rev. Acad. Ci. Exactas Fis. Quim. Nat. Zaragoza, II. Ser. 42, (1987), 24-43; Math. Rev. 
89g47059. 

18. On the solution by series of some nonlinear equations, Rev. Acad. Ci. Exactas Fis.  Quim.
Nat. Zaragoza, II. Ser. 42, (1987), 18-23. Z.F.M.64947048, (1989). Math. Rev.  90f65085, V.V.
Vasin (Sverdlosk). 

19. Newton-Like methods under mild differentiability conditions with error analysis, Bull.
Austral. Math. Soc. Vol. 37, 1, (1988), 131-147; Z.F.M.62965061, (1988), S. Reich;  Math. Rev.
89b65142, A.V. Dzhishkariani (Tbilisi). 

20. On Newton's method and nondiscrete mathematical induction, Bull. Austral. Math. Soc.  Vol.
38, (1988), 131-140; Math. Rev. 90a65136, A.M. Galperin (Ben-Gurion Intern. Airp.). 

21. On a class of nonlinear integral equations arising in neutron transport, Aequationes
Mathematicae. Vol. 35, (1988), 99-111; Math. Rev. 89M47058 H.E. Gollwitzer (1-DREX). 

22. On multilinear equations, Pr. Rev. Mat. Vol. 14, July, (1988), 95-105. 

23. New ways for finding solutions of polynomial equations in Banach space, Tamkang J.  Math.
Vol. 19, 1, (1988), 37-42.  Math Rev. 90f47093, V. V. Vasin, (Sverdlosk). 

24. On a new iteration for solving the Chandrasekhar's H-equations, Pr. Rev. Mat. No 15,
(1988), 21-31. 

25. On a new iteration for solving polynomial equations in Banach space, Funct. et Approx.
Comment. Math. Vol. XIX (1988). 

26. Conditions for faster convergence of contraction sequences to the fixed points of some
equations in Banach space, Tamkang J. Math. Vol. 19, 3, (1988), 19-22.  Math. Rev.  90j47074,
Roman Manka (Mogilno). 

27. On some nonlinear equations, Pr. Rev. Mat. No 15, (1988), 75-82. 

28. On the approximation of solutions of compact operator equations, PR. Rev. Mat. Vol.  14,
July, (1988), 29-46. 

29. Approximating the fixed points of some nonlinear equations, Mathem. Slovaca, 38, #4
(1988), 409-417; Z.F.M.667 (1989), S.L. Singh. Math. Rev. 90g47109 (O.P.Kapoor (6-11TK)). 

30. Some sufficient conditions for finding a second solution of the quadratic equation in
Banach space, Mathem. Slovaca, 4, (1988).  Math. Rev. 90g47108. (O.P. Kapoor (6-11TK)). 

31. Concerning the approximate solutions of operator equations in Hilbert space under mild
differentiability conditions, Tamkang J. Math. Vol 19, 4, (1988), 81-87. 

32. On the Secant method and fixed points of nonlinear equations, Monatshefte fur Mathematik,
106, (1988), 85-94; Z.F.M.65265043, (1989).  Math. Rev. 90b6511, A.M.Galperin, Ben-Gurion
Intern. Airport. 

33. An iterative procedure for finding "large" solutions of the quadratic equation in Banach
space, P.U.J.M. Vol.XXI, (1988), 13-21. 

34. Vietta-Like relations in Banach space, Rev.Acad.Ci.Exactas Fis.Quim.Nat.Zaragoza, I,
Ser.43, (1988), 103-107. Math. Rev. 47f47095, V.V. Vasin, (Sverdlovsk). 

35. A global theorem for the solutions of polynomial equations, Rev. Acad. Ci. Exactas Fis. 
Quim. Nat. Zaragoza, I, Ser. 43, (1988), 93-101.  Math. Rev. 90f47094, V.V. Vasin,
(Sverdlosk). 

36. Concerning the convergence of Newton's method, P.U.J.M. Vol. XXI, (1988), 1-11. 

37. On the number of solutions of some integral equations arising in radiative transfer,
Internat. J. Math. & Math. Sci. Vol. 12, No. 2, (1989), 297-304.  Math. Rev. 90h86004 S. 
Rajasekar (Ticuchirapalli). 

38. On the approximate solutions of operator equations in Hilbert space under mild
differentiability conditions, J. Pure & Appl. Sc. Vol. 8, No. 1, (1989), 51-56. 

39. On the fixed points of some compact operator equations, Tamkang J. Math. vol. 20, No. 3,
(1989), 203-209.  Math Rev. 91a47088 Jing Xian Sum (PRC-Shan). 

40. Error bounds for a certain class of Newton-Like methods, Tamkang J. Math. Vol. 20, No. 4,
(1989). 

41. On a generalization of fixed and common fixed point theorems of operators in complete
metric spaces, Rev. Mat. Cubo, 5, (1989), 17-25. 

42. Approximating distinct solutions of quadratic equations in Banach space, Rev. Mat.  Cubo,
5, (1989), 1-16. 

43. Concerning the convergence of iterates to fixed points of nonlinear equations in Banach
space, Bull. Malays. Math. Soc. Vol. 12, 2, (1989), 15-24. 

44. A series solution of the quadratic equation in Banach space, Chinese J. Math. Vol. 27, No.
4, (1989).  Math. Rev. 90k47131. 

45. On a fixed point in a 2-Banach space, Rev. Acad. Ciencias, Zaragoza 44, (1989), 19-21. 
Math. Rev. 91a47077. 

46. Some matrices in oligopoly theory, New Mexico J. Sci. 29, 1, (1989), 22. 

47. On a theorem of Fisher and Khan, Rev. Acad. Ciencias, Zaragoza, 44, (1989), 13- 17. 

48. On quadratic equations, Mathematica-Rev. Anal. Numer. Theor. Approximation 18, 1, (1989),
19-26. 

49. Concerning the approximate solutions of nonlinear functional equations under mild
differentiability conditions. Bull. Malays. Math. Soc. Vol. 12, 1, (1989), 55-65. 

