Pengguna:Dedhert.Jr/Uji halaman 17: Perbedaan antara revisi

Nature and influence of the problems[sunting | sunting sumber]

Hilbert's problems ranged greatly in topic and precision. Some of them, like the 3rd problem, which was the first to be solved, or the 8th problem (the Riemann hypothesis), which still remains unresolved, were presented precisely enough to enable a clear affirmative or negative answer. For other problems, such as the 5th, experts have traditionally agreed on a single interpretation, and a solution to the accepted interpretation has been given, but closely related unsolved problems exist. Some of Hilbert's statements were not precise enough to specify a particular problem, but were suggestive enough that certain problems of contemporary nature seem to apply; for example, most modern number theorists would probably see the 9th problem as referring to the conjectural Langlands correspondence on representations of the absolute Galois group of a number field.^[1] Still other problems, such as the 11th and the 16th, concern what are now flourishing mathematical subdisciplines, like the theories of quadratic forms and real algebraic curves.

There are two problems that are not only unresolved but may in fact be unresolvable by modern standards. The 6th problem concerns the axiomatization of physics, a goal that 20th-century developments seem to render both more remote and less important than in Hilbert's time. Also, the 4th problem concerns the foundations of geometry, in a manner that is now generally judged to be too vague to enable a definitive answer.

The other 21 problems have all received significant attention, and late into the 20th century work on these problems was still considered to be of the greatest importance. Paul Cohen received the Fields Medal in 1966 for his work on the first problem, and the negative solution of the tenth problem in 1970 by Yuri Matiyasevich (completing work by Julia Robinson, Hilary Putnam, and Martin Davis) generated similar acclaim. Aspects of these problems are still of great interest today.

Ignorabimus[sunting | sunting sumber]

Following Gottlob Frege and Bertrand Russell, Hilbert sought to define mathematics logically using the method of formal systems, i.e., finitistic proofs from an agreed-upon set of axioms.^[2] One of the main goals of Hilbert's program was a finitistic proof of the consistency of the axioms of arithmetic: that is his second problem.^[a]

However, Gödel's second incompleteness theorem gives a precise sense in which such a finitistic proof of the consistency of arithmetic is provably impossible. Hilbert lived for 12 years after Kurt Gödel published his theorem, but does not seem to have written any formal response to Gödel's work.^[b][c]

Hilbert's tenth problem does not ask whether there exists an algorithm for deciding the solvability of Diophantine equations, but rather asks for the construction of such an algorithm: "to devise a process according to which it can be determined in a finite number of operations whether the equation is solvable in rational integers." That this problem was solved by showing that there cannot be any such algorithm contradicted Hilbert's philosophy of mathematics.

In discussing his opinion that every mathematical problem should have a solution, Hilbert allows for the possibility that the solution could be a proof that the original problem is impossible.^[d] He stated that the point is to know one way or the other what the solution is, and he believed that we always can know this, that in mathematics there is not any "ignorabimus" (statement whose truth can never be known).^[e] It seems unclear whether he would have regarded the solution of the tenth problem as an instance of ignorabimus: what is proved not to exist is not the integer solution, but (in a certain sense) the ability to discern in a specific way whether a solution exists.

On the other hand, the status of the first and second problems is even more complicated: there is not any clear mathematical consensus as to whether the results of Gödel (in the case of the second problem), or Gödel and Cohen (in the case of the first problem) give definitive negative solutions or not, since these solutions apply to a certain formalization of the problems, which is not necessarily the only possible one.^[f]

The 24th problem[sunting | sunting sumber]

Hilbert originally included 24 problems on his list, but decided against including one of them in the published list. The "24th problem" (in proof theory, on a criterion for simplicity and general methods) was rediscovered in Hilbert's original manuscript notes by German historian Rüdiger Thiele in 2000.^[5]

Sequels[sunting | sunting sumber]

Since 1900, mathematicians and mathematical organizations have announced problem lists, but, with few exceptions, these have not had nearly as much influence nor generated as much work as Hilbert's problems.

One exception consists of three conjectures made by André Weil in the late 1940s (the Weil conjectures). In the fields of algebraic geometry, number theory and the links between the two, the Weil conjectures were very important.^[6][7] The first of these was proved by Bernard Dwork; a completely different proof of the first two, via ℓ-adic cohomology, was given by Alexander Grothendieck. The last and deepest of the Weil conjectures (an analogue of the Riemann hypothesis) was proved by Pierre Deligne. Both Grothendieck and Deligne were awarded the Fields medal. However, the Weil conjectures were, in their scope, more like a single Hilbert problem, and Weil never intended them as a programme for all mathematics. This is somewhat ironic, since arguably Weil was the mathematician of the 1940s and 1950s who best played the Hilbert role, being conversant with nearly all areas of (theoretical) mathematics and having figured importantly in the development of many of them.

