Sirtdagi Riemann aloqasi - Riemannian connection on a surface

Sirtlarning geometriyasiga klassik yondoshish uchun qarang Sirtlarning differentsial geometriyasi.

Yilda matematika, Riman aloqasi a sirt yoki Riemann 2-manifold tomonidan kashf etilgan bir nechta ichki geometrik tuzilmalarni nazarda tutadi Tullio Levi-Civita, Élie Cartan va Hermann Veyl yigirmanchi asrning boshlarida: parallel transport, kovariant hosilasi va ulanish shakli . Ushbu tushunchalar hozirgi shaklida qo'yilgan asosiy to'plamlar faqat 1950-yillarda. XIX asrning klassik yondashuvi sirtlarning differentsial geometriyasi, katta qismi tufayli Karl Fridrix Gauss, klassik nazariyasi uchun tabiiy muhitni ta'minlaydigan ushbu zamonaviy doirada qayta ishlangan harakatlanuvchi ramka shuningdek Riemann geometriyasi yuqori o'lchovli Riemann manifoldlari. Ushbu hisob nazariya uchun kirish sifatida mo'ljallangan ulanishlar.

Tarixiy obzor

Tullio Levi-Civita (1873–1941)

Élie Cartan (1869–1951)

Hermann Veyl (1885–1955)

Gaussning klassik asaridan so'ng sirtlarning differentsial geometriyasi^[1]^[2]^[3]^[4] va keyinchalik kontseptsiyasining paydo bo'lishi Riemann manifoldu tomonidan boshlangan Bernxard Riman o'n to'qqizinchi asr o'rtalarida, ning geometrik tushunchasi ulanish tomonidan ishlab chiqilgan Tullio Levi-Civita, Élie Cartan va Hermann Veyl yigirmanchi asrning boshlarida katta yutuqlarni namoyish etdi differentsial geometriya. Kirish parallel transport, kovariant hosilalari va ulanish shakllari egrilikni tushunishning yanada kontseptual va bir xil usulini berdi, bu esa yuqori o'lchovli manifoldlarga umumlashtirishga imkon berdi; bu endi bitiruv darajasidagi darsliklarda standart yondashuv.^[5]^[6]^[7] Shuningdek, u yangi topologik invariantlarni aniqlash uchun muhim vosita bo'ldi xarakterli sinflar orqali Chern-Vayl gomomorfizmi.^[8]

Garchi Gauss birinchi bo'lib Evklid fazosidagi sirtlarning differentsial geometriyasini o'rgangan bo'lsa ham E³, Rimanning 1854 yildagi Habilitationsschrift-dan keyingina Riman kosmosining tushunchasi paydo bo'ldi. Christoffel o'zining nomli ramzlarini 1869 yilda taqdim etgan. Tensor hisob-kitobi tomonidan ishlab chiqilgan Ricci, bilan muntazam ravishda davolashni nashr etgan Levi-Civita 1901 yilda. Tensorlarning kovariant differentsiatsiyasi tomonidan geometrik talqin berilgan Levi-Civita (1917) sirtlarda parallel transport tushunchasini kim kiritgan. Uning kashfiyoti sabab bo'ldi Veyl va Kartan ulanishning turli xil tushunchalarini, shu jumladan affin aloqasini ham joriy etish. Cartanning yondashuvi zamonaviy paketlarda zamonaviy tilda yangradi Ehresmann, shundan so'ng mavzu tezkorlik bilan hozirgi shaklini oldi Chern, Ambrose va Ashulachi, Kobayashi, Nomizu, Lichnerovich va boshqalar.^[9]

Sirtdagi ulanishlarni turli usullar bilan aniqlash mumkin. The Riemann aloqasi yoki Levi-Civita aloqasi^[10] ko'tarish jihatidan eng oson tushuniladi vektor maydonlari, birinchi buyurtma sifatida qaraladi differentsial operatorlar manifolddagi funktsiyalarga, qismlar bo'yicha differentsial operatorlarga ta'sir ko'rsatadigan ramka to'plami. O'rnatilgan sirt holatida ushbu ko'taruvchi juda ko'p oddiy va ortogonal proektsiya nuqtai nazaridan tavsiflanadi. Darhaqiqat, ramka to'plami bilan bog'langan vektor to'plamlari barcha ahamiyatsiz to'plamlarning pastki to'plamlari bo'lib, ular atrof muhitdagi Evklidlar makoniga tarqaladi; birinchi darajali differentsial operator har doim ahamiyatsiz bo'lmagan to'plamning qismiga, xususan, asl pastki to'plamning qismiga qo'llanilishi mumkin, garchi natijada olingan qism endi pastki to'plamning bo'lagi bo'lmasligi mumkin. Buni ortogonal proektsiyalash orqali tuzatish mumkin.

Riemann aloqasi, ko'mishdan mustaqil ravishda, mavhum ravishda tavsiflanishi mumkin. Geodeziya tenglamalarini Riman aloqasi nuqtai nazaridan yozish oson, ularni Kristofel ramzlari bilan mahalliy darajada ifodalash mumkin. Sirtdagi egri chiziq bo'ylab ulanish a ni aniqlaydi birinchi darajali differentsial tenglama ramka to'plamida. The monodromiya ushbu tenglama aniqlanadi parallel transport ulanish uchun ushbu kontekstda kiritilgan tushuncha Levi-Civita.^[10] Bu ulanishni kollektordagi ko'tarish yo'llari sifatida ramka to'plamidagi yo'llarga tasvirlashning ekvivalenti ko'proq geometrik usulini beradi. Bu frantsuz mualliflari tomonidan ma'qullangan "harakatlanuvchi ramka" klassik nazariyasini rasmiylashtiradi.^[11] Ko'chalarni bir nuqtaga ko'tarish natijasida paydo bo'ladi holonomiya guruhi o'sha paytda. Nuqtadagi Gauss egriligini nuqtada tobora kichkina ko'chadan atrofida parallel tashish natijasida tiklash mumkin. Ekvivalent egrilikni to'g'ridan-to'g'ri cheksiz ravishda hisoblash mumkin Qavslar yolg'on ko'tarilgan vektor maydonlari.

Kartonning yondashuvi, 1-shaklli ulanish yordamida ramka to'plami ning M, Riemann aloqasini tushunishning uchinchi usulini beradi, bu ayniqsa ko'milgan sirt uchun ta'riflash oson. Natijasi tufayli Kobayashi (1956), keyinchalik tomonidan umumlashtirildi Narasimxon va Ramanan (1961), Evklid fazosiga kiritilgan sirtdagi Riemen aloqasi E³ bu Riman aloqasining Gauss xaritasi ostidagi orqaga qaytishdir S².^[12] Identifikatoridan foydalanish S² bilan bir hil bo'shliq SO (3) / SO (2), ulanish 1-shakli faqat ning tarkibiy qismidir Maurer-Cartan 1-shakl SO (3) bo'yicha. Boshqacha qilib aytganda, hamma narsa 2-sohani to'g'ri tushunish uchun kamayadi.^[13]

Kovariant lotin

Torus ustidagi vektor maydoni

Sirt uchun M ichiga o'rnatilgan E³ (yoki umuman olganda yuqori o'lchovli Evklid fazosi), a ning bir nechta teng ta'riflari mavjud vektor maydoni X kuni M:

ning tekis xaritasi M ichiga E³ har bir nuqtada teginish fazosida qiymatlarni olish;
The tezlik vektori a mahalliy oqim kuni M;
birinchi buyurtma differentsial operator har qanday mahalliy jadvalda doimiy muddatsiz M;
a hosil qilish ning C^∞(M).

