Kooperationsmodelle (OSP)

Another possible allegory for the open-source model is again the academy, which it resembles even more directly than the cathedral. Scientists, too, release their work openly to others for their use, testing, and further development. Their research is based on the idea of an open and self-correcting process. The latter idea of self-correction was emphasized by Robert Merton as an equally important cornerstone of scientific ethic as openness. He called it organized P oi thedea of synusia ofroacPlhiatong 1l the historically, it _ so" mc1üded "the 's Academy, which a truth through critical dialogue.12 The scientific ethic entails a model in which theories are developed collectively and their flaws are perceived and gradually removed by means of criti­cism provided by the entire scientific community Of course, scientists, too, have chosen this model not only for ethical reasons but also because it has proved to be the most successful way of creating scientific knowl­edge. All of our understanding of nature is based on this academic or scientific model. The reason why the original hackers' open-source model works so effectively seems to —in addition to the facts that they are realizing their passions and are motivated by peer recognition, as scien­tists are also—that to a great degree it conforms to the ideal open academic model, which is historically the best adapted for information creation. Broadly speaking, one can say that in the academic model the point of departure also tends to be a problem or goal researchers find personally interesting; they then provide their own Solution (even though in many in-stances the mere statement of the problem or proclama­tion of a program is interesting in itself). The academic ethic demands that anyone may use, criticize, and de­velop this Solution. More important than any final result is the underlying information or chain of arguments that has produced the Solution. (It is not enough to merely publish "E = mc2"—theoretical and empirical justifications are also required.) Nevertheless, the scientific ethic does not involve only rights; it also has the same two fundamental obligations: the sources must always be mentioned (pla­giarism is ethically abhorrent), and the new Solution must not be kept secret but must be published again for the benefit of the scientific community. The fulfillment of these two obligations is not required by law but by the scientific community's internal, powerful moral sanctions. Following this model, normal physics research, for ex-ample, continuously provides new additions ("develop-mental versions") to what has already been achieved, and after testing these refinements the scientific community accepts them as part of its body of knowledge ("stable ver-Much more rarely, there is an entire "paradigm shift," to use the expression that philosopher of science Thomas Kuhn introduced in his book The Structure of Sci­entific Revolutions.14 In the broadest sense, there have been only three long-lived research paradigms in physics: the Aristotelian-Ptolemaic physics, the "classic" Newtonian physics, and the Einsteinian-Heisenbergian physics based on the theory of relativity and quantum mechanics. Seen this way, present theories are versions 3.y.z. (Many physicists already call the version 4, which they believe is imminent, "The Theory of Everything." Computer hack­ers would not anticipate the arrival of version 4.0.0 quite so eagerly.) The opposite of this hacker and academic open model can be called the closed model, which does not just close off information but is also authoritarian. In a business en­terprise built on the monastery model, authority sets the goal and chooses a closed group of people to implement it. After the group has completed its own testing, others have to accept the result as it is. Other uses of it are "unauthorized uses." We can again use our allegory of the monas­tery as an apt metaphor for this" style, which is well summed up by Saint"Basil-the-Greats"monastic rule from the fourth century: "No one is to concern himself with the superior's method of administration."15 The closed model does not allow for initiative or criticism that would enable an activity to become more creative and self-corrective. We have mentioned that hackers oppose hierarchical operation for such ethical reasons as that it easily leads to a culture in which people are humiliated, but they also think that the nonhierarchical manner is the most effec­tive one. From the point of view of a traditionally struc­tured business, this may initially seem quite senseless. How could it ever work? Should not someone draw an or­ganization chart for the Net and Linux developers? It is interesting to note that similar things might be said of sci­ence. How could Einstein ever arrive at his E = mc2 in the chaos of self-organized groups of researchers? Should sci­ence not operate with a clear-cut hierarchy, headed up by a CEO of Science, with a division chief for every disci­pline? Both scientists and hackers have learned from experi­ence that the lack of strong structures is one of the reasons why this model is so powerful. Hackers and scientists can just start to realize their passions and then network with other individuals who share them. This spirit clearly dif­fers from that found not only in business but also in gov­ernment. In governmental agencies, the idea of authority permeates an action even more strongly than it does in companies. For the hackers, the typical governmental way of having endless meetings, forming countless commit-tees, drafting tedious strategy papers, and so on before anything happens is at least as great a pain as doing mar­ket research to justify an idea before you can start to cre­ate. (It also irritates scientists and hackers no end when the university is turned into a governmental bureaucracy or monastery.) But the relative lack of structures does not mean that there are no structures. Despite its apparent tumult, hack­erism does not exist in a state of anarchy any more than science does. Hacker and scientific projects have their relative guiding figures, such as Torvalds, whose task it is to help in determining direction and supporting the cre­ativity of others. In addition, both the academic and hacker models have a special publication structure. Re-search is open to anyone, but in practice contributions in­cluded in reputable scientific publications are selected by a smaller group of referees. Still, this model is designed so as to guarantee that, in the long run, it is the truth that de­termines the referee group rather than the other way around. Like the academic referee group, the hacker net-work's referee group retains its position only as long as its choices correspond to the considered choices of the entire peer community. If the referee group is unable to do this, the community bypasses it and creates new channels. This means that at the bottom the authority status is open to anyone and is based only on achievement—no one can achieve permanent tenure. No one can assume a position in which his or her work could not be reviewed by peers, just as anyone else's creations can be. The Hacker Learning Model It goes without saying that the academy was very influen­tial long before there were computer hackers. For exam­ple, from the nineteenth century onward, every industrial echnology (electricity, telephone, television, etc.) would have been unthinkable without its underpinning of scien­tific theory. The late industrial revolution already marked a transition to a society that relied upon scientific results; the hackers bring about a reminder that, in the informa­tion age, even more important than discrete scientific re­sults is the open academic model that enables the creation of these results. This is a central insight. In fact, it is so important that the second big reason for the pragmatic success of the hacker model seems to be the fact that hackers' learning is modeled the same way as their development of new soft-ware (which can actually be seen as the frontier of their collective learning). Thus, their learning model has the same strengths as the development model. A typical hacker's learning process starts out with set­ting up an interesting problem, working toward a solution by using various sources, then submitting the solution to extensive testing. Learning more about a subject becomes the hacker's passion. Linus Torvalds initially taught him-self programming on a computer he inherited from his grandfather. He set up problems for himself and found out what he needed to know to solve them. Many hackers have learned programming in a similarly informal way, follow­ing their passions. The example of the ability of ten-year-olds to learn very complicated programming issues tells us much about the importance of passion in the learning process, as opposed to the slow going their contem-poraries often find their education in traditional schools to be.16 Later on, the beginnings of Torvalds's operating system arose out of his explorations into the processor of the PC he purchased in 1991. In typical hacker fashion, simple experiments with a program that just tested the features of the processor by writing out either As or Bs gradually ex­panded into a plan for a Net newsgroup-reading program and then on to the ambitious idea of an entire operating system.17 But even though Torvalds is a self-taught pro­grammer in the sense that he acquired his basic knowl­edge without taking a class, he did not learn everything all by himself. For example, in order to familiarize himself with operating systems, he studied the source codes of Tanenbaum's Minix as well as various other information sources provided by the hacker community. From the very beginning, in true hacker fashion, he has never hesitated to ask for help with questions in areas in which he has not yet acquired expertise. A prime strength of the hacker learning model lies in the fact that a hacker's learning teaches others. When a hacker studies the source code of a program, he often de­velops it further, and others can learn from this work. When a hacker checks out information sources main­tained on the Net, he often adds helpful information from his own experience. An ongoing, critical, evolutionary discussion forms around various problems. The reward for participating in this discussion is peer recognition. The hackers' open learning model can be called their "Net Academy." It is a continuously evolving learning en­vironment created by the learners themselves. The learn­ing model adopted by hackers has many advantages. In the hacker world, the teachers or assemblers of informa­tion sources are often those who have just learned some-thing. This is beneficial because often someone just engaged in the study of a subject is better able to teach it to others than the expert who no longer comes to it fresh and has, in a way, already lost his grasp of how novices think. For an expert, empathizing with someone who is just learning something involves levels of simplification that he or she often resists for intellectual reasons. Nor does the expert necessarily find the teaching of basics very satisfying, while a student may find doing such teaching tremendously rewarding, since he or she does not as a rule get to enjoy the position of instructor and is generally not given sufficient opportunity to use his or her talents. The process of teaching also involves by its very nature the comprehensive analysis of subject matter. If one is really able to teach something to others, one must have already made the material very clear to oneself. While preparing the material, one has to consider it care-fully from the point of view of possible further questions and counterarguments. Once again, this hacker model resembles Plato's Aca­decoy, where students were not regarded as targets for knowledge transmission but were referred to as compan-ions in learning (synetheis).18 In the Academy's view, the central task of teaching was to strengthen the learners' ability to pose problems, develop lines of thought, and present criticism. As a result, the teacher was metaphori­cally referred to as a midwife,19 a matchmaker,20 and a master of ceremonies at banquets.21 It was not the teacher's task to inculcate the students with preestab­lished knowledge but to help them give birth to things from their own starting points. In the hacker community, too, the experts understand themselves as learners who can just act as gadflies, mid-wives, and symposiarchs to others, thanks to their deeper knowledge. The Net Academy The ethos of the original a academic and the hacker model—well summed up by Plat'ö's-iäea that "no free per-son should learn anything, like a slave"22—is totally dif­ferent from that of the mastery (scchool), the spirit of which was summed up by $en dict's monastic rule: "It belongeth to the master to speak and to teach; it becometh the disciple to be silent and to listen."23 The irony is that currently the academy tends to model its learning struc­ture on the monastic sender-receiver model. The irony is usually only amplified when the academy starts to build a "virtual university": the result is a computerized monas­tery school. The scientific revolution in the seventeenth century was supposed to mean the abandonment of scholasticism and its replacement with a science continually striving for new knowledge. Nevertheless, the university has pre-served the scholastic teaching model and hierarchy, down to its vocabulary (e.g., a "dean" was originally an office-holder of a monastery). The scientific revolution took place four hundred years ago, but it is not very well re­flected in our universities as a basis for research-based learning. It seems quite strange that we expect scholastic teaching methods to be able to produce modern individu­als capable of independent thought and the creation of new knowledge. The wider significance of the hacker learning model is its healthy reminder to us of the potential in the original idea of seeing the academic development and learning models as identical. We could also use this idea to create a generalized Net Academy, in which all study materials would be free for use, critique, and development by every-one. By improving existing material in new directions, the network would continuously produce better resources for the study of the subjects at hand. Members of the network would be driven by their passions for various subjects and by the peer recognition for their contributions. Logically, the continued expansion and development of this material, as well as the discussion and examination of it, would also have to be the Net Academy's only way to grant study credits; and, true to the spirit, the highest credits should be given for those accomplishments that prove the most valuable to the entire learning community. A hacker-style reading of the material with a view toward criticizing and improving it—that is, toward doing some-thing, motivating oneself, with it—would also be much more conducive to learning than the current tendency to just read material. The Net Academy would follow the hacker model in creating an important continuum from the beginning stu­dent all the way to the foremost researcher in the field. Students would learn by becoming researching learners from the very beginning, by discussing matters with researchers, and later on by studying the research publi­cations of their field directly. In the per­manently Net enrich all other learners. eve learnAlin~ event would per‑ one or in the company of others, the Iearner woürd add something to the shared material. This differs from our present mode of disposable learning, in which every student starts from the begin-ring, passes the same exams isolated from everyone else, and never gets to benefit from the insights of others. Worse, after the exam the examiner basically tosses all those individual insights into the wastebasket. This is as absurd a procedure as would be the decision of each gen­eration of researchers to finally toss all their results away ("I see, E = mc2; so what—toss!") and let the next genera­tion start over.24 It goes without saying that the practical realization of the general Net Academy presents a great challenge. For example, as in the world of hackers and researchers, a guiding structure for the collective creation of learning materials is needed. When material is constantly adapted and expanded in new directions, competing versions are born. This is always the case in the hacker and research fields. Hackers have solved practical problems arising from this by developing so-called concurrent-versioning systems: these enable one to see how competing versions differ from the existing version and from each other. On a more theoretical level, the problem can be solved by the practice of referees. With the help of a concurrent-versioning system, a self-organized group of referees can make decisions between competing versions and combine their ideas if need be. After the hackers' reminder of the full significance of the academic model, it would be odd to continue our cur-rent practice of providing learners mainly with results, without making them learn much more deeply the aca­demic model itself, which is based on a collective process of posing of problems, the questioning of them, and the development of solutions—a process driven by passion and recognition for socially valuable contributions. The core of the academy does not consist of its individual achievements but of the academic model itself. The Social Model Expressing this one possible wider application inherent in the hacker model must not, of course, be understood to say that we should just wait for governments or corpora­tions to execute it. A central point of hackerism is to re-mind us that through the open model great things can be accomplished by individuals' direct cooperation. The only limit is our imagination. For example, the hacker open model could be transformed into a social model—call it the open-resource model—in which someone announces: I have an idea, I can contribute this much to it, please join me! Although this version of the open model would also involve local physical action, the Net would be used as an effective means for joining forces and later disseminating and developing the idea further. For example, I could announce on the Net that I would be willing, once in a while, to help some elderly person take care of things. I can announce that kids can come and play at our house after school. I can say that I would be glad to walk one of the neighborhood dogs on week-days. Perhaps the effectiveness of this model could be strengthened by adding a condition that the helped person commit to helping someone else equally. The Net can be used as a means to organize local resources. Gradually, others will join the realization of great social ideas, and this will generate even greater ideas. There would be a self-feeding effect, as in the computer hacker model. We have seen that the hacker model can bring about great things in cyberspace without governments and cor­porations as mediators. It remains to be seen what great things individuals' direct cooperation will accomplish in our "flesh reality."

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