Paul Erdős posed hundreds, if not thousands, of mathematical problems, many of them profound. Erdős often offered monetary rewards; the size of the reward depended on the perceived difficulty of the problem.^[8]

The end of the millennium, which was also the centennial of Hilbert's announcement of his problems, provided a natural occasion to propose "a new set of Hilbert problems." Several mathematicians accepted the challenge, notably Fields Medalist Steve Smale, who responded to a request by Vladimir Arnold to propose a list of 18 problems.

At least in the mainstream media, the de facto 21st century analogue of Hilbert's problems is the list of seven Millennium Prize Problems chosen during 2000 by the Clay Mathematics Institute. Unlike the Hilbert problems, where the primary award was the admiration of Hilbert in particular and mathematicians in general, each prize problem includes a million dollar bounty. As with the Hilbert problems, one of the prize problems (the Poincaré conjecture) was solved relatively soon after the problems were announced.

The Riemann hypothesis is noteworthy for its appearance on the list of Hilbert problems, Smale's list, the list of Millennium Prize Problems, and even the Weil conjectures, in its geometric guise. Although it has been attacked by major mathematicians of our day, many experts believe that it will still be part of unsolved problems lists for many centuries. Hilbert himself declared: "If I were to awaken after having slept for a thousand years, my first question would be: Has the Riemann hypothesis been proved?"^[9]

In 2008, DARPA announced its own list of 23 problems that it hoped could lead to major mathematical breakthroughs, "thereby strengthening the scientific and technological capabilities of the DoD."^[10][11][12]

Summary[sunting | sunting sumber]

Of the cleanly formulated Hilbert problems, problems 3, 7, 10, 14, 17, 18, 19, and 20 have a resolution that is accepted by consensus of the mathematical community. On the other hand, problems 1, 2, 5, 6, 9, 11, 15, 21, and 22 have solutions that have partial acceptance, but there exists some controversy as to whether they resolve the problems.

That leaves 8 (the Riemann hypothesis), 12, 13 and 16^[g] unresolved, and 4 and 23 as too vague to ever be described as solved. The withdrawn 24 would also be in this class. Number 6 is deferred as a problem in physics rather than in mathematics.

Table of problems[sunting | sunting sumber]

Tabel berikut memuat 23 masalah Hilbert. Untuk detail solusi dan referensi lebih lanjut, silahkan lihat artikel yang dipranala di kolom pertama.