Oxirgi shart bu topshiriqni anglatadi f ↦ Xf kuni C^∞(M) qoniqtiradi Leybnits qoidasi

{ displaystyle X (fg) = (Xf) g + f (Xg).}

Barchaning maydoni vektor maydonlari ${ displaystyle { mathcal {X}}}$ (M) shakllantiradi modul ustida C^∞(M) ostida yopilgan Yolg'on qavs

{ displaystyle [X, Y] f = X (Yf) -Y (Xf)}

bilan C^∞(M) baholangan ichki mahsulot (X,Y) ni kodlaydigan Riemann metrikasi kuni M.

Beri ${ displaystyle { mathcal {X}}}$ (M) ning submodulidir C^∞(M, E³)=C^∞(M) ${ displaystyle otimes}$ E³, operator X ${ displaystyle otimes}$ Men belgilanadi ${ displaystyle { mathcal {X}}}$ (M) qiymatlarini hisobga olgan holda C^∞(M, E³).

Ruxsat bering P silliq xarita bo'ling M ichiga M₃(R) shu kabi P(p) bo'ladi ortogonal proektsiya ning E³ ga teginuvchi bo'shliqqa p. Shunday qilib birlik normal vektor uchun n_n da p, belgigacha noyob aniqlangan va v yilda E³, proektsiya tomonidan berilgan $P$ (p)(v) = v - (v · n_p) n_p.

Ko'rsatkich bo'yicha ko'paytirish P beradi C^∞(M) ning modul xaritasi C^∞(M, E³) ustiga ${ displaystyle { mathcal {X}}}$ (M). Topshiriq

{ displaystyle nabla _ {X} Y = P ((X otimes I) Y)}

operatorni belgilaydi ${ displaystyle nabla _ {X}}$ kuni ${ displaystyle { mathcal {X}}}$ (M) deb nomlangan kovariant hosilasi, quyidagi xususiyatlarni qondirish

${ displaystyle nabla _ {X}}$ bu C^∞(M) chiziqli X
${ displaystyle nabla _ {X} (fY) = (Xf) Y + f nabla _ {X} Y}$ (Modulni chiqarish uchun Leybnits qoidasi)
${ displaystyle X (Y, Z) = ( nabla _ {X} Y, Z) + (Y, nabla _ {X} Z)}$ (metrikaga muvofiqligi )
${ displaystyle nabla _ {X} Y- nabla _ {Y} X = [X, Y]}$ (simmetriya xususiyati).

Birinchi uchta xususiyat shuni ko'rsatadiki ${ displaystyle nabla}$ bu affine ulanish metrikaga mos keladi, ba'zan uni a deb ham atashadi hermitchi yoki metrik ulanish. Oxirgi simmetriya xususiyati burilish tensori

{ displaystyle T (X, Y) = nabla _ {X} Y- nabla _ {Y} X- [X, Y]}

bir xilda yo'qoladi, shuning uchun affine aloqasi bo'ladi burilishsiz.

Topshiriq ${ displaystyle nabla}$ ushbu to'rt shart bilan o'ziga xos tarzda aniqlanadi va Riemann aloqasi yoki Levi-Civita aloqasi.

Riemen aloqasi Evklid kosmosga joylashtirilishi yordamida aniqlangan bo'lsa-da, bu o'ziga xoslik xususiyati uning aslida ichki invariant yuzaning

To'rt xususiyatning ma'nosini anglatishini ta'kidlab, uning mavjudligini to'g'ridan-to'g'ri umumiy sirt uchun isbotlash mumkin Koszul formulasi

{ displaystyle 2 ( nabla _ {X} Y, Z) = X cdot (Y, Z) + Y cdot (X, Z) -Z cdot (X, Y) + ([X, Y], Z) + ([Z, X], Y) + (X, [Z, Y]),}

Shuning uchun; ... uchun; ... natijasida ${ displaystyle nabla _ {X} Y}$ faqat metrikaga bog'liq va o'ziga xosdir. Boshqa tomondan, agar bu ta'rif sifatida ishlatilsa ${ displaystyle nabla _ {X} Y}$ , yuqoridagi to'rt xususiyat qondirilganligi osonlikcha tekshiriladi.^[14]

Uchun $siz$ ning izometrik joylashtirilishi $M$ yilda E³, teginuvchi vektorlar ${ displaystyle u_ {1} = qisman _ {x}}$ va ${ displaystyle u_ {2} = qisman _ {y} u}$ hosil a ${ displaystyle 2 times 2}$ matritsa ${ displaystyle g_ {ij} = u_ {i} cdot u_ {j}}$ Bu ijobiy-aniq matritsa. Uning teskari tomoni ham matritsali musbat aniq simmetrikdir ${ displaystyle g ^ {ij}}$ . Teskari matritsaga ega noyob musbat aniq kvadrat ildizga ega ${ displaystyle h_ {ij}}$ . Buni tekshirish odatiy holdir ${ displaystyle e_ {i} = sum _ {j} h_ {ij} u_ {j}}$ teginish makonining ortonormal asosini tashkil qiladi. Bunday holda, teginish fazosiga proyeksiya quyidagicha beriladi ${ displaystyle P (p) (v) = sum (v, e_ {i}) e_ {i}}$ Shuning uchun; ... uchun; ... natijasida

{ displaystyle nabla _ { kısalt _ {i}} qisman _ {j} u = P (p) ( qisman _ {i} qisman _ {i} u) = sum _ {k} ( qisman _ {i} qismli _ {j} u, e_ {k}) e_ {k} = sum _ {k, ell, m} ( qismli _ {i} qismli _ {j} u) cdot ( kısalt _ { ell} u) h_ {k ell} h_ {km} qisman _ {m} u = sum _ { ell, m} ( qismli _ {i} qismli _ {j } u) cdot ( qismli _ { ell} u) g ^ { ell m} qisman _ {m} u.}

Shunday qilib ${ displaystyle nabla _ { kısalt _ {i}} qismli _ {j} = sum _ {k} Gamma _ {ij} ^ {k} kısalt _ {k}}$ , qayerda

{ displaystyle Gamma _ {ij} ^ {k} = {1 2} dan ortiq sum _ { ell} g ^ {k ell} chap ( qismli _ {i} ( qismli _ {j} u cdot kısalt _ { ell} u) + qismli _ {j} ( qismli _ {i} u cdot qisman _ { ell} u) - qismli _ { ell} ( qismli _ {i} u cdot kısalt _ {j} u) o'ng.}

Beri ${ displaystyle g_ {ij} = u_ {i} cdot u_ {j}}$ , bu yana bir usulni keltirib chiqaradi Christoffel ramzlari:

{ displaystyle Gamma _ {ij} ^ {k} = {1 2} dan ortiq sum _ { ell} g ^ {k ell} ( qismli _ {i} g_ {j ell} + qisman _ {j} g_ {i ell} - qismli _ { ell} g_ {ij}).}

Kovariant hosilasi uchun formulalar mahalliy koordinatalardan ham olinishi mumkin (x,y) izometrik ko'milishlardan foydalanmasdan. Qabul qilish ${ displaystyle kısalt _ {x}}$ va ' ${ displaystyle kısalt _ {y}}$ vektor maydonlari sifatida, ulanish ${ displaystyle nabla}$ Christoffel belgilaridan foydalanib, faqat metrikada ifodalanishi mumkin:^[15]

{ displaystyle nabla _ { kısalt _ {i}} qismli _ {j} = sum _ {k} Gamma _ {ij} ^ {k} qismli _ {k}.}

Formulani olish uchun Koszul formulasi bilan qo'llanilishi mumkin $X$ , $Y$ va $Z$ ga o'rnatildi ${ displaystyle kısalt _ {i}}$ ning; u holda barcha Yolg'on qavslari qatnaydi.

Egrilik operatori

The Riemann egriligi tensori yordamida kovariant hosilalari bilan aniqlanishi mumkin egrilik operatori:

{ displaystyle R (X, Y) = nabla _ {X} nabla _ {Y} - nabla _ {Y} nabla _ {X} - nabla _ {[X, Y]}.}

Vazifadan beri ${ displaystyle (X, Y, Z) mapsto R (X, Y) Z}$ bu C^∞(M) har bir o'zgaruvchida chiziqli, bundan kelib chiqadi R(x,Y)_p at endomorfizmdir p. Uchun X va Y da chiziqli mustaqil teginuvchi vektorlar $p$ ,

{ displaystyle K = {(R (X, Y) Y, X) over (X, X) (Y, Y) - (X, Y) ^ {2}}}

asosni tanlashga bog'liq emas va Gauss egriligi da $p$ . The Riemann egriligi tensori tomonidan berilgan^[16]^[17]

{ displaystyle R (X, Y, Z, W) = (R (X, Y) Z, W).}

Mustaqilligini tekshirish $K$ oddiy o'zgarishlarni yuborishda o'zgarmasligini ta'kidlash kifoya ( $X$ , $Y$ ) ga ( $Y$ , $X$ ), ( $λ X$ , $Y$ ) va ( $X$ + $Y$ , $Y$ ). Bu o'z navbatida operatorga bog'liq $R (X, Y)$ bu qiyshaygan.^[18] Nishab qo'shilib ketish shunga olib keladi $(R (X, Y) Z, Z)$ = 0 hamma uchun $Z$ , chunki bu quyidagicha

{ displaystyle (R (X, Y) Z, Z) = X ( nabla _ {Y} Z, Z) -Y ( nabla _ {X} Z, Z) - ( nabla _ {[X, Y ]} Z, Z) = {1 2} dan yuqori (XY (Z, Z) -YX (Z, Z) - [X, Y] (Z, Z)) = 0.}

Geodeziya

Agar v(t) bu yo'l M, keyin Eyler tenglamalari uchun v bo'lish a geodezik kabi ixchamroq yozilishi mumkin^[19]

{ displaystyle nabla _ { dot {c}} { dot {c}} = 0.}

Parallel transport

Sferadagi geodeziya uchburchagi atrofida vektorni parallel tashish. Ko'chirilgan vektorning uzunligi va uning har ikki tomoni bilan yasagan burchagi doimiy bo'lib qoladi.

Evklid tekisligidagi egri chiziq va boshlang'ich nuqtadagi vektorni hisobga olgan holda, vektorni harakatlanuvchi vektorning asl va bir xil uzunlikka parallel bo'lishini talab qilish orqali egri chiziq bo'ylab tashish mumkin, ya'ni u egri chiziq bo'ylab doimiy turishi kerak. Agar egri chiziq yopilsa, yana boshlang'ich nuqtaga yetganda vektor o'zgarmaydi. Bu umumiy sirtda mumkin emasligi yaxshi ma'lum, bu soha eng tanish holat. Darhaqiqat, bir vaqtning o'zida bir vaqtning o'zida aniqlash yoki bunday sirtning barcha teginuvchi tekisliklarini "parallellashtirish" mumkin emas: yagona parallel yopiq yuzalar bu gomeomorfik torusga.^[20]

Parallel transportni har doim sirtdagi egri chiziqlar bo'yicha faqat sirtdagi metrikadan foydalanib aniqlash mumkin. Shunday qilib, egri chiziq bo'ylab teginuvchi tekisliklarni ichki geometriya yordamida aniqlash mumkin, hattoki sirtning o'zi ham parallel bo'lmaydi.

Geodeziya bo'ylab parallel transportni, sirtning "to'g'ri chiziqlarini" aniqlash oson. Tegens tekislikdagi vektor geodeziya bo'ylab doimiy uzunlikka ega va geodeziyaning tezlik vektori bilan doimiy burchak hosil qiladigan noyob vektor maydoni sifatida tashiladi.

Umumiy egri chiziq uchun geodezik egrilik egri chiziq geodeziya bo'lishdan qanchalik uzoqlashishini o'lchaydi; u egri chiziq vektorining sirtda aylanish tezligi sifatida aniqlanadi. O'z navbatida geodezik egrilik parallel tashish paytida egri chiziq bo'ylab teguvchi tekislikdagi vektorlarning qanday aylanishini aniqlaydi.

Vektorli maydon v(t) birlik tezligi egri chizig'i bo'ylab v(t), geodezik egrilik bilan k_g(t), deyilgan parallel egri chiziq bo'ylab

u doimiy uzunlikka ega
θ burchagi (t) uni tezlik vektori bilan bajaradi ${ displaystyle { dot {c}} (t)}$ qondiradi

{ displaystyle { dot { theta}} (t) = - k_ {g} (t)}

Bu geodeziya bo'ylab parallel tashish uchun avvalgi qoidani beradi, chunki u holda k_g = 0, shuning uchun angle burchagi (t) doimiy bo'lib qolishi kerak.^[21] Parallel transportning mavjudligi uchun standart mavjudlik teoremalaridan kelib chiqadi oddiy differentsial tenglamalar. Yuqoridagi differentsial tenglamani kovariant hosilasi bo'yicha qayta yozish mumkin

{ displaystyle nabla _ { dot {c}} v = 0}

Ushbu tenglama yana bir marta parallel tashish faqat metrik tuzilishga bog'liqligini, shuning uchun sirtning ichki o'zgarmasligini ko'rsatadi. Parallel transport zudlik bilan qismlarga bo'lingan C ga qadar uzaytirilishi mumkin¹ chiziqlar.

Qachon M ichiga o'rnatilgan sirtdir E³, bu oxirgi shartni proektsiyani qadrlaydigan funktsiya nuqtai nazaridan yozish mumkin P kabi

{ displaystyle P (c (t)) { dot {v}} (t) = 0}

yoki boshqacha aytganda:^[22]

Ning tezlik vektori v yuzaga normal bo'lishi kerak.