50. On the convergence of certain iterations to the fixed points of nonlinear equations,
Annales sectio computatorica.  Ann. Univ. Sci. Budapest. Sect. Computing 9, (1989), 21-31. 

51. On the secant method and nondiscrete mathematical induction.  Mathematica-Revue D'analyse
Numerique et de theorie de l'approximation tome 18, No. 1, (1989), 27-36. 

52. On Newton's method for solving nonlinear equations and multilinear projections, Functiones
et approximatio Comment. Math., XIX, (1990), 41-52. 

53. Nonlinear operator equations and pointwise convergence, Functiones et approximatio
Comment. Math., XIX, (1990), 29-39. 

54. Iterations converging faster than Newton's method to the solutions of nonlinear equations
in Banach space, Functiones et approximatio Comment. Math., XIX, (1990), 23-28. 

55. On some quadratic integral equations, Functiones et Approximmatio, XIX, (1990), 159-166. 

56. A mesh independence principle for nonlinear equations using Newton's method and nonlinear
projections, Rev. Acad. Ciencias. Zaragoza 45, (1990), 19-35. 

57. Error bounds for the modified secant method, BIT, 30, (1990), 92-100. 

58. Improved error bounds for a certain class of Newton-Like methods, J.  Approximation Theory
and its Applications, (6:1), (1990), 80-98. 

59. On the solution of some equations satisfying certain differential equations, P.U.J.M., Vol
XXIII, (1990), 47-59. 

60. On some projection methods for approximating the fixed points of nonlinear equations in
Banach space, Tamkang J. Math., Vol. 21, 4, (1990), 351-357. 

61. On some projection methods for the approximation of implicit functions, Appl. Math.  Lett.
Vol. 3, No. 2, (1990), 5-7.  Math. Rev. 91b65066. 

62. On the monotone convergence of some iterative procedures in partially ordered Banach
spaces, Tamkang J. Math. Vol. 21, No. 3, (1990), 269-277. 

63. The Newton-Kantorovich method under mild differentiability conditions and the Ptak error
estimates, Monatshefte fur Mathematik, Vol. 109, No. 3, (1990). 

64. The secant method in generalized Banach spaces, Appl. Math. & Comput., 39, (1990),
111-121. 

65. On the solution of equations with nondifferentiable operators and Ptak error estimates,
BIT, 30, (1990), 752-754. 

66. On some projection methods for enclosing the root of a nonlinear operator equation, 
P.U.J.M., Vol XXIII, (1990), 35-46.

67. A mesh independence principle for operator equations and their discretizations under mild
differentiability conditions, Computing, 45, (1990), 265-268. 

68. On Newton's method under mild differentiability conditions, Arabian J. Math. Vol.  15, 1,
(1990), 233-239. 

69. Remarks on quadratic equations in Banach space, Intern. J. Math. & Math. Sc., Vol.  13,
No. 3, (1990), 611-616. 

70. On the improvement of the speed of convergence of some iterations converging to solutions
of quadratic equations, Acta Math. Hungarica, Vol. 57/3-4, (1990),

71. A note on Newton's method, Rev. Acad. Ciencias Zaragoza, 45, (1990), 37-45. 

72. On the solution of compact linear and quadratic operator equations in Hilbert space, Rev.
Acad. Ciencias Zaragoza, 45, (1990), 47-52. 

73. On some generalized projection methods for solving nonlinear operator equations with a
nondifferentiable term, Bull. Malays. Math. J., Vol 13, No. 2, (1990), 85-91. 

74. Comparison theorems for algorithmic models, Applied Math. and Comput., Vol. 40, No. 2,
Nov. (1990), 179-187. 

75. On an iterative algorithm for solving nonlinear equations, Beitrage zur Numerischen Math.
(Renamed Z.A.A.), Vol. 10, No. 1, (1991), 83-92. 

76. On time dependent multistep dynamic processes with set valued iteration functions on
partially ordered topological spaces, Bull. Austal. Math. So., Vol. 43, (1991), 51-61. 

77. Error bounds for the secant method, Math. Slovaca, Vol. 41, 1, (1991), 69-82. 

78. On the approximate solutions of nonlinear functional equations under mild
differentiability conditions, Acta Math. Hungarica, Vol. 58 (1-2), (1991), 3-7. 

79. On the convergence of some projection methods with perturbation, J. Comput. and Appl.
Math. 36, (1991), 255-258. 

80. On an application of a modification of the Zincenko method to the approximation of
implicit functions, Z.A.A. 10, 3(1991), 391-396. 

81. On some projection methods for solving nonlinear operator equations with a
nondifferentiable term, Rev. Academia de Ciencias, Zaragoza, 46, (1991), 17-24. 

82. Integral equations for two-point boundary value problems. Rev. Academia de Ciencias,
Zaragoza 46, (1991), 25-35. 

83. A fixed point theorem for orbitally continuous functions, Pr. Rev. Mat. Vol. 10, No.  7,
(1991), 53-57. 

84. Bounds for the zeros of polynomials, Rev. Academia de ciencias. Zaragoza, 47, (1992),
61-66.. 

85. On a class of quadratic equations with perturbation, Functiones et Approximmatio, XX,
(1992), 51-63. 

86. On a new iteration for finding "almost" all solutions of the quadratic equation in Banach
space, Studia Scientiarum Mathematicarum Hungarica, 27 (3-4), (1992), 361-368. 

87. A Newton-like method for solving nonlinear equations in Banach space, Studia Scientiarum
Mathematicarum Hungarica, 27 (3-4), (1992), 369-378. 