Masalah	Penjelasan secara singkat	Status	Terpecahkan pada tahun
Masalah ke-1	Hipotesis kontinum, suatu hipotesis yang mengatakan bahwa tidak ada himpunan yang mempunyai kardinalitas antara kardinalitas bilangan bulat dan kardinalitas bilangan real)	2 Masalah ini mustahil untuk dibuktikan atau dibantahkan dalam teori himpunan Zermelo–Fraenkel dengan atau tanpa menggunakan aksioma pemilihan. Teorema himpunan Zermelo–Fraenkel adalah konsisten, dalam artian bahwa teorema ini tidak mengandung kontradiksi. Masih belum ada konsensus apakah ini adalah solusi untuk masalah tersebut.	1940, 1963
Masalah ke-2	Buktikan bahwa aksioma aritmetika adalah konsisten.	2 Belum ada konsensus mengenai apakah hasil Gödel dan Gentzen memberikan solusi untuk masalah yang dinyatakan terpecahkan atau tidak. teorema ketaklengkapan kedua Gödel, yang dibuktikan di tahun 1931, menunjukkan bahwa tiada bukti konsistensinya yang dapat diselesaikan dalam aritmetika itu sendiri. Gentzen membuktikan di tahun 1936 bahwa konsistensi aritmetika yang diikuti dari well-foundedness dari ordinal  ε0.	1931, 1936
Masalah ke-3	Diberikan sebarang dua polihedron yang mempunyai volume yang sama. Apakah polihedron pertama yang dipotong menjadi potongan yang berhingga banyaknya akan selalu dapat disatukan kembali agar menghasilkan polihedron kedua?	1 Terpecahkan. Jawabannya adalah tidak. Ini terbukti menggunakan invarian Dehn.	1900
Masalah ke-4	Konstruksi semua ruang metrik dengan garis-garis adalah geodesik.	4 Belum jelas apakah terselesaikan atau tidak.[h]	—
Masalah ke-5	Are continuous groups automatically differential groups?	2 Resolved by Andrew Gleason, assuming one interpretation of the original statement. If, however, it is understood as an equivalent of the Hilbert–Smith conjecture, it is still unsolved.	1953?
Masalah ke-6	Mathematical treatment of the axioms of physics (a) axiomatic treatment of probability with limit theorems for foundation of statistical physics (b) the rigorous theory of limiting processes "which lead from the atomistic view to the laws of motion of continua"	2 Partially resolved depending on how the original statement is interpreted.[13] Items (a) and (b) were two specific problems given by Hilbert in a later explanation.[14] Kolmogorov's axiomatics (1933) is now accepted as standard. There is some success on the way from the "atomistic view to the laws of motion of continua."[15]	1933–2002?
Masalah ke-7	Apakah ab transenden, untuk bilangan aljabar a ≠ 0,1 dan bilangan irasional aljabar b?	1 Terpecahkan. Jawabannya adalah bisa. Ini dapat diilustrasikan dengan teorema Gelfond atau teorema Gelfond–Schneider.	1934
Masalah ke-8	Hipotesis Riemann ("bagian real dari sebarang akar non-trivial dari fungsi zeta Riemann adalah ${\textstyle {\frac {1}{2}}}$"), dan masalah-masalah lain yang membahas tentang bilangan prima, seperti konjektur Goldbach dan konjektur bilangan prima kembar	3 Belum terpecahkan.	—
Masalah ke-9	Find the most general law of the reciprocity theorem in any algebraic number field.	2 Partially resolved.[i]	—
Masalah ke-10	Carilah algoritma untuk menentukan apakah suatu polinomial persamaan Diophantine yang diberikan dengan koefisien bialngan bulat memiliki penyelesaian berupa bilangan bulat.	1 Terpecahkan. Jawabannya adalah mustahil. Teorema Matiyasevich mengimplikasikan tiada algoritma yang menentukan solusi bilangan bulat pada polinomial persamaan Diophantine.	1970
Masalah ke-11	Solving quadratic forms with algebraic numerical coefficients.	2 Partially resolved.[16]	—
Masalah ke-12	Extend the Kronecker–Weber theorem on Abelian extensions of the rational numbers to any base number field.	2 Partially resolved.[17]	—
Masalah ke-13	Solve 7th degree equation using algebraic (variant: continuous) functions of two parameters.	3 Unresolved. The continuous variant of this problem was solved by Vladimir Arnold in 1957 based on work by Andrei Kolmogorov, but the algebraic variant is unresolved.[j]	—
Masalah ke-14	Is the ring of invariants of an algebraic group acting on a polynomial ring always finitely generated?	1 Resolved. Result: No, a counterexample was constructed by Masayoshi Nagata.	1959
Masalah ke-15	Rigorous foundation of Schubert's enumerative calculus.	2 Partially resolved.[butuh rujukan]	—
Masalah ke-16	Describe relative positions of ovals originating from a real algebraic curve and as limit cycles of a polynomial vector field on the plane.	3 Unresolved, even for algebraic curves of degree 8.	—
Masalah ke-17	Express a nonnegative rational function as quotient of sums of squares.	1 Resolved. Result: Yes, due to Emil Artin. Moreover, an upper limit was established for the number of square terms necessary.	1927
Masalah ke-18	(a) Are there only finitely many essentially different space groups in n-dimensional Euclidean space? (b) Is there a polyhedron that admits only an anisohedral tiling in three dimensions? (c) What is the densest sphere packing?	1 (a) Resolved. Result Yes (by Ludwig Bieberbach) (b) Resolved. Result: Yes (by Karl Reinhardt). (c) Widely believed to be resolved, by computer-assisted proof (by Thomas Callister Hales). Result: Highest density achieved by close packings, each with density approximately 74%, such as face-centered cubic close packing and hexagonal close packing.[k]	1928 (a) 1910 (b) 1928 (c) 1998
Masalah ke-19	Are the solutions of regular problems in the calculus of variations always necessarily analytic?	1 Resolved. Result: Yes, proven by Ennio de Giorgi and, independently and using different methods, by John Forbes Nash.	1957
Masalah ke-20	Do all variational problems with certain boundary conditions have solutions?	1 Resolved. A significant topic of research throughout the 20th century, culminating in solutions for the non-linear case.	?
Masalah ke-21	Proof of the existence of linear differential equations having a prescribed monodromic group	2 Partially resolved. Result: Yes/No/Open depending on more exact formulations of the problem.	?
Masalah ke-22	Uniformization of analytic relations by means of automorphic functions	2 Partially resolved. Uniformization theorem	?
Masalah ke-23	Further development of the calculus of variations	4 Too vague to be stated resolved or not.	—

See also[sunting | sunting sumber]

• Landau's problems
• Millennium Prize Problems

Notes[sunting | sunting sumber]

References[sunting | sunting sumber]

Further reading[sunting | sunting sumber]

External links[sunting | sunting sumber]

Wikisumber memiliki naskah asli yang berkaitan dengan artikel ini:

Mathematical Problems

• Hazewinkel, Michiel, ed. (2001) [1994], "Hilbert problems", Encyclopedia of Mathematics, Springer Science+Business Media B.V. / Kluwer Academic Publishers, ISBN 978-1-55608-010-4 
• "Original text of Hilbert's talk, in German". Diarsipkan dari versi asli tanggal 2012-02-05. Diakses tanggal 2005-02-05.  Parameter |url-status= yang tidak diketahui akan diabaikan (bantuan)
• "David Hilbert's "Mathematical Problems": A lecture delivered before the International Congress of Mathematicians at Paris in 1900" (PDF). 
• Buku audio domain publik Mathematical Problems di LibriVox

Templat:Hilbert's problems