Arnold taklif qildi^[23]^[24] chunki geodeziya segmentida parallel transportni ta'riflash oson, ixtiyoriy C da parallel transport¹ egri chiziqli geodezik egri chiziqlarning taxminiy oilasida parallel transport chegarasi sifatida qurilishi mumkin.^[25]

Ushbu tenglama yana bir bor ko'rsatadiki, parallel tashish faqat metrik tuzilishga bog'liq, shuning uchun sirtning ichki o'zgarmasligi; geodezik egrilikni o'z ichiga olgan oddiy differentsial tenglamani yozishning yana bir usuli v. Parallel transport zudlik bilan qismlarga bo'lingan C ga qadar uzaytirilishi mumkin¹ chiziqlar.

Kovariant hosilasini o'z navbatida parallel tashishdan tiklash mumkin.^[26] Aslini olib qaraganda ${ displaystyle nabla _ {X} Y}$ bir nuqtada hisoblash mumkin p, egri chiziq bilan v orqali p teginish bilan X, cheklanishini ko'rish uchun parallel tashish yordamida Y ga v da teginish fazosidagi funktsiya sifatida p va keyin lotinni oladi.

Orthonormal ramka to'plami

Ruxsat bering M ichiga o'rnatilgan sirt bo'ling E³. The yo'nalish sirtda "tashqi tomonga yo'naltirilgan" normal birlik vektorini bildiradi n sirtning har bir nuqtasida aniqlanadi va shu sababli determinantni teginuvchi vektorlarda aniqlash mumkin v va w o'sha paytda:

{ displaystyle mathrm {det} ({ mathbf {v}}, { mathbf {w}}) = ({ mathbf {v}} times { mathbf {w}}) cdot { mathbf { n}},}

odatdagidan foydalanib skalar uchlik mahsulot kuni E³ (o'zi aniqlovchi).

Buyurtma qilingan asos yoki ramka v, w tegang kosmosda deyilgan yo'naltirilgan if det (v, w) ijobiy.

The teginish to'plami ning M juftlardan iborat (p, v) ichida M x E₃ shu kabi v ga teginuvchi tekislikda yotadi M da p.
The ramka to'plami E ning M uchtadan iborat (p, e₁, e₂) bilan e₁, e₂ yo'naltirilgan ortonormal asos teginuvchi tekislikning p.
The doira to'plami ning M juftlardan iborat (p, v) bilan ||v|| = 1. Bu ramka to'plami bilan bir xil, chunki har bir birlik teginish vektori uchun v, noyob teginuvchi vektor mavjud w det bilan (v, w) = 1.

Samolyotda aylanishlar guruhidan beri SO (2) harakat qiladi shunchaki o'tish davri tekislikdagi ortonormal ramkalarda, u ham ramka yoki aylana to'plamlariga ta'sir qiladi M.^[7] Ning ta'riflari teginish to'plami, birlik teginish to'plami va (yo'naltirilgan ortonormal) ramka to'plami E odatiy usulda o'zboshimchalik yuzalariga kengaytirilishi mumkin.^[7]^[16] So'nggi ikkitasi o'rtasida yana shunga o'xshash identifikatsiya mavjud, ular yana asosiy SO (2) to'plamlarga aylanadi. Boshqa so'zlar bilan aytganda:

Kadrlar to'plami a asosiy to'plam bilan tuzilish guruhi SO (2).

Ning tegishli tushunchasi ham mavjud parallel transport ramka to'plamlarini o'rnatishda:^[27]^[28]

Har qanday doimiy ravishda farqlanadigan egri chiziq M ichida egri chiziqqa ko'tarilishi mumkin E shunday qilib, ko'tarilgan egri chiziqning teginuvchi vektor maydoni asl egri chiziqning teginish vektor maydonining ko'tarilishi bo'lsin.

Ushbu ibora egri chiziqdagi har qanday ramkani egri chiziq bo'ylab parallel ravishda ko'chirish mumkinligini anglatadi. Bu aynan "harakatlanuvchi kadrlar" g'oyasi. Har qanday birlik teginish vektori yo'naltirilgan ramkaga noyob tarzda to'ldirilishi mumkinligi sababli, teginuvchi vektorlarning parallel tashilishi ramkalarning parallel tashilishini nazarda tutadi (va unga teng). Geodeziya ko'tarilishi M ichida geodeziya bo'lib chiqadi E Sasaki metrikasi uchun (pastga qarang).^[29] Bundan tashqari, Gauss xaritasi M ichiga S² bog'liq ramka to'plamlari orasidagi tabiiy xaritani keltirib chiqaradi ekvariant SO (2) harakatlari uchun.^[30]

Cartanning ramka to'plamini markaziy ob'ekt sifatida joriy etish g'oyasi nazariyasining tabiiy cho'qqisi edi harakatlanuvchi ramkalar tomonidan Frantsiyada ishlab chiqilgan Darboux va Gursat. Shuningdek, u parallel rivojlanishlarni takrorladi Albert Eynshteyn "s nisbiylik nazariyasi.^[31] Xristofel ramzlari kabi Gauss formulalarida paydo bo'ladigan ob'ektlarga ushbu doirada tabiiy geometrik izoh berilishi mumkin. Intuitivdan farqli o'laroq oddiy to'plam, kabi osongina ingl quvurli mahalla ichki yuzaning E³, ramka to'plami ichki invariant bo'lib, uni joylashtirishdan mustaqil ravishda aniqlash mumkin. Joylashtirilganda, uni Evklid ramka to'plamining pastki to'plami sifatida ham ko'rish mumkin. E³ x SO (3), o'zi a submanifold ning E³ x M.₃(R).

Asosiy aloqa

Bog'lanish nazariyasi Élie Cartan va keyinroq Charlz Ehresmann, atrofida aylanadi:^[32]

asosiy to'plam E;
The tashqi differentsial hisob ning differentsial shakllar kuni E.

Hammasi "tabiiy" vektorli to'plamlar manifold bilan bog'langan Mkabi teginish to'plami, kotangens to'plami yoki tashqi to'plamlar, yordamida ramka to'plamidan qurish mumkin vakillik nazariyasi tuzilish guruhining K = SO (2), a ixcham matritsa guruhi.

Kartanning ulanish ta'rifini vektor maydonlarini ko'tarish usuli sifatida tushunish mumkin M ramka to'plamidagi vektor maydonlariga E tuzilish guruhi harakati ostida o'zgarmas K. Parallel tashish S qismlarini ko'tarish usuli sifatida aniqlanganligi sababli¹ dan yo'llarM ga E, bu avtomatik ravishda vektor maydonlarini yoki teginish vektorlarini ko'tarish usulini cheksiz ravishda keltirib chiqaradi M ga E. Bir nuqtada berilgan teginish vektori bilan yo'lni tanlang va keyin uni ko'tarilgan yo'lning teginuvchi vektoriga solishtiring. (Vektorli maydonlar uchun egri chiziqlarni mahalliy oqimning ajralmas egri chiziqlari sifatida qabul qilish mumkin.) Shu tarzda har qanday vektor maydoni X kuni M vektor maydoniga ko'tarilishi mumkin X* yoqilgan E qoniqarli^[33]

X* - bu vektor maydoni E;
xarita X ↦ X* bu C^∞(M) chiziqli;
X* bu K-variant va vektor maydonini induktsiya qiladi X C da^∞(M) ${ displaystyle subset}$ C^∞(E).

