Software engineering/Rework |
Software engineering is the profession that creates and maintains List of software engineering topics#Applications by applying List of software engineering topics#Technologies and practices from computer science, project management, Engineering, domain knowledge, and other fields.
Software is the set of directions that enables computer hardware to perform useful work. In the last decades of the twentieth century, cost reductions in computer hardware led to software becoming a ubiquitous component of the devices used by industrialized societies.
Software engineering, like traditional engineering disciplines, deals with issues of cost and reliability. Some software applications contain millions of Source lines of code that are expected to perform properly in the face of changing conditions.
As of 2002, the U. S. Bureau of Labor Statistics counts 675,000 computer software engineers holding jobs in the United States, and there are estimated to be about one-and-a-half million practitioners in the European Union, Asia, and elsewhere; these figures are about 60% of the number of practitioners engaged in traditional engineering. List of software engineering topics#Notable pioneers include Barry Boehm, Fred Brooks, C. A. R. Hoare, and David Parnas. There is extensive debate about what SE is, who qualifies as an SE, who sets the standards, etc.
See also List of software engineering topics.
=Terminology=
==Origins==
The term software engineering was used occasionally in the late 1950s and early 1960s. The term software engineering was popularized by the held in Garmisch, Germany and has been in widespread use since.
==Meanings==
The term software engineering is commonly used with a variety of distinct meanings:
Software engineering is practiced by software engineers.
==Debate over who is a software engineer==
Some people believe that Software Development is a more appropriate term than Software Engineering for the process of creating software. People like Pete McBreen (author of Software Craftsmanship ) believe that the term Software Engineering implies levels of rigor and proven processes that are not appropriate for all types of software development.
Some people dispute the notion that the field is mature enough to warrant the title engineering . In each of the last few decades, at least one radical new approach has entered the mainstream of software development (e.g. Structured programming, Object-oriented programming, Agile software development), implying that the field is still changing too rapidly to be considered an engineering discipline. Other people would argue that the supposedly radical new approaches are actually evolutionary rather than revolutionary, the mere introduction of new tools rather than fundamental changes.
There are currently no widely accepted criteria for distinguishing someone who is a software engineer from someone who is not a software engineer. In addition, the industry is in the midst of a complex debate on the licensing of practicing software engineers.
==Levels==
For the localities that do not license software engineers, some hiring classifications are made based on education and experience. Classification levels may include: entry-level, mid-level, and senior.
Typical entry-level software engineers have a bachelor s degree and zero to five years of experience. Typical mid-level software engineers have a bachelor s or master s degree and have five to ten years of experience. Typical senior-level software engineers have an advanced degree and have ten or more years of experience. Note that these are only guidelines that are trends seen in hiring practices and that many exceptions exist.
=Software engineering today=
Software engineering affects economies and societies in many ways.
; Economic : In the U.S., software drove about 1/4 of all Economics during the 1990s (about $90 billion per year), and 1/6 of all productivity growth (efficiency within GDP) during the late 1990s (about $33 billion per year). Software engineering drove $1 trillion of economic and productivity growth over the last decade. Around the world, software drives economic growth in similar ways, though reliable statistics are hard to find.
; Social : Software engineering changes world Society, wherever people use computers. Email, the world-wide web, and instant messaging enable people to interact in new ways. Software lowers the cost and improves the quality of health-care, fire departments, and other important social services.
Successful projects where software engineering methods have been applied include Linux, the space shuttle software, and automatic teller machines.
See also software engineering economics.
==Room for improvement==
In spite of the enormous economic growth and productivity gains enabled by software, persistent complaints about the quality remain.
Deficient software engineering is often blamed for project failures when the blame might more properly be placed with business managers who ignore lessons already learned by Software Engineers.
See also Debates within software engineering and Criticism of software engineering
==Technologies and practices==
What is the best way to make more and better software SEs advocate many different technologies and practices, with much disagreement. This debate has gone on for 60 years and may continue forever. Software engineers use a wide variety of technologies and practices.
Practitioners use a wide variety of technologies: compilers, code repositories, to word processors.
Practitioners use a wide variety of practices to carry out and coordinate their efforts: pair programming, code reviews, daily stand up meetings.
=Education=
People from many different educational backgrounds make important contributions to SE. The fraction of practitioners who earn computer science or software engineering degrees has been slowly rising. Today, about 1/2 of all software engineers earn computer science or software engineering degrees. For comparison, about 3/4 of all traditional engineers earn engineering degrees.
; Software degrees : About half of all practitioners today have computer science academic degrees, which are the most relevant degrees that are widely available. A small, but growing, number of practitioners have software engineering academic degrees. As of 2004, in the U.S., about 2,000 universities offer computer science degrees and about 50 universities offer software engineering degrees. Most SE practitioners will earn computer science degrees for decades to come, though someday this may change.
