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Carl Gauss's


Carl Gauss's Fundamental Theorem of Algebra In September 1798, after three years of selfdirected study, the great mathematician Carl Friedrich Gauss, then 21 years old, left Göttingen University without a diploma. He returned to his native city of Brunswick to begin the composition of his Disquisitiones Arithmeticae, and, lacking any prospect of employment, hoped to continue receiving his student stipend. After several months of living on credit, word came from the Duke that the stipend would continue, provided Gauss obtained his doctor of philosophy degree—a task Gauss thought a distraction, and wished to postpone. Nevertheless, he took the opportunity to produce a virtual declaration of independence from the stifling world of deductive mathematics, in the form of a written thesis submitted to the faculty of the University of Helmstedt, on a new proof of the fundamental theorem of algebra. Within months, he was granted his doctorate without even having to appear for oral examination. Describing his intention to his former classmate, Wolfgang Bolyai, Gauss wrote, "The title [fundamental theorem] indicates quite definitely the purpose of the essay; only about a third of the whole, nevertheless, is used for this purpose; the remainder contains chiefly the history and a critique of works on the same subject by other mathematicians (viz. d'Alembert, Bougainville, Euler, de Foncenex, Lagrange, and the encyclopedists ... which latter, however, will probably not be much pleased), besides many and varied comments on the shallowness which is so dominant in our presentday mathematics." In essence, Gauss was defending, and extending, a principle that goes back to Plato, in which only physical action, not arbitrary assumptions, defines our notion of magnitude. Like Plato, Gauss recognized it were insufficient to simply state his discovery, unless it were combined with a polemical attack on the Aristotelean falsehoods that had become so popular among his contemporaries. Looking back on his dissertation 50 years later, Gauss said, "The demonstration is presented using expressions borrowed from the geometry of position; for in this way, the greatest acuity and simplicity is obtained. Fundamentally, the essential content of the entire argument belongs to a higher domain, independent from space [i.e., antiEuclidean—bmd], in which abstract general concepts of magnitudes, are investigated as combinations of magnitudes connected by continuity: a domain, which, at present, is poorly developed, and in which one cannot move without the use of language borrowed from spatial images." It is my intention to provide a summary sketch of the history of this idea, and Gauss' development of it. It can not be exhaustive. Rather it seeks to outline the steps which should form the basis for oral pedagogical dialogues, already under way in various locations.[1] MultiplyExtended MagnitudeA physical concept of magnitude was already fully developed by circles associated with Plato, and expressed most explicitly in the Meno, Theatetus, and Timaeus dialogues. Plato and his circle demonstrated this concept, pedagogically, through the paradoxes that arise when considering the uniqueness of the five regular solids, and the related problems of doubling a line, square, and cube. As Plato emphasized, each species of action generated a different species of magnitude. He denoted such magnitudes by the Greek term dunamais, a term akin to Leibniz' use of the word Kraft, translated into English as "power." That is, a linear magnitude has the "power" to double a line, while only a magnitude of a different species has the "power" to double the square, and a still different species has the "power" to double a cube (see Figures 1a1c). In Bernhard Riemann's language, these magnitudes are called, respectively: simply extended, doubly extended, and triply extended. Plato's circle emphasized that magnitudes of lesser extension lacked the capacity to generate magnitudes of higher extension, creating, conceptually, a succession of "higher powers." Do not think here of the deductive use of the term "dimension." While a perfectly good word, "dimension" in modern usage too often is associated with the Kantian idea of formal Euclidean space, in which space is considered as a combination of three, independent, simply extended dimensions. Think, instead, of "physical extension." A line is produced by a physical action of simple extension. A surface may be bounded by lines, but it is not made from lines; rather, a surface is irreducibly doubly extended. Similarly, a volume may be bounded by surfaces, which in turn are bounded by lines, but, it is irreducibly triply extended. Thus, a unit line, square, or cube, may all be characterized by the number One, but each One, is a species of a different power. Plato's circle also emphasized, that this succession of magnitudes of higher powers, was generated by a succession of different types of action. Specifically, a simply extended magnitude was produced from linear action, doubly extended magnitudes from circular action, and triply extended magnitudes from extended circular action, such as the rotational actions which produce a cone, cylinder, or torus. This is presented, pedagogically, by Plato in the Meno dialogue, with respect to