Bu yerda K davriy oqim sifatida ishlaydi E, shuning uchun kanonik generator A uning Lie algebrasi mos keladigan vektor maydoni vazifasini bajaradi vertikal vektor maydoni A*. Yuqoridagi shartlardan kelib chiqadiki, ixtiyoriy nuqtaning tangens fazosida E, ko'targichlar X* ikki o'lchovli subspace-ni o'z ichiga oladi gorizontal vertikal vektorlarga bir-birini to'ldiruvchi pastki bo'shliqni hosil qiladigan vektorlar. Kanonik Riemann metrikasi E Shigeo Sasaki gorizontal va vertikal pastki bo'shliqlarni ortogonal qilib belgilab, har bir pastki makonga o'zining tabiiy ichki mahsulotini beradi.^[29]^[34]

Gorizontal vektor maydonlari quyidagi tavsifni tan oladi:

Har bir K- o'zgarmas gorizontal vektor maydoni E shaklga ega X* noyob vektor maydoni uchun X kuni M.

Ushbu "universal ko'tarish" keyinchalik darhol vektorli to'plamlarga ko'tarilishni keltirib chiqaradi E va shuning uchun kovariant hosilasi va uni umumlashtirish shakllarini tiklashga imkon beradi.

Agar $ Delta $ ning tasviri bo'lsa K cheklangan o'lchovli vektor makonida V, keyin bog'langan vektor to'plami E X_K V ustida M C ga ega^∞(M) bilan aniqlanishi mumkin bo'lgan bo'limlar moduli

{ displaystyle C ^ { infty} (E, V) ^ {K},}

barcha yumshoq funktsiyalarning maydoni ξ:E → V qaysiki K- bu ma'noda ekvariant

{ displaystyle xi (x cdot g) = sigma (g ^ {- 1}) xi (x)}

Barcha uchun x ∈ E va g ∈ K.

SO (2) ning identifikatori R² ning tangens to'plamiga to'g'ri keladi M.

Kovariant hosilasi ${ displaystyle nabla _ {X}}$ o'zgarmas bo'limi on formula bo'yicha aniqlanadi

{ displaystyle nabla _ {X} xi = (X ^ {*} otimes I) xi.}

Kadrlar to'plamidagi ulanish yordamida ham tavsiflanishi mumkin K-invariant differentsial 1-shakllari E.^[7]^[35]

Kadrlar to'plami E a 3-manifold. Bo'sh joy p- shakllar kuni E Λ bilan belgilanadi^p(E).^[36] Bu tuzilish guruhining tabiiy harakatini tan oladi K.

Asosiy to'plamdagi ulanish berilgan E ko'tarishga mos keladi X ↦ X* vektor maydonlari M, noyob narsa bor ulanish shakli ω in

{ displaystyle Lambda ^ {1} (E) ^ {K}}

,

maydoni K-invariant 1-shakllar E, shu kabi^[16]

{ displaystyle omega (X ^ {*}) = 0}

barcha vektor maydonlari uchun X kuni M va

{ displaystyle omega (A ^ {*}) = 1,}

vektor maydoni uchun A* yoqilgan E kanonik generatorga mos keladi A ning ${ displaystyle { mathfrak {k}}}$ .

Aksincha ko'tarish X* quyidagi xususiyatlar bilan ajralib turadi:

X* bu K-variant va induksiya qiladi X kuni M;
ω (X*)=0.

Karton tuzilish tenglamalari

Kadrlar to'plamida E yuzaning M uchta kanonik 1-shakl mavjud:

Ulanish shakli ω, struktura guruhi ostida o'zgarmas K = SO (2)
Ikki tautologik 1-shakl θ₁ va θ₂, identifikatsiyalashning asosiy vektorlariga muvofiq o'zgaruvchan K

Agar π: E ${ displaystyle rightarrow}$ M tabiatning proektsiyasi, 1 shakllari θ₁ va θ₂ tomonidan belgilanadi

{ displaystyle theta _ {i} (Y) = (d pi (Y), e_ {i})}

qayerda Y - bu vektor maydoni E va e₁, e₂ ga teginuvchi vektorlar M ortonormal ramkaning.

Ushbu 1-shakllar quyidagilarni qondiradi strukturaviy tenglamalar, ushbu formulada Cartan uchun:^[37]

{ displaystyle d theta _ {1} = omega wedge theta _ {2}, , , d theta _ {2} = - omega wedge theta _ {1}}

(Birinchi tizimli tenglamalar)

{ displaystyle d omega = - (K circ pi) theta _ {1} wedge theta _ {2}}

(Ikkinchi tizimli tenglama)

qayerda K Gauss egriligi M.

Holonomiya va egrilik

Yuzning Gauss egriligini ko'rsatish uchun ramka to'plamidagi parallel transportdan foydalanish mumkin M kichik egri chiziqlar atrofida vektorlarni tarjima qilish natijasida olingan aylanish miqdorini o'lchaydi M.^[38] Holonomiya tangensli vektor (yoki ortonormal ramka) yopiq egri chiziq atrofida parallel ravishda ko'chirilganda paydo bo'ladigan hodisadir. Loop yopilganda erishilgan vektor asl vektorning aylanishi bo'ladi, ya'ni u SO (2) aylanish guruhining elementiga to'g'ri keladi, boshqacha qilib aytganda burchak moduli 2π. Bu tsiklning yaxlitligi, chunki burchak boshlang'ich vektorni tanlashiga bog'liq emas.

Geometrik talqini Yolg'on qavs ikkitadan vektor maydonlari

Egrilikning bu geometrik talqini o'xshash geometrikaga asoslanadi Yolg'on qavs ikkitadan vektor maydonlari kuni E. Ruxsat bering U₁ va U₂ vektor maydonlari bo'ling E tegishli bilan mahalliy oqimlar a_t va β_t.

Bir nuqtadan boshlang A ga mos keladi x yilda E, sayohat ${ displaystyle { sqrt {s}}}$ uchun integral egri chiziq bo'ylab U₁ nuqtaga B da ${ displaystyle alpha _ { sqrt {s}} (x)}$ .
Sayohat B borish orqali ${ displaystyle { sqrt {s}}}$ uchun integral egri chiziq bo'ylab U₂ nuqtaga C da ${ displaystyle beta _ { sqrt {s}} alpha _ { sqrt {s}} (x)}$ .
Sayohat C borish orqali ${ displaystyle - { sqrt {s}}}$ uchun integral egri chiziq bo'ylab U₁ nuqtaga D. da ${ displaystyle alpha _ {- { sqrt {s}}} beta _ { sqrt {s}} alpha _ { sqrt {s}} (x)}$ .
Sayohat D. borish orqali ${ displaystyle - { sqrt {s}}}$ uchun integral egri chiziq bo'ylab U₂ nuqtaga E da ${ displaystyle beta _ {- { sqrt {s}}} alpha _ {- { sqrt {s}}} beta _ { sqrt {s}} alpha _ { sqrt {s}} ( x)}$ .