; Domain degrees : Some practitioners have degrees in application domains, bringing important domain knowledge and experience to projects. In MIS, some practitioners have business degrees. In embedded systems, some practitioners have electrical or computer engineering degrees, because embedded software often requires a detailed understanding of hardware. In medical software, some practitioners have medical informatics, general medical, or biology degrees.
; Other degrees : Some practitioners have mathematics, science, Engineering, or other technical degrees. Some have philosophy, or other non-technical degrees. And, some have no degrees. Note that Barry Boehm earned degrees in mathematics and Edsger Dijkstra earned degrees in physics.
==Graduate==
Graduate computer science degrees have been available from hundreds of universities for several decades.
Graduate software engineering degrees have been available from dozens of universities for a decade or so.
==Undergraduate==
Undergraduate computer science degrees are available from most universities.
In 1996, .
==Secondary==
Programming and coding are being taught to students at an increasingly earlier stage in secondary schools. However, software engineering is not always included in the curriculum. Many have the impression that students are adequately capable of managing projects. Development techniques beyond learning a programming syntax is required .
=Employment=
See also software engineering demographics.
==Roles in industry==
Some organizations have specialists to perform each of these tasks. Other organizations required software engineers to do many or all of them. In large projects, people may specialize in only 1 role. In small projects, people may fill several or all roles at the same time.
Specializations include: in industry (Requirements analysis, Software architecture, Software developer, Software testing, technical support, Project management) and in academia (educators, researchers).
There is considerable debate over the future employment prospects for Software Engineers and other IT Professionals. For example, an online futures market called the [http://www.ideosphere.com/fx-bin/Claimclaim=ITJOBS Future of IT Jobs in America] attempts to answer whether there will be more IT jobs, including software engineers, in 2012 than there were in 2002.
==Employers==
Most software engineers work as employees or contractors. Software engineers work with businesses, government agencies (civilian or military), and non-profit organizations. Some software engineers work for themselves as free agents.
==Certification==
Certification is a contentious issue. Some see it as a tool to improve professional practice. Others point out that very few traditional engineers bother with any form of certification.
The most successful certification programs are oriented toward specific technologies, and are managed by the vendors of these technologies. These certification programs are tailored to the institutions that would employ people who use these technologies.
General certification of software practitioners has struggled. The Association for Computing Machinery had a professional certification program in the early 1980s, which was discontinued due to lack of interest. Today, the IEEE is certifying software professionals, but only about 500 people have passed the exam by March 2005.
=Comparing related fields=
Many fields are closely related to software engineering; here are some key similarities and distinctions. Comparing SE with other fields helps explain what SE is and helps define what SE might or should become. There is considerable debate over which fields SE most resembles (or should most resemble). These complex and inexact comparisons explain why some see software engineering as its own field.
==What is the nature of SE==
Software engineering resembles many different fields in many different ways. The following paragraphs make some simple comparisons.
; Mathematics : Programs have many mathematical properties. For example the correctness and complexity of many algorithms are mathematical concepts that can be rigorously proven. Programs are finite, so in principle, developers could know many things about a program in a rigorous mathematical way. The use of mathematics within software engineering is often called formal methods. However, computability theory shows that not everything useful about a program can be proven. Mathematics works best for small pieces of code and has difficulty scaling up. Edsger Dijkstra has argued that software engineering is a branch of mathematics.
; Science : Programs have many scientific properties that can be measured. For example, the performance and scalability of programs under various workloads can be measured. The effectiveness of caches, bigger processors, faster networks, newer databases are scientific issues. Mathematical equations can sometimes be deduced from the measurements. Scientific approaches work best for system-wide analysis, but often are meaningless when comparing different small fragments of code.
; Engineering : Software Engineering is considered by many to be an Engineering discipline because there are pragmatic approaches and expected characteristics of engineers. Proper analysis, documentation, and commented code are signs of an engineer. David Parnas has argued that software engineering is engineering.
; Manufacturing : Programs are built in as a sequence of steps. By properly defining and carrying out those steps, much like a manufacturing assembly line, advocates hope to improve the productivity of developers and the quality of final programs. This approach inspires the many different processes and methodologies.
; Project Management : Commercial (and many non-commercial) software projects require management. There are budgets and schedules to set. People to hire and lead. Resources (office space, computers) to acquire. All of this fits more appropriately within the purview of management.
; Art : Programs contain many artistic elements, akin to writing or painting. User interfaces should be aesthetically pleasing to users. Code should be aesthetically pleasing to programmers. Many goals of good design are NP-complete or worse (such as minimizing the number of lines of code, minimizing number of variables, etc.), meaning they are not decided objectively by either man or computer, so they must be decided by one s own sense of aesthetics. Even the decision of whether a variable name or class name is clear and simple is an artistic question. Donald Knuth famously argued that programming is an art.