88. On the convergence of nonstationary Newton-methods, Func. et. Approx., Vol. XXI, (1992),
7-16. 

89. On an application of the Zincenko method to the approximation of implicit functions. 
Publicationes Mathematicae, Vol. 40/1-2; (1992), 43-49. 

90. Improved error bounds for the modified secant method, Intern. J. Computer Math.  Vol. 43,
No. 1+2, (1992), 99-109. 

91. On the midpoint method for solving nonlinear operator equations in Banach spaces, Appl.
Math. Letters, Vol. 5, No. 4, (1992), 7-9. 

92. On an application of a Newton-like method to the approximation of implicit functions,
Math. Slovaca, 42, No. 3, (1992), 339-347. 

93. On the monotone convergence of general Newton-like methods, Bull. Austral. Math.  Soc.,
45, (1992), 489-502. 

94. Convergence of general iteration schemes, J. Math. Anal. and Applic., 168, No. 1, (1992),
42-62. 

95. Some generalized projection methods for solving operator equations. Journ. Comp.  Appl.
Math., 39, No. 1 (1992), 1-6. 

96. Sharp error bounds for a class of Newton-like methods under weak smoothness assumptions.,
Bull. Austral. Math. Soc. 45, (1992), 415-422. 

97. Approximating Newton-like procedures, Appl. Math. Lett., Vol. 5, No. 1, (1992), 27-29. 

98. On a mesh independence principle for operator equations and the secant method, Acta Math.
Hungarica, 60, 1-2, (1992), 7-19. 

99. On the solution of quadratic integral equations, P.U.J.M., Vol. XXV , (1992), 131- 143. 

100. The secant method under weak assumptions, Proceedings CAM 92, Edmond, OK, June (1992),
7-18. 

101. On the convergence of generalized Newton-methods and implicit functions, Journ.  Comp.
Appl. Math. 43, (1992), 335-342. 

102. On a Stirling-like method, P.U.J.M., Vol. XXV (1992), 83-94. 

103. An algorithm for solving nonlinear programming problems using Karmarkar's technique,
Proceedings CAM 92, Edmond, OK, June (1992), 287-296. 

104. On the approximate construction of implicit functions and Ptak error estimates, P.U.J.M.,
Vol. XXV, (1992), 95-98. 

105. On the numerical solution of linear perturbed two-point boundary value problems with
left, right and interior boundary layers. Arabian J. Science and Engineering 17 : 4B, October
(1992), 611-624. 

106. On the convergence of Newton-like methods. Tamkang J. Math, Vol. 23, No. 3 (1992),
165-170. 

107. On the monotone convergence of algorithmic models, Applied Math. and Comput. 48, (2-3),
(1992), 167-176. 

108. Approximating Newton-like iterations in Banach space, P.U.J.M., Vol. XXV, (1992), 49-59. 

109. On the approximation of quadratic equations in Banach space using finite rank operators,
Rev. Academia de ciencias Zaragoza 47, (1992), 67-76. 

110. Remarks on the convergence of Newton's method under Holder continuity conditions. 
Tamkang J. Math. Vol. 23, No. 4 (1992), 269-277. 

111. On the solution of nonlinear operator equations in Banach space and their
discretizations, Pure Mathematics and Applications, Ser. B, Vol. 3, No. 2-3-4 (1992), 157-
173. 

112. On the convergence of optimization algorithms modeled by point-to-set mappings, Pure
Mathematics and Applications, Ser. B, Vol. 3, No. 2-3-4, (1992), 77-86. 

113. On an application of a modification of a Newton-Like method to the approximation of
implicit functions, Bull. Malays Math. Soc., Vol 16, 1, (1993), 25-32. 

114. On the convergence of inexact Newton-like methods, Public. Math. Debrecen, Vol. 43, 1-2,
(1993), 79-85. 

115. On some projection methods for the solution of nonlinear operator equations with
nondifferentiable operators.  Tamkang J. Math. Vol. 24, No. 1 (1993), 1-8. 

116. An initial value method for solving singular perturbed two-point boundary value problems.
Arabian Journ. Scienc. and Engineer. Vol. 18, 1 (1993), 3-5. 

117. On the solution of nonlinear equations with a nondifferentiable term, Mathematica- Revue
D'analyse Numerique et de theorie de l'approximation Tome 22, 2 (1993), 125-135. 

118. Some methods for finding error bounds for Newton-like methods under mild
differentiability conditions, Acta Math. Hungarica, 61, (3-4), (1993), 183-194. 

119. On the secant method, Publicationes Mathematicae Debrecen, Vol. 43, 3-4, (1993), 223-238. 

120. Improved error bounds for Newton's method under generalized Zabrejko-Nguen-type
assumptions. Appl. Math. Letters Vol. 6, No. 3, (1993), 75-77. 

121. A fourth order iterative method in Banach spaces. Appl. Math Letters Vol. 6, No. 4,
(1993), 97-98. 

122. Newton-like methods and nondiscrete mathematical induction, Studia Scientiarum
Mathematicarum Hungarica, 28 (1993), 417-426. 

123. Robust estimation and testing for general nonlinear regression models.  Appl. Math.  and
Comp. 58, (1993), 85-101. 

124. A mesh independence principle for nonlinear operator equations in Banach space and their
discretizations, Studia Scientiarum Math. Hung. 28, (1993) 401-415. 

125. Sharp error bounds for the secant method under weak assumptions. P.U.J.M. Vol.  XXVI,
(1993), 54-62. 

126. An error analysis of Stirling's method in Banach spaces, Tamkang J. Math., Vol. 24, No. 2
(1993), 115-133. 

127. New sufficient conditions for the approximation of distinct solutions of the quadratic
equation in Banach space, Tamkang J. Math, Vol. 24, No. 4, (1993), 355-372. 