Umuman olganda yakuniy nuqta E boshlang'ich nuqtadan farq qiladi A. Sifatida s ${ displaystyle rightarrow}$ 0, yakuniy nuqta E orqali egri chiziqni aniqlaydi A. Yolg'on qavs [U₁,U₂] da x aynan shu egri chiziqning teginuvchi vektori A.^[39]

Ushbu nazariyani qo'llash uchun vektor maydonlarini kiriting U₁, U₂ va V ramka to'plamida E $ mathbb {1} $ uchun ikki tomonlama bo'lgan₁, θ₂ va har bir nuqtada ω. Shunday qilib

{ displaystyle omega (U_ {i}) = 0, , theta _ {i} (V) = 0, , omega (V) = 1, , theta _ {i} (U_ {j) }) = delta _ {ij}.}

Bundan tashqari, V ostida o'zgarmasdir K va U₁, U₂ ning identifikatsiyasiga muvofiq o'zgartirish K.

Cartan-ning strukturaviy tenglamalari quyidagi yolg'on qavs munosabatlarini nazarda tutadi:

{ displaystyle [V, U_ {1}] = U_ {2}, , , , , [V, U_ {2}] = - U_ {1}, , , , , [U_ {1}, U_ {2}] = (K circ pi) V}

Yolg'on qavsining geometrik talqini ushbu tenglamalarning oxirgi qismida qo'llanilishi mumkin. Ω dan beri (U_men) = 0, a oqimlari_t va β_t yilda E o'z proektsiyalarini parallel tashish orqali ko'taruvchilardir M.

Norasmiy g'oya quyidagicha. Boshlanish nuqtasi A va yakuniy nuqta E mohiyatan SO (2) elementi bilan farq qiladi, ya'ni burilish burchagi. Prognoz qilingan yo'l bilan yopilgan maydon M taxminan ${ displaystyle { sqrt {s}} cdot { sqrt {s}} = s}$ . Shunday qilib, chegarada s ${ displaystyle rightarrow}$ 0, bu burchakka bo'lingan burilish burchagi koeffitsientiga intiladi Vya'ni egrilik.

Ushbu fikr quyidagi natijada aniq amalga oshiriladi.^[40]

Ruxsat bering f tekislikdagi ochiq diskning diffeomorfizmi bo'lsin M va Δ bu diskda uchburchak bo'lsin. Keyin pastadir holonomiyasi burchagi ostidagi rasm bilan shakllangan f uchburchak perimetri ostidagi tasvirning Gauss egriligining integrali bilan berilgan f uchburchakning ichki qismi

Belgilarda mod 2π holonomiya burchagi quyidagicha berilgan

{ displaystyle theta = int _ {f ( Delta)} K}

bu erda integral maydon maydoniga nisbatan M.

Bu natija Gauss egriligi orasidagi munosabatni anglatadi, chunki uchburchak kattaligi bir nuqtaga qisqarganda, bu burchakning maydonga nisbati nuqtadagi Gauss egriligiga intiladi. Natijada kombinatsiyasini isbotlash mumkin Stoks teoremasi va Cartanning strukturaviy tenglamalari va o'z navbatida geodeziya uchburchaklaridagi Gauss teoremasini umumiy uchburchaklarga umumlashtirish uchun foydalanish mumkin.^[41]

Kovariant lotin orqali egrilikning boshqa standart yondashuvlaridan biri ${ displaystyle nabla _ {X}}$ , farqni aniqlaydi

{ displaystyle R (X, Y) = nabla _ {X} nabla _ {Y} - nabla _ {Y} nabla _ {X} - nabla _ {[X, Y]}}

tangens to'plamining endomorfizmlari maydoni sifatida Riemann egriligi tensori.^[16]^[42]Beri ${ displaystyle nabla _ {X}}$ ko'tarilgan vektor maydoni tomonidan indüklenir X* yoqilgan E, vektor maydonlaridan foydalanish U_men va V va ularning Yolg'on qavslari ushbu yondashuvga ozmi-ko'pmi tengdir. Vertikal vektor maydoni V=A* kanonik generatorga mos keladi A ning ${ displaystyle { mathfrak {k}}}$ bilan kelishganligi sababli ham qo'shilishi mumkin V va qondiradi [V,U₁] = U₂ va [V,U₂] = —U₁.

Misol: 2-shar

2-sharning differentsial geometriyasiga uch xil nuqtai nazardan qarash mumkin:

analitik geometriya, chunki 2-shar a submanifold ning E³;
guruh nazariyasi, ixcham matritsa guruhidan beri SO (3) uzluksiz simmetriya guruhi sifatida 2-sferada tranzitiv harakat qiladi;
klassik mexanika, chunki qattiq 2 shar samolyotda aylana oladi.

S² birlik shar bilan aniqlanishi mumkin E³

{ displaystyle S ^ {2} = {a in E ^ {3} colon | a | = 1 }.}

Uning shamlardan to'plami T, birlik teginish to'plami U va yo'naltirilgan ortonormal ramka to'plami E tomonidan berilgan

{ displaystyle T = {(a, v) colon | a | = 1, , a cdot v = 0 },}

{ displaystyle U = {(a, v) colon | a | = 1, , | v | = 1, , a cdot v = 0 },}

{ displaystyle E = {(a, e_ {1}, e_ {2}) nuqta (e_ {1} marta e_ {2}) cdot a = 1, , | a | = 1, , | e_ {i} | = 1, , a cdot e_ {i} = 0, , e_ {1} cdot e_ {2} = 0 }.}

Xaritani yuborish (a,v) ga (a, v, a x v) imkon beradi U va E aniqlanishi kerak.

Ruxsat bering

{ displaystyle Q (a) v = (v cdot a) a}

da normal vektorga ortogonal proyeksiya bo'ling a, Shuning uchun; ... uchun; ... natijasida

{ displaystyle P (a) = I-Q (a)}

ning teginish fazosiga ortogonal proyeksiyasidir a.

Guruh G = SO (3) aylantirish orqali harakat qiladi E³ ketish S² o'zgarmas. The stabilizator kichik guruhi K (1,0,0) vektorning in E₃ bilan aniqlanishi mumkin SO (2) va shuning uchun

S² SO (3) / SO (2) bilan aniqlanishi mumkin.

Ushbu harakat amaldagi harakatga qadar davom etadi T, U va E qilish orqali G har bir komponent bo'yicha harakat qilish. G harakat qiladi o'tish davri bilan kuni S² va shunchaki o'tish davri kuni U va E.

