223,457 research outputs found
A Novice's Process of Object-Oriented Programming
Exposing students to the process of programming is merely implied but not explicitly addressed in texts on programming which appear to deal with 'program' as a noun rather than as a verb.We present a set of principles and techniques as well as an informal but systematic process of decomposing a programming problem. Two examples are used to demonstrate the application of process and techniques.The process is a carefully down-scaled version of a full and rich software engineering process particularly suited for novices learning object-oriented programming. In using it, we hope to achieve two things: to help novice programmers learn faster and better while at the same time laying the foundation for a more thorough treatment of the aspects of software engineering
\u3ci\u3eTiphia Vernalis\u3c/i\u3e (Hymenoptera: Tiphiidae) Parasitizing Oriental Beetle, \u3ci\u3eAnomala Orientalis\u3c/i\u3e (Coleoptera: Scarabaeidae) in a Nursery
(excerpt)
Tiphia vernalis Rohwer is native to China, Japan, and Korea where it is an external parasite of Popillia spp. (King 1931). It was released into the United States from China and Korea during the mid-1920s through early 30s (Fleming 1968). After it became established in the United States, releases were made from domestic sources beginning in 1931 (King et al. 1951). Tiphia vernalis was released into Ohio sporadically during 1936-1953 (King et al.1951). Tiphia vernalis has been reported parasitizing Popillia spp. (P. quadriguttata (Fabricius) in Korea; P. chinensis (Frivaldsky) and P. formosana (Arrow) in China; and P. japonica Newman in Japan) exclusively in the field (Balock 1934, Fleming 1968). It accepted Anomala (=Exomala) orientalis Waterhouse (oriental beetle) as a host in the laboratory and cocoons were obtained (King et al.1927, Balock 1934), but there are no previously published reports of T. vernalis parasitizing A. orientalis in the field
Computing Optimal Morse Matchings
Morse matchings capture the essential structural information of discrete
Morse functions. We show that computing optimal Morse matchings is NP-hard and
give an integer programming formulation for the problem. Then we present
polyhedral results for the corresponding polytope and report on computational
results
Ligand Binding, Protein Fluctuations, and Allosteric Free Energy
Although the importance of protein dynamics in protein function is generally
recognized, the role of protein fluctuations in allosteric effects scarcely has
been considered. To address this gap, the Kullback-Leibler divergence (Dx)
between protein conformational distributions before and after ligand binding
was proposed as a means of quantifying allosteric effects in proteins. Here,
previous applications of Dx to methods for analysis and simulation of proteins
are first reviewed, and their implications for understanding aspects of protein
function and protein evolution are discussed. Next, equations for Dx suggest
that k_{B}TDx should be interpreted as an allosteric free energy -- the free
energy associated with changing the ligand-free protein conformational
distribution to the ligand-bound conformational distribution. This
interpretation leads to a thermodynamic model of allosteric transitions that
unifies existing perspectives on the relation between ligand binding and
changes in protein conformational distributions. The definition of Dx is used
to explore some interesting mathematical relations among commonly recognized
thermodynamic and biophysical quantities, such as the total free energy change
upon ligand binding, and ligand-binding affinities for individual protein
conformations. These results represent the beginnings of a theoretical
framework for considering the full protein conformational distribution in
modeling allosteric transitions. Early applications of the framework have
produced results with implications both for methods for coarsed-grained
modeling of proteins, and for understanding the relation between ligand binding
and protein dynamics.Comment: 18 pages; 7 figures; Second International Congress of the
Biocomputing and Physics of Complex Systems Research Institute, Zaragoza,
Spain, 8-11 Feb 2006; increase breadth of review of methods for analysis of
allosteric mechanisms; Add AIP in press; fix missing kTs in equation
Set systems without a 3-simplex
A 3-simplex is a collection of four sets A_1,...,A_4 with empty intersection
such that any three of them have nonempty intersection. We show that the
maximum size of a set system on n elements without a 3-simplex is for all , with
equality only achieved by the family of sets either containing a given element
or of size at most 2. This extends a result of Keevash and Mubayi, who showed
the conclusion for n sufficiently large.Comment: 5 page
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