128. On the convergence of inexact Newton methods. Chinese J. Math. Sept. Vol 21, No. 3 (1993)
227-234. 

129. On the solution of equations with nondifferentiable operators, Tamkang J. Math., Vol. 
24, No. 3, (1993), 237-249. 

130. Sufficient conditions for the convergence of general iteration schemes, Chinese J. 
Math., Vol. 21, No. 2 (1993), 195-205. 

131. On a two-point Newton method in Banach spaces of order four and applications, (1993),
Proceedings of the 9th Annual Conference on Applied Mathematics, CAM 93, University of
Central, Oklahoma, Edmond, (1993), 34-48, P.U.J.M. Vol. 27, (1994). 

132. On a two-point Newton method in Banach spaces of order three and applications Proceedings
of the 9th Annual Conference on Applied Mathematics, CAM 93, University of Central, Oklahoma,
Edmond, (1993), 24-37, P.U.J.M., Vol. 27, (1994). 

133. On a two point Newton-method in Banach spaces and the Ptak error estimates, Proceedings
of the 9th Annual Conference on Applied Mathematics, CAM 93, University of Central Oklahoma,
Edmond, (1993), 8-24. 

134. Sufficient convergence conditions for iteration schemes modeled by point-to-set mappings,
Proceedings of the 9th Annual Conference on applied Mathematics, CAM 93, University of Central
Oklahoma, CAM 93, Edmond, OK (1993), 48-52.  Also Applied Mathematics Letters, (1996). 

135. On the convergence of a Chebysheff-Halley-type method under Newton-Kantorovich
hypotheses. Appl. Math. Letters Vol. 6, No. 5, (1993), 71-74. 

136. On an application of a variant of the closed graph theorem and the secant method. 
Tamkang J. Math. Vol. 24, No. 3 (1993), 251-267. 

137. Newton-like methods in partailly ordered Banach spaces. Approx. Theory and Its Applic. 9
: 1 (1993), 1-10. 

138. Results on the Chebyshev method in Banach spaces. Projecciones Revista Vol. 12, No.  2,
(1993), 119-128. 

139. On the convergence of an Euler-Chebysheff-type method under Newton-Kantorovich
hypotheses, Pure Mathematics and Applications, Vol. 4, No. 3, (1993), 369-373. 

140. A note on the Halley method in Banach spaces.  Appl. Math. and Comp. 58 (1993), 215-224. 

141. On the solution of underdetermined systems of nonlinear equations in Euclidean spaces,
Pure Mathematics and Applications, Vol 4, No. 3, (1993), 199-209. 

142. On the a posteriori error bounds for a certain iteration under Zabrejko-Ngyen
assumptions, Rev. Academia de Ciencias, Zaragoza (48), (1993), 77-85. 

143. Newton-like methods in generalized Banach spaces, Functiones et Approximatio, XXII,
(1993), 107-114. 

144. On S-order of convergence, Rev. Academia de Ciencias Zaragoza, 48, (1993), 69- 76. 

145. A theorem on perturbed Newton-like methods in Banach spaces. Studia Scientiarum
Mathematicarum Hungarica, 29, (1994), 295-305. 

146. Some notes on nonstationary multistep iteration processes. Acta Mathematica Hungarica
Vol. 64, 1, (1994), 59-64. 

147. Stirling's method in generalized Banach spaces. Annales Univ. Sci. Budapest. Sect.  Comp.
15, (1994), 1-15. 

148. Improved a posteriori error bounds for Zincenko's iteration, Intern. J. Comp. Math., Vol.
51, (1994), 51-54. 

149. The Jarrat method in a Banach space setting. J. Comp. Appl. Math. 51, (1994), 103-106. 

150. The midpoint method in Banach spaces and Ptak-error estimates, Appl. Math. and
Computation, 62, 1(1994), 1-16. 

151. A convergence theorem for Newton-like methods under generalized Chen- Yamamoto-type
assumptions, Appl. Math. and Comput. 61, 1, (1994). 

152. On the convergence of some projection methods and inexact Newton-like iterations, Tamkang
J. Math. Vol. 25, No. 4, (1994), 335-341. 

153. On Newton's method and nonlinear operator equations, P.U.J.M. Vol 27, (1994). 

154. On the midpoint iterative method for solving nonlinear operator equations and
applications to the solution of integral equations, University of Arkansas, Research Report,
Vol A-R-21, Mathematica-Revue D'analyse Numerique et de Theorie de l'approximation, Tome 23,
fasc. 2, (1994), 139-152. 

155. Parameter based algorithms for approximating local solutions of nonlinear complex
equations, Proyecciones Vol. 13, No. 1, (1994), 53-61. 

156. The Halley-Werner method in Banach spaces, Mathematica-Revue D'analyse Numerique et de
Theorie de l'approximation, Tome 23, fasc. 2, (1994), 1-14. 

157. On a multistep Newton method in Banach spaces and the Ptak error estimates, Proceeding of
the Tenth Annual conference on Applied Mathematics, CAM 94, University of Central Oklahoma,
Edmond, (1994), 1-15. 

158. Error bound representations of Chebysheff-Halley-type methods in Banach spaces, Rev.
Academia de Ciencias Zaragoza 49, (1994), 57-69. 

159. On the monotone convergence of fast iterative methods in partially ordered topological
spaces, Proceedings of the Tenth Annual Conference on Applied Mathematics, CAM 94, University
of Central Oklahoma, Edmond, (1994), 16-19. 

160. On the discretization of Newton-like methods, Internat. J. Computer. Math. Vol. 52,
(1994), 161-170. 

161. A local convergence theorem for the super-Halley method in a Banach space, Appl.  Math.
Lett. Vol. 7, No. 5, (1994), 49-52. 

162. A convergence analysis for a rational method with a parameter in Banach space, Pure
Mathematics and Applications 5, 1, (1994), 59-73. 