SO (3) ning ta'siri E SO (2) ning harakati bilan harakat qiladi E ramkalarni aylantiradigan

{ displaystyle (e_ {1}, e_ {2}) mapsto ( cos theta , e_ {1} - sin theta , e_ {2}, sin theta , e_ {1} + cos theta , e_ {2}).}

Shunday qilib E tuzilish guruhi bilan asosiy to'plamga aylanadi K. Olish G-orbitada nuqta ((1,0,0), (0,1,0), (0,0,1)), bo'sh joy E bilan aniqlanishi mumkin G. Ushbu identifikatsiya ostida G va K kuni E chapga va o'ngga tarjima qilish. Boshqa so'zlar bilan aytganda:

Ning yo'naltirilgan ortonormal ramka to'plami S² SO (3) bilan aniqlanishi mumkin.

The Yolg'on algebra ${ displaystyle { mathfrak {g}}}$ SO (3) hammasidan iborat nosimmetrik haqiqiy 3 x 3 matritsalar.^[43] The qo'shma harakat ning G konjugatsiya orqali ${ displaystyle { mathfrak {g}}}$ ning harakatini takrorlaydi G kuni E³. Guruh SU (2) kompleksdan iborat 3 o'lchovli Lie algebrasiga ega skewermit izsiz Izomorf bo'lgan 2 x 2 matritsalar ${ displaystyle { mathfrak {g}}}$ . SU (2) omillarining uning markazi orqali matritsalari ± qo'shma harakati Men. Ushbu identifikatsiyalar ostida SU (2) a sifatida namoyish etiladi ikki qavatli qopqoq SO (3) ning, shuning uchun SO (3) = SU (2) / ± Men.^[44] Boshqa tomondan, SU (2) 3-sharga diffeomorfdir va shu identifikatsiya ostida 3-sferadagi standart Riemann metrikasi SU (2) bo'yicha mohiyatan noyob biinvariant Riemann metrikasiga aylanadi. Ko'rsatkich bo'yicha ± Men, SO (3) ni bilan aniqlash mumkin haqiqiy proektsion makon 3 o'lchovining o'zi va o'zi noyob binvariant Riemann metrikasiga ega. Ushbu metrik uchun geometrik eksponent xarita Men matritsalardagi odatiy eksponent funktsiyaga va shu bilan geodeziyaga to'g'ri keladi Men exp shakliga ega Xt qayerda X egri-nosimmetrik matritsa. Bu holda Sasaki metrikasi SO (3) bo'yicha bu ikki o'zgaruvchan metrikaga mos keladi.^[45]^[46]

Ning harakatlari G o'zi va shu sababli C^∞(G) chap va o'ng tarjima orqali cheksiz kichik harakatlarni keltirib chiqaradi ${ displaystyle { mathfrak {g}}}$ kuni C^∞(G) vektor maydonlari bo'yicha

{ displaystyle lambda (X) f (g) = {d over dt} f (e ^ {- Xt} g) | _ {t = 0}, , , rho (X) f (g) = {d over dt} f (ge ^ {Xt}) | _ {t = 0}.}

O'ng va chap o'zgarmas vektor maydonlari formulaga bog'liq

{ displaystyle lambda (X) f (g) = - rho (g ^ {- 1} Xg) f (g).}

Vektorli maydonlar λ (X) va r (X) o'ngga va chapga tarjima bilan boring va barcha o'ng va chap o'zgarmas vektor maydonlarini bering G. BeriC^∞(S²) = C^∞(G/K) bilan aniqlanishi mumkin C^∞(G)^K, to'g'ri tarjima ostida o'zgarmas funktsiya K, operatorlar λ (X) shuningdek vektor maydonlarini es (X) ustida S².

Ruxsat bering A, B, C ning standart asosi bo'lishi ${ displaystyle { mathfrak {g}}}$ tomonidan berilgan

{ displaystyle A = { begin {pmatrix} 0 & 1 & 0 - 1 & 0 & 0 0 & 0 & 0 end {pmatrix}}, , , B = { begin {pmatrix} 0 & 0 & 0 0 & 0 & 1 0 & -1 & 0 end { pmatrix}}, , , C = { begin {pmatrix} 0 & 0 & 1 0 & 0 & 0 - 1 & 0 & 0 end {pmatrix}}.}

Ularning Qavslar yolg'on [X,Y] = XY – YX tomonidan berilgan

{ displaystyle [A, B] = C, , , [B, C] = A, , , [C, A] = B.}

Vektorli maydonlar λ (A), λ (B), λ (C) ning har bir nuqtasida teginish fazosining asosini tashkil qiladi G.

Xuddi shunday chap o'zgarmas vektor maydonlari r (A), r (B), r (C) ning har bir nuqtasida teginish fazosining asosini tashkil qiladi G.A, β, γ mos keladigan bo'lsin ikkilamchi asos chap invariant 1-shakllar bo'yicha G.^[47] Yolg'on qavs munosabatlari shuni anglatadi Maurer-Kartan tenglamalari

{ displaystyle d alpha = beta wedge gamma, , , d beta = gamma wedge alfa, , , d gamma = alpha wedge beta.}

Bular ham tegishli komponentlar Maurer-Kartan shakli

{ displaystyle omega _ {G} = g ^ {- 1} dg,}

chap invariant matritsa bo'yicha baholangan 1-shakl G, munosabatni qondiradigan

{ displaystyle d omega _ {G} = - (g ^ {- 1} dg , g ^ {- 1}) dg = - omega _ {G} wedge omega _ {G}.}

Ichki mahsulot yoniq ${ displaystyle { mathfrak {g}}}$ tomonidan belgilanadi

{ displaystyle (X, Y) = mathrm {Tr} , XY ^ {T}}

qo'shma harakat ostida o'zgarmasdir. $ Omega $ tomonidan hosil qilingan pastki bo'shliqqa ortogonal proektsiya bo'lsin A, ya'ni ustiga ${ displaystyle { mathfrak {k}}}$ , ning algebra K. Uchun X yilda ${ displaystyle { mathfrak {g}}}$ , vektor maydonining ko'tarilishi Π (X) C dan^∞(G/K) C ga^∞(G) formula bilan berilgan

{ displaystyle Pi (X) ^ {*} f (g) = - rho ( pi (g ^ {- 1} Xg)) f (g)}

Ushbu ko'tarish G- forma vektor maydonlarida ekvariantX) va umumiy vektor maydonlariga noyob kengaytmaga ega G / K.

Chap invariant 1-shakl a - ulanish shakli ω on G ushbu ko'tarishga mos keladi. Karton tizimli tenglamalaridagi boshqa ikkita 1-shakl θ bilan berilgan₁ = β va θ₂ = γ. Strukturaviy tenglamalarning o'zi faqat Maurer-Kartan tenglamalari. Boshqa so'zlar bilan aytganda;

SO (3) / SO (2) uchun Cartan tizimli tenglamalari SO (3) da chap invariant 1-shakllar uchun Maurer-Cartan tenglamalariga kamayadi.

A bog'lanish shakli bo'lgani uchun,

vertikal vektor maydonlari yoniq G shakldagi narsalar f · Λ (A) bilan f yilda C^∞(G);
gorizontal vektor maydonlari yoniq G shakldagi narsalar f₁ · Λ (B) + f₂ · Λ (C) bilan f_men yilda C^∞(G).