; Performance : The act of writing software requires that developers summon the energy to find the answers they need while they are at the keyboard. Creating software is a performance that resembles what athletes do on the field, and actors and musicians do on stage. Some argue that SEs need inspiration to spark the creation of code. Sometimes a creative spark is needed to create the architecture or develop a piece of code. Others argue that discipline is the key attribute. Pair programming emphasizes this point of view. Both Kent Beck and Watts Humphrey have argued this emphasis.
==Branch of which field==
Is SE (or should SE be) a branch of programming, a branch of computer science, a branch of traditional engineering, or a field that stands on its own There is considerable #Debates over this. This has important implications for professionalism, licensing, and ethics. Licensing is a polarizing issue: some fiercely advocate it while others staunchly oppose it.
; Branch of programming : Programming emphasizes writing code, independent of projects and customers. Software engineering emphasizes writing code in the context of projects and customers by making plans and delivering applications. As a branch of programming, SE would probably have no significant licensing or professionalism issues.
; Branch of computer science : Many believe that software engineering is a part of computer science, because of their close historical connections and their relationship to mathematics. They advocate keeping SE a part of computer science. Both computer science and software engineering care about programs. Computer science emphasizes the theoretical, eternal truths while software engineering emphasizes practical, everyday usefulness. Some argue that computer science is to software engineering as physics and chemistry are to traditional engineering. As a branch of computer science, SE would probably have few licensing or professionalism concerns.
; Branch of engineering : Others advocate making SE a part of traditional engineering. This is especially true for people who want to emulate other elements of engineering, such as licensing. Both engineering and software engineering share many project management problems and solutions. But, they apply different technologies, they use different kinds of processes, and are driven by different economics. As a branch of engineering, SE would probably adopt the engineering model of licensing and professionalism.
; Freestanding field : Recently, software engineering has been finding its own identity and emerging as an important freestanding field. Practitioners are slowly realizing that they form a huge community in their own right. Software engineering may need to create a form of regulation/licensing appropriate to its own circumstances.
The U. S. Bureau of Labor Statistics treats [http://www.bls.gov/oco/ocos267.htm Computer software engineers] as a freestanding field. The general category of [http://www.bls.gov/oco/ocos027.htm engineers] includes computer hardware engineers, but not computer software engineers
See also Comparing software engineering and related fields.
=History=
Software engineering has a long evolving history. Both the tools that are used and the applications that are written have evolved over time. It seems likely that software engineering will continue evolving for many decades to come.
See also History of software engineering.
==60 year time line==
==Future directions for software engineering==
Aspect-oriented programming and agile methods are important emerging SE technologies and practices. The 2005 ICSE had tracks on both of these topics.
; Aspects : Aspect-oriented programming help programmers deal with Ilities by providing tools to add or remove boilerplate code from many areas in the source code. Aspects describe how all objects or functions should behave in particular circumstances. For example, aspect (computer science)s can add Debugging, Data logging, or Lock (software engineering) control into all objects of particular types. Researchers are currently working to understand how to use aspects to design general-purpose code. Related concepts include generative programming and Template (programming).
; Agile : Agile software development guides software development projects that evolve rapidly with changing expectations and competitive markets. The heavy, document-driven Processes (like TickIT, CMM and ISO 9000) are fading in importance. Some people believe that companies and agencies export many of the jobs that can be guided by heavy-weight processes. Related concepts include extreme programming and Lean manufacturing.
The [http://www.softwaresystems.org/future.html Future of Software Engineering] conference (FOSE) held at the ICSE 2000 documented the state of the art of SE in 2000 and listed many problems to be solved over the next decade. The [http://www.dreamsongs.com/Feyerabend/Feyerabend.html Feyerabend project] attempts to discover the future of software engineering by seeking and publishing innovative ideas.
=Conferences, organizations and publications=
==Conferences==
Several academic conferences devoted to software engineering are held every year. There are also many other academic conferences every year devoted to special topics within SE, such as programming languages, requirements, testing, and so on.
; ICSE : The biggest and oldest conference devoted to software engineering is the [http://www.icse-conferences.org/ International Conference on Software Engineering]. This conference meets every year to discuss improvements in research, education, and practice.
; ESEC : The [http://esecfse.cs.helsinki.fi/ European Software Engineering Conference].
; FSE : The [http://www.isr.uci.edu/FSE-12/ Foundations of Software Engineering] conference is held every year, alternating between Europe and North America. It emphasizes theoretical and foundational issues.
; CUSEC : Conferences dedicated to inform undergraduate students like the annual [http://www.cusec.ca Canadian University Software Engineering Conference] are also very promising for the future generation. It is completely organized by undergraduate students and lets different Canadian Universities interested in Software Engineering host the conference each year. Past guests include Kent Beck, Joel Spolsky, Philippe Kruchten, Hal Helms, Craig Larman, as well as university professors and students.
==Organizations==
==Publications==
==External Links==
=Quotes=
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