163. On sufficient conditions of the convergence and an optimality of the error estimate for a
high speed iterative algorithm for solving nonlinear algebraic systems, Chinese J. Math.  Vol.
22, No. 4, (1994), 373-384. 

164. On the convergence of modified contractions, Journ. Comput. Appl. Math., 55, (1994),
183-189. 

165. A multipoint Jarratt-Newton-type approximation algorithm for solving nonlinear operator
equations in Banach spaces, Functiones et Aproximatio Commentarii Matematiki, XXIII, (1994),
97-108. 

166. Convergence results for the super-Halley method using divided differences, Functiones et
Approximatio Commentari Mathematici, XXIII, (1994), 109-122. 

167. On the aposteriori error estimates for Stirling's method. Studia Scientiarum
Mathematicarum Hungarica 30, (1995), 205-216. 

168. Sufficient conditions for the convergence of Newton-like methods under weak smoothness
assumptions, Mathematics, CAM 95, Edmond, OK (1995), Proceeding of the eleventh conference on
computational and applied mathematics, (1995), 1-13. 

169. On Stirling's method, Tamkang J. Math. Vol 27, No. 1, (1995). 

170. Stirling's method and fixed points of nonlinear operator equations in Banach space,
Bulletin of the Institute of Mathematics Academia Sinica, Vol. 23, No. 1, (1995), 13-20. 

171. Error bounds for fast two-point Newton methods of order four, Mathematics, CAM 95,
Edmond, OK (1995), Proceedings of the Eleventh Annual Conference on Computational and Applied
Mathematics, (1995), 14-18. 

172. Improved error bounds for fast two-point Newton methods of order three, Mathematics, CAM
95, Edmond, OK (1995), Proceedings of the Eleventh Annual Conference on Computational and
Applied Mathematics, (1995), 19-23. 

173. A unified approach for constructing fast two-step Newton-like methods, Monatshefte fur
Mathematik. 119, (1995), 1-22. 

174. Results on Newton methods; Part I:  A unified approach for constructing perturbed
Newton-like methods in Banach space and their applications. Appl. Math. and Comp., (1995). 

175. Results on Newton methods, Part II:  Perturbed Newton-like methods in generalized Banach
spaces, Appl. Math. and Comp., (1995). 

176. An inverse-free Jarratt type approximation in a Banach space. Journal of Approximation
theory and its Applications, 11, (1995). 

177. An error Analysis for the secant method under generalized Zabrejko-Nguen-type
assumptions, Arabian Journal of Science and Engineering 20:1, (1995), 197-206. 

178. Optimal-order parameter identification in solving nonlinear systems in a Banach space.
Journal of Computational Mathematics, 13, 2, (1995). 

179. Nondifferentiable operator equations on Banach spaces with a convergence structure, Pure
Mathematics and Applications, (PUMA), Vol. 6, 1, (1995). 

180. Perturbed Newton-like methods and nondifferentiable operator equations on Banach spaces
with a convergence structure, Southwest Journal of Pure and Applied Mathematics, Vol.  1,
(1995), 1-12. 

181. Results on controlling the residuals of perturbed Newton-like methods on Banach spaces
with a convergence structure. (SWJPAM) Southwest Journal of Pure and Applied Mathematics, Vol.
1 (1995), 32-38. 

182. On an application of a variant of the closed graph theorem to the solution of nonlinear
equations, Pure Mathematics and Applications, (PUMA). 

183. On the method of tangent hyperbolas, Journal of Approximation Theory and its
Applications. 

184. On the convergence of two-step methods generated by point-to-point operators, Appl. Math.
and Comput. 


Submitted for Publication

185. A unified approach for constructing fast two-step methods in Banach space and their
applications. 

186. Convergence theorems for Newton-like methods under generalized Newton- Kantorovich
conditions. 

187. A simplified proof concerning the convergence and error bound for a rational cubic method
in Banach spaces and applications to nonlinear integral equations. 

188. The Chebyshev method in Banach spaces and the Ptak error estimates. 
 
189. The Halley method in Banach spaces and the Ptak error estimates. 

190. The Halley-Werner method in Banach spaces and the Ptak error estimates. 

191. Error bounds for the midpoint method in Banach spaces.

192. Error bounds for the Chebyshev method in Banach spaces.

193. Error bounds for the Halley method in Banach spaces.

194. Error bounds for the Halley-Werner method in Banach spaces.

195. Improved error bounds for Newton-like iterations under Chen-Yamamoto assumptions. 

196. An error analysis for Steffensen's method.

197. On the Secant method and the Ptak error estimates.

198. A convergence theorem for Steffensen's method and the Ptak error estimates.

199. An error analysis for the Steffensen method under generalized Zabrejko-Nguen-type
assumptions. 

200. On the solution of nonlinear equations under Holder continuity assumptions.

201. On the convergence of an Euler-Chebysheff-type method using divided differences of order
one. 

202. On the convergence of a Chebysheff-Halley-type method using divided differences of order
one. 

203. On the monotone convergence of an Euler-Chebysheff-typemethod in partially ordered
topological spaces. 

204. On the monotone convergence of a Chebysheff-Halley-type method in partially ordered
topological spaces. 

205. Improved error bounds for an Euler-Chebysheff-type method. 

206. Improved error bounds for a Chebysheff-Halley-type method.

207. Convergence results for a fast iterative method in linear spaces.

208. Error bounds for an almost fourth order method under generalized conditions.

209. A unified approach for the construction of fast two-step Newton methods.

210. On the approximation of quadratic equations in Banach space using finite rank operators. 

211. On the method of tangent parabolas.

212. A study on the order of convergece of a rational iteration for solving quadratic
equations in a Banach space. 

213. On the super-Halley method using divided differences. 

214. Perturbed Newton methods in generalized Banach spaces. 

215. A mesh independence principle for perturbed Newton-like methods and their
discretizations. 

216. On an extension of the mesh-independence principle for operator equations in Banach
space. 

217. Results involving nondifferentiable equations on Banach spaces with a convergence
structure and Newton methods. 

218. Inexact Newton methods and nondifferenctiable operator equations on Banach spaces with a
convergence structure. 

219. A mesh independence principle for inexact Newton-like methods and their discretizations
under generalized Lipschitz conditions. 

220. Generalized conditions for the convergence of inexact Newton methods on Banach spaces
with a convergence structure and applications. 

221. Generalized conditions for the convergence of inexact Newton-like methods on Banach
spaces with a convergence structure and applications. 

222. On a new Newton-Mysovskii-type theorem and applications. Part I: Inexact Newton- like
methods and their discretizations. 

223. On a new Newton-Mysovskii-type theorem and applications. Part II: The asymptotic mesh
independence principle for inexact Newton-Galerkin-like methods. 

224. Approximating solutions of operator equations using modified contractions and
applications. 

225. A unified approach for solving nonlinear operator equations and applications. 

    (M).  BOOKS

1. The Theory and Applications of Iteration Methods.  ISBN 0-8493-8014-6, CRC Press, Inc. Boca
Raton, Florida, U.S.A. (1993). 

This textbook was written for students in engineering, the physical sciences, mathematics, and
economics as an upper undergraduate or graduate level.  Prerequisits for using the text are
calculus, linear algebra, elements of functional analysis, and the fundamentals in
differential equations.  Students with some knowledge of the principles of numerical analysis
and optimization will have an advantage, since the general schemes and concepts can be easily
followed if particular methods, special cases are already known.  However such knowledge is
not essential in understanding the material of this book. 

A large number of problems in applied mathematics and also in engineering are solved by
finding the solutions of certain equations.  For example, dynamic systems are mathematically
modelled by difference or differential equations, and their solutions represent usually the
states of the systems.  For the sake of simplicity assume that a time-invariant system is
driven by the equation x = f(x), where x is the state, then the equilibrium states are
determined by solving the equation f(x) = 0.  Similar equations are used in the case of
discrete systems.  The unknowns of engineering equations can be functions (difference,
differential, integral equations), vectors (system of linear or nonlinear algebraic
equations), or real or complex numbers (single algebraic equations with single unknowns). 
Except special cases the most commonly used solution methods are iterative, when starting from
one or several initial approximations a sequence is constructed, which converges to a solution
of the equation.  Iteration methods are applied also for solving optimization problems.  In
such cases the iteration sequences converge to an optimal solution of the problem in hand. 
Since all of these methods have the same recursive structure, they can be introduced and
discussed in a general framework. 

In recent years, the study of general iteration schemes has included a substantial effort to
identify properties of iteration schemes that will guarantee their convergence in some sense. 
A number of these results have used an abstract iteration scheme that consists of the
recursive application of a point-to-set mapping.  In this book we are concerned with this type
of results. 

Each Chapter contains several new theoretical results and important applications in
engineering, in dynamic economic systems, in input-output systems, in the solution of
nonlinear and differential equation, and optimization problems. 

Chapter 1 gives an outline of general iteration schemes, in which the convergence ofsuch
schemes is examined.  We also show that our conditions are very general:  most classical
results can be obtained as special cases, and if the conditions are weakened slightly then our
results may not hold.  In Chapter 2 the discrete time-scale Liapunov theory is extended to
time dependent, higher order, nonlinear difference equations.  In addition, the speed of
convergence is estimated in most cases.  The monotone convergence to the solution is examined
in Chapter 3 and comparison theorems are proven in Chapter 4.  It is also shown that our
results generalize well-known classical theorems such as the contraction mapping principle,
the lemma of Kantorovich, the famous Gronwall lemma, and the well known stability theorem of
Uzawa.  Chapter 5 examines conditions for the convergence of special single-step methods such
as Newton's method, modified Newton's method, and Newton-like methods generated by point-to-
point mappings in a Banach space setting.  The speed of convergence of such sequences is
examined using the theory of majorants and a method called "continuous induction", which
builds on a special variant of Banach's closed graph theorem.  Finally, Chapter 6 examines
conditions for monotone convergence of special single-step methods such as Newton's method,
Newton-like methods, and secant methods generated by point-to-point mappings in a partially
ordered space setting. 

At the end of each chapter case studies and numerical examples are presented from different
fields of engineering, and economy. 

2. Approximate solutions of nonlinear operator equations in abstract spaces and applications
(to appear). 

3. The solution of polynomial operator equations in abstract spaces and applications (to
appear). 

    (N)  EDITING

I am the Editor in Chief of the Southwest Journal of Pure and Applied Mathematics or "SWJPAM"
for short.  This is a purely electronic Journal established in 1995. 

    (O)  OTHER

The following professors have requested papers:

	1.	Etzio Venturino, Univer. Iowa, (Dept. Math.), U.S.A.
	2.	A.G. Kartsatos, Univer. South Florida, (Dept. Math.), U.S.A.
	3.	H. Jarchow, Institute fur Angewandte Mathematik der Universitat Zurich Ch-8001 
		Zurich, Switzerland.
	4.	M.S. Khan, King Abdulaziz Univer., (Dept. Math.), Saudi Arabia.
	5.	Manfred Knebusch, Universitat Regensburg Fakultat fur Mathematik 8400 
		Regensburg Universitatsstrabe 31, W. Germany.
	6.	Ernest J. Eckert. College of environmental sciences, The University of Wisconsin-
		Green Bay, 2420 Nicolet Dr., Green Bay, WI 54302, U.S.A.
	7.	Josef Danes, Mathematical Institute Charles University Sokolovska 83 18600 
		Prague 8-Karlin, Chechoslovakia.
	8.	Goral Reddy, Dept. Math. Univ. ST. Andrews, Scotland.
	9.	Jerzy Popenda, Dept. Math. T. Univ. Poznan, Poland.
	10.	Vlastimil Ptak, Chechoslovak Academy of Science, Praha, Chechoslovakia.
	11.	Alejandro Figueroa, Universidad de Magallanes, Punta Arenas-Chile.
	12.	Dragan Jucic, Osijek, Yugoslavia.
	13.	Ahmad B. Casdam, Multan, Pakistan.
	14.	Luis Saste Habana, Cuba.
	15.	S.N. Mishra, Lesotho, Africa.
	16.	Josef Kral, Prague, Chechoslovakia.
	17.	Juan J. Nieto, Santiago, Spain.
	18.	S.D. Chatterji, Lausanne, Switzerland.
	19.	Peter Madhe, Berlin, Germany.
	20.	Ioan Muntean, Cluj, Romania.
	21.	S.L. Singh, Xardwar, India.
	22.	P.D.N. Sriniras, India.
	23.	S. Grzegorskii, Lublin, Poland.
	24.	Toma's Arechaga, Aires, Argentina.
	25.	J.D. Deader, Salt Lake, Utah, U.S.A.
	26.	P. Drouet, Rhone, France.
	27.	J. Weber, The University of Wisconsin, Milwakee, U.S.A.
	28.	David C. Kurtz, Rollins College, U.S.A.
	29.	Jorge L. Quiroz, Colima Mexico.
	30.	Ming - Po Chen, Taiwan, Republic of China.
	31.	Mustafa Telci, Begtepe, Ankara Turkey.
	32.	Helmut Dietrich, Merseburg, Germany.
	33.	Dong Chen, Fayeteville, Arkansas, U.S.A.
	34.	Mohammad Tabatabai, Cameron University, OK, U.S.A.  
	35.	M.S. Khan, Sultan Quboos University, Muscat, Sultanate of Oman.     
	36.	Laszlo Mate, Technical University, Budapest, Hungary.  
	37.	Pathak, H.K., Bhilai Nayar, INDIA.
	38.	Osvaldo, Pino Garcia, Habanna, Cuba.
	39.	B.K. Sharma, Ravishankor University, Raipur, India.
	40.	Aied Al-Knazi King Abdul Aziz Univ., Jeddah, Saudi Arabia.
	41.	Hassan-Qasin King Abdul Aziz Univ., Jeddah, Saudi Arabia.
	42.	Tadeusz Jankowski, Univ. Gdansk, Gdansk ,Poland. 
	43.	K. Kurzak, University Teachers College, Dept. Chemistry, Siedlce, Poland.
	44.	R.  Gonzalez, 2000 Rosario, Argentina.
	45.	Emad Fatemi, Ecole Polytechnique Federale de Lqusanne, Switzerland.
	46.	Prasad Balusu, Univ. Rochester, MI, U.S.A.
	47.	Dieter Schott, Rostolki, Germany.
	48.	J.M. Martinez, IMECC-UNICAMP, Brasil.
	49.	Prasad Balusu, India.
	50.	Qun-sheng Zhou, P.R. China.	
	51.	W. Kliesch, Universitat Leipzig, Germany.
	52.	Adriana Kindybalyuk, Ukrain Academy of Sciences, Kiev, Ukraine.
	53.	Roman Brovsek, Ljubljana Slovenia.
	54.	D. Mathieu, L.M.R.E., France.
	55.	Donald Schaffner, Rutger University, N.J., U.S.A.
	56.	David Ward, Barron Associates, Charlottesville, VA, U.S.A.
	57.	Eugene Parker, Batton Associates, Charlottesville, VA, U.S.A.
	58.	Miguel Gomez, Habana Cuba.
	59.	L. Brueggemann, Leipzig-Halle Germany.
	60.	Fidel Delgado, Habana, Cuba.
	61.	B.C. Dhage, Maharashtra, India.
	62.	Leida Perea, Habana, Cuba.
	63.	David Ruch, Sam Houston Univ., Huntsville, Texas.
	64.	Patrick J. Van Fleet, Sam Houston Univ., Huntsville, Texas.
	65.	Tomas Arechaga, BS. Aires, Argentina.
	66.	M.A. Hernandez, Spain.
	67.	J. Illuateau, Romania.
	68.	Ioan A. Rus, Univ.  of Cluj-Napoca, Romania.
	69.	V.K. Jain, Kharagpur, India.
	70.	Alan Lun, University of Melbourne, Victoria Australia.
	71.	A.M. Saddeek, Assiut University of Mathematics, Assiut, A.R. Egypt.

    (P)  AWARDS, HONORS AND AFFILIATIONS

Chairman Applied Mathematics Section Annual Meeting of the American Mathematical and
Mathematical Association of America Meeting, held at San Franscisco, Jan. 1991. 

Book Reviewer "Elementary Numerical Analysis" by Kendall Atkinson, University of Iowa,
Published by Wiley and Sons Inc. Publ. (1992). 

    Scientific Papers Reviewer For

	(a)	Journal of Computational and Applied Mathematics
	(b)	P.U.J.M.
	(c)	Mathematica Slovaca
	(d)	Pure Mathematics and Applications (PUMA)
	(e)	Southwest Journal of Pure and Applied Mathematics

    Author of Three Books   (see)  4(O).

    Journal Editing

	I am the Editor in Chief of the Southwest Journal of Pure and Applied Mathematics or 
	"SWJPAM" for sort. 

    Outstanding Graduation Record  

	I was able to finish both my M.S. and Ph.D. degrees at the University of Georgia at the 
	record time of two years which has not been broken yet.

    International Recognition	

	A total of 69 scientists from five continents have requested reprints of 91% of his
	published work so far. 

	I have been asked to participate in the evaluation process for tenure and promotion by 
	several U.S.A. and international universities.