Asosiy vektor maydonlarining mavjudligi λ (A), λ (B), λ (C) SO (3) ning parallel bo'lishini ko'rsatadi. SO (3) / SO (2) uchun bu to'g'ri emas tukli to'p teoremasi: S² yo'qolgan vektor maydonlarini hech qaerda qabul qilmaydi.

Kadrlar to'plamidagi parallel transport SO (3) / SO (2) dan SO (3) gacha bo'lgan yo'lni ko'tarishga teng. Buni matritsali oddiy oddiy differentsial tenglamani ("transport tenglamasi") to'g'ridan-to'g'ri echish orqali amalga oshirish mumkin g_t = A · g qayerda A(t) qiyshiq simmetrik va g SO (3) da qiymatlarni qabul qiladi.^[48]^[49]^[50]

Aslida SO (3) / O (2) dan SO (3) gacha bo'lgan yo'lni ko'tarish teng va qulaydir. E'tibor bering, O (2) SO (3) da SO (2) ning normallashtiruvchisi va O (2) / SO (2) guruhi deb ataladigan Veyl guruhi, SO (3) / SO (2) = ga ta'sir qiluvchi 2-tartibli guruhdir S² sifatida antipodal xarita. SO (3) / O (2) miqdori bu haqiqiy proektsion tekislik. Uni bitta darajadagi yoki ikkita darajadagi proektsiyalar oralig'i bilan aniqlash mumkin Q Mda₃(R). Qabul qilish Q 2-darajali proektsiya va sozlama bo'lish F = 2Q − Men, SO (3) / O (2) sirt modeli bymatrikalar berilgan F qoniqarli F² = Men, F = F^T va Tr F = 1. Qabul qilish F₀= diag (–1,1,1) har bir asosiy nuqta sifatida F shaklida yozilishi mumkin g F₀ g⁻¹.

Yo'l berilgan F(t), oddiy differentsial tenglama ${ displaystyle g_ {t} g ^ {- 1} = F_ {t} F / 2}$ , dastlabki shart bilan ${ displaystyle g (0) = I}$ , noyob C ga ega¹ yechim g(t) qiymatlari bilan G, parallel tashish orqali ko'tarishni berish F.

Agar Q(t) - bu 2-darajali proektsiyalarning mos keladigan yo'li, parallel tashish uchun shartlar

{ displaystyle Q = gQ_ {0} g ^ {- 1}, , , Q_ {0} g ^ {- 1} { nuqta {g}} Q_ {0} = 0}

O'rnatish A = ½F_t F. Beri F² = Men va F nosimmetrik, A nosimmetrik va qoniqtiradiQAQ = 0.

Noyob echim g(t) oddiy differentsial tenglamaning

{ displaystyle { dot {g}} = Ag ,}

dastlabki shart bilan g(0) = Men tomonidan kafolatlangan Pikard-Lindelef teoremasi, bo'lishi shart g^Tg doimiy va shuning uchun Men, beri

{ displaystyle {d over dt} (g ^ {T} g) = { dot {g}} ^ {T} g + g ^ {T} { dot {g}} = g ^ {T} ( A ^ {T} + A) g = 0.}

Bundan tashqari,

{ displaystyle F (t) = g (t) F (0) g (t) ^ {- 1} ,}

beri g⁻¹Fg 0 lotiniga ega:

{ displaystyle {d over dt} (g ^ {- 1} Fg) = - g ^ {- 1} { dot {g}} g ^ {- 1} Fg + g ^ {- 1} { dot {F}} g + g ^ {- 1} F { nuqta {g}} = g ^ {- 1} (- { nuqta {g}} g ^ {- 1} F + { nuqta {F}} + F { nuqta {g}} g ^ {- 1}) g = 0.}

Shuning uchun Q = g Q₀ g⁻¹. Vaziyat QAQ = 0 nazarda tutadi Q g_t g⁻¹ Q = 0 va shuning uchun Q₀ g⁻¹ g_t Q₀ =0.^[51]

Boshqasi bor kinematik parallel siljish va geodezik egrilikni "siljish yoki burishsiz prokatlash" nuqtai nazaridan tushunish usuli. Yigirmanchi asrning boshlaridan boshlab differentsial geometrlarga yaxshi ma'lum bo'lgan bo'lsa-da, u muammolarga nisbatan ham qo'llanilgan muhandislik va robototexnika.^[52] 2-sharni gorizontal tekislikda sirpanmasdan yoki burilmasdan uch o'lchovli kosmosda siljigan qattiq jism sifatida ko'rib chiqing. Aloqa nuqtasi tekislikdagi va sirtdagi egri chiziqni tasvirlaydi. Har bir aloqa nuqtasida gorizontal tekislikning o'zi bilan va shu sababli bir-biri bilan sharning turli teginish tekisliklarini aniqlash mumkin.

Odatdagidek egrilik tekislik egri chizig'i - bu sharda kuzatilgan egri chiziqning geodezik egriligi.
Tegishli tekisliklarning egri chiziq bo'ylab bu identifikatsiyasi parallel transportga to'g'ri keladi.

Sfera uchun buni tasavvur qilish juda oson: aynan shu tarzda marmarni mukammal tekis stol usti bo'ylab ag'darish mumkin.

Muqobil, ammo teng keladigan nuqtai nazarni ta'minlash uchun samolyot va shar rollari o'zgarishi mumkin. Sfera sobit deb qaraladi va tekislik sharning egri chizig'i bo'ylab siljish yoki burilishsiz aylanishi kerak.^[53]

O'rnatilgan yuzalar

Qachonki sirt M ichiga o'rnatilgan E³, Gauss xaritasi M ${ displaystyle rightarrow}$ S² ortonormal ramka to'plamlari orasidagi SO (2) -variantli xaritaga cho'ziladi E ${ displaystyle rightarrow}$ SO (3). Darhaqiqat, tangens ramka va normal vektordan tashkil topgan uchlik SO (3) elementini beradi.

1956 yilda Kobayashi buni isbotladi:^[54]

Kengaytirilgan Gauss xaritasi ostida SO (3) bo'yicha ulanish ulanishni keltirib chiqaradi E.

Demak, ω, ω shakllari₁ va θ₂ kuni E SO (3) dagi narsalarni qaytarib olish yo'li bilan olinadi; va ko'tarish yo'llari M ga E 2-sharga boradigan yo'lni xaritalash, SO (3) ga ko'tarish va keyin ko'taruvchini orqaga tortib bajarish mumkin. E. Shunday qilib, ichki yuzalar uchun ramka to'plamidagi asosiy ulanishga ega bo'lgan 2-soha "universal model" ni taqdim etadi, bu universal to'plamlar uchun prototip Narasimxon va Ramanan (1965).

In more concrete terms this allows parallel transport to be described explicitly using the transport equation. Parallel transport along a curve v(t) bilan t taking values in [0,1], starting from a tangent from a tangent vector v₀ also amounts to finding a map v(t) from [0,1] to R³ shu kabi

v(t) is a tangent vector to M da v(t) bilan v(0) = v₀.
The velocity vector ${displaystyle {dot {v}