doubly extended magnitudes, and in the Timaeus, with respect to the uniqueness of the five regular solids, and the problem of doubling the cube. Plato's collaborator, Archytus, demonstrated that the magnitude with which a cube is doubled, is not generated by circular action, but from extended circular action, i.e. conic sections (see Figures 2a and 2b). It fell to Apollonius of Perga (262200 B.C.) to present a full exposition of the generation of magnitudes of higher powers, in his work on Conics. His approach was exhaustively to investigate the generation of doubly and triply extended magnitudes, which he distinguished into plane (circle/line) and solid (ellipse, parabola, hyperbola) loci. As Abraham Gotthelf Kästner indicates in his History of Mathematics (1797), the investigation of the relationships among higher powers, gave rise to what became known by the Arabic word algebra; and, from Gottfried Wilhelm Leibniz (16441716) on, as analysis. Here, the relationship of magnitudes of the second power (squares) and the third power (cubes) were investigated in the form of quadratic and cubic algebraic equations, respectively. Meanwhile, equations of higher than the third degree took on a formal significance, but lacked the physical connection which could be seen in quadratics and cubics. Girolamo Cardan (15011576), and later, Leibniz, showed that there was a "hole" in all forms of algebraic equations, as indicated by the appearance of the square roots of negative numbers, as solutions to such equations. Peering into this "hole," Leibniz recognized that algebra could teach nothing about physics, but, that a general physical principle underlay all algebraic equations, of whatever power. Writing in about 1675 to Christiaan Huyghens (16291695) on the square roots of negative numbers, Leibniz added that he had invented a machine which produced exactly the required action of this general physical principle: "It seems that after this instrument, there is almost nothing more to be desired for the use which algebra can or will be able to have in mechanics and in practice. It is believable that this was the aim of the geometry of the ancients (at least that of Apollonius) and the purpose of loci that he had introduced, because he had recognized that a few lines determine instantly, what long calculations in numbers could achieve only after long work capable of discouraging the most firm." While finding the physical action that generated a succession of higher powers, Leibniz left open the question of what physical action produced the square roots of negative numbers. Gauss's Proof of the Fundamental TheoremBy the time Gauss left Göttingen, he had already developed a concept of the physical reality of the square roots of negative numbers, which he called, complex numbers. Adopting the method of Plato's cave metaphor, from The Republic, Gauss understood his complex numbers to be shadows reflecting a complex of physical actions (action acting on action). This complex action reflected a power greater than the triply extended action that characterizes the manifold of visible space. It was Gauss' unique contribution, to devise a metaphor, from which to represent these higher forms of physical action, so those actions could be represented, by their reflections, in the visible domain. In his 1799 dissertation, Gauss brilliantly chose to develop his metaphor, polemically, on the most vulnerable flank of his opponents' algebraic equations. Like Leibniz, Gauss rejected the deductive approach of investigating algebraic equations on their own terms, insisting that it was physical action that determined the characteristics of the equations. A simple example will help illustrate the point. Think of the physical meaning of the equation x^{2}=4. Obviously, x refers to a side of a square whose area is 4. Thus, 2 is a solution to this equation. Now, think of the physical meaning of the equation x^{2}=4. From a formal deductive standpoint, this equation refers to the side of a square whose area is  4. But, how can a square have an area of 4? Formally, the second equation can be solved by introducing the number 2 [[square root of]] 1, or 2i, which when squared, equals  4. But, the question remains, what is the physical meaning of [[square root of]]  1? One answer is to say that [[square root of]]  1 has no physical meaning, and thus the equation x^{2}=4 has no solution. To this, Euler and Lagrange added the sophistry, richly ridiculed by Gauss in his dissertation, that the equation x^{2}=4 has a solution, but the solution is impossible! Gauss demonstrated the physical meaning of the [[square root of]] 1, not in the visible domain of squares, but in the cognitive domain, of the principle of squaring. This can be illustrated pedagogically, by drawing a square whose area we'll call 1. Then draw the diagonal of that square, and draw a new square using that diagonal as a side. The area of the new square will be 2. Now, repeat this action, again to generate a square whose area is 4 (Figure 3). What is the principle of squaring so illustrated? The action that generated the magnitude which produced the square whose area is 2, was a rotation of 45° and an extension of length from 1 to the [[square root of]] 2. To produce the square whose area is 4, that rotation of 45 degrees was doubled to 90°, and the extension was