	Member American Mathematical Society

	Member Mathematical Association of America

	Member Pi Mu Epsilon

	Nominated for the Distinguished Faculty Award for 1993 and 1995, Cameron University

    DEPARTMENTAL SERVICE

	(a)	Member of the graduate studies committee (N.M.S.U.)
	(b)	Member of the graduate faculty (N.M.S.U.)
	(c)	I have been asked and provided input to the members of the departmental personnel 
		committee concerning hiring, updating the math major and other matters.
	(d)	I have been serving as a regular advisor to students and have helped some of 
		them to present papers and give talks at conferences.
	(e)	See also items 3 and 4.

    UNIVERSITY SERVICE

	(a)	I have been participating in the Cameron Interscholastic service.
	(b)	I have been serving some of the Cameron faculty as consultant.
	(c)	Dean's representative (N.M.S.U.).
	(d)	See also items 3 and 4.

    STUDENT SERVICE

	(a) I have been participating in many of our student activities including Mathematics,
	Pi Mu Epsilon and CS Club activities. 

	(b)	See also items 3 and 4.

    COMMUNITY SERVICE

	(a) I have been helping people from Lawton (Fort Sill, Goodyear plan and others) and
	surrounding areas with their mathematical problems. 


A PROGRESS REPORT ON DR. IOANNIS K. ARGYROS

DEPARTMENT OF MATHEMATICAL SCIENCES

Dr. Argyros started graduate studies in 1982 at the University of Georgia, and by 1984 he had
finished both M.Sc and Ph.D. degrees in Mathematics.  His record time for finishing these
graduate degrees has not been broken yet.  His work was based on problems suggested by
Professor S. Chandrasekhar (University of Indiana, Nobel prize of Physics 1983).  Because of
his exceptional results he was asked by Professor Felix Browder (President of the American
Mathematical Society) to give a talk, while still a student at the international conference of
Functional Analysis and Applications held at the University of Berkeley on July 1983. 

Dr. Argyros worked for two years at the University of Iowa and four years at the New Mexico
State University as an assistant professor of Mathematics before coming at Cameron during the
Fall of 1990 as an associate professor of Mathematics.  In 1993 he was granted tenure, and in
1994 he was promoted to the rank of full professor of mathematics. 

Dr. Argyros has produced two Ph.D students and seven M.Sc. students.  He has also helped
several students find a job or pursue a graduate degree at reputable universities.  At the
previous two universities, where he served he was involved in the recruitment of the new
graduate students, preparation of their schedule and their comprehensive examinations as a
member of the graduate committee.  He was also serving as a Dean's representative in the
evaluation of graduate students from other departments.  According to the opinion of the
Departments of Mathematics where he has worked so far his teaching skills rank at the top of
the faculty. 

Dr. Argyros has published more than 200 scientific papers, approximately 7% of which jointly
with professors from our as well as other universities.  Approximately 68% of these papers are
published with the name of Cameron University.  In fact these papers have been published not
only in U.S.A. but at the top refereed journals in 23 countries in four continents. 

A total of 69 scientists from five continents have requested reprints of 91% of his published
work so far.  More than a hundred scientific manuscripts have cited or used his results so
far. 

During the Spring of 1995 he became Editor in Chief of a new reputable electronic journal
entitled Southwest Journal of Pure and Applied Mathematics or SWJPAM. 

He has also been asked from several U.S.A. and international universities to participate in
the evaluation process of several professors for tenure and promotion. 

His expertise are in several areas of applied Mathematics (Numerical-Real Analysis,
Optimization, Differential-Integral equations, Mathematical Physics, Mathematical Economics
and Approximation theory), but he has also published work in pure Mathematics (Functional
Analysis).  His results have applications in Astrophysics (neutron transport, radiative
transfer and kinetic theory of gases), Mechanics (Electromechanical networks), Economics
(dynamic economic systems), to the solution of nonlinear programming problems, and statistics
(evaluation of t-estimators). 

Dr. Argyros has given talks and presented scientific papers at several local and international
converences, in some of which he served as a chairman. 

Dr. Argyros is repeatedly mentioned in several U.S. and International publications and books. 
In fact he reviewed the book entitled "Elementary Numerical Analysis" authored by Professor
Kendall Atkinson and published in November of 1992 (second edition) by Wiley and Sons Inc. 
This book is considered to be the best and most widespread book in the field.  In this book
the author praises Dr. Argyros for his teaching, as well as his research skills, some of which
were incorporated for the further improvement of this book. 

During his career, Dr. Argyros has received several grants from universities and the U.S.A. 
army in order to pursue his teaching and research career.  He is also the reviewer of several
reputable U.S. and International journals.  So far he has reviewed approximately 39 scientific
papers.  In 1993 and 1995 he was nominated for the Distinguished Faculty Award for those
years. 

In 1993 he, jointly with professor Ferenc Szidarovszky from the University of Arizona
published a graduate textbook entitled "The Theory and Applications of Iteration Models" 

(CRC Press Inc. Publishing Company, Boca Raton, Florida) to be used by students in
Mathematics, Physics, Economics, Engineering and the applied sciences.  This book received
excellent reviews from the scientific community before publication.  Here are some quotations
about the book expressed by some of the reviewers: 

	"This is an excellent deep book that was missing from the market",

	"Their treatment is lean and coherent yet remarkably comprehensive.  Their careful 
	explanations are fully supported by numerous examples and illustrations that make the 
	material clear and comprehensible to students". 

During the Fall of 1993 he was contracted to write another graduate textbook entitled
"Approximate Solutions of Nonlinear Operator Equations in Abstract Spaces and Applications" to
be used by students in Mathematics, Physics, Astrophysics, Mechanics, Engineering and the
applied sciences.  This text is approximately 500 pages and will be published in 1996. 

	During 1998, my third graduate book will be published entitled "The Solution of 
Polynomial Operator Equations in Abstract Spaces and Applications".