squared to become 2. Repeat this process several times, to illustrate that the principle of squaring, can be thought of as the combined physical action, of doubling a rotation and squaring the length. The square root is simply the reverse action. That is, halving the angle of rotation and decreasing the length by the square root. Now draw a circle and a diameter, and apply this physical action of squaring to every point on the circle. That is, take every point on the circumference of the circle. Draw the radius connecting that point to the center of the circle. That radius makes an angle with the diameter you drew. To "square" that point, double the angle between the radius and the diameter, and square the length. Repeat this action with several points. Soon you will be able to see that the points on the first circle all map to points on another concentric circle, whose radius is the square of the original circle. But, it gets curiouser and curiouser. Since you doubled the angle each time you squared a point, the original circle will map to the "squared" circle twice (Figure 4)! There is a physical example that illustrates this process. Take a bar magnet and rotate a compass around the magnet. As the compass moves from the North to the South pole of the magnet (180°), the compass needle will make one complete revolution (360°). As it moves from the South pole back to the North, the needle will make another complete revolution. In effect, the bar magnet "squares" the compass (Figure 5)! Gauss associated his complex numbers with this type of compound physical action (rotation combined with extension). He made them visible, metaphorically, as spiral action projected onto a surface. Every point on that surface represents a complex number. Each number denotes a unique combination of rotation and extension. The point of origin of the action ultimately refers to a physical singularity, such as the lowest point of the catenary, or the poles of the rotating Earth, or the center of the bar magnet. In the above example, the original circle becomes a unit circle in the complex domain. The center of the circle is the origin, denoted by 0, the ends of the diameter are denoted by 1 and  1. The square root of  1 is found by halving the rotation between 1 and1, and reducing the radius by the square root. Think carefully, and you will see that [[square root of]]  1 and [[square root of]] 1 are represented by the points on the circumference which are halfway between 1 and 1 (Figure 6). Gauss demonstrated that all algebraic powers, of any degree, when projected onto his complex domain, could be represented by an action similar to that just demonstrated for squaring. For example, the action of cubing a complex number is accomplished by tripling the angle of rotation and cubing the length. This maps the original circle three times onto a circle whose radius is the cube of the original circle. The action associated with the biquadratic power (fourth degree) involves quadrupling the angle of rotation and squaring the square of the length. This will map the original circle four times onto a circle whose radius is increased by the square of the square, and so forth for the all higher powers. Thus, even though the manifolds of action associated with these higher powers exist outside the triply extended manifold of visible space, the characteristic of action which produced them, was brought into view, by Gauss, in his complex domain. Email your questions to schiller@schillerinstitute.org 



Background: The following comments are excerpted from Lyndon H. LaRouche Jr.'s article, Laputa's President Bush" April 18, 2002. ..All of the greatest scientists in the history of modern, globally extended European civilization, such as Gauss and Riemann, relied, to a greater or lesser degree, on those proven methods of what became known during the Nineteenth Century as the Classical Humanist education policies of Friedrich Schiller and Wilhelm von Humboldt and Germany's great scienceorganizer of that century, Alexander von Humboldt. Typical of the longenduring damage which the Romantic influence did to European science, is the case of the wretched hoaxster Claudius Ptolemy, whose Aristotelean fabrications in the matter of astronomy, typified the dark age of the intellect which descended upon Europe from about 212 A.D. until the FifteenthCentury rebirth of Classical knowledge. All of the progress in European science and artistic culture since the end of the Fourteenth Century, have been not only the benefit of a revival of the preRoman Classical tradition, but the founding of the modern form of sovereign nationstate, which began during that century, with the successive monarchies of France's Louis XI and England's Henry VII. 

Education, Science and Poetry Page Dialogues with Lyndon LaRouche in 2002 FIDELIO MAgazine Table of Contents 19972001 FIDELIO Magazine Table of Contents 19911996 [1] This pedagogical exercise is part of an ongoing series on "Riemann for AntiDummies," produced for study by members and friends of the International Caucus of Labor Committees. Some have been published in New Federalist newspaper. See also Bruce Director, "The Division of the Circle and Gauss's Concept of the Complex Domain," 21st Century Science & Technology, Winter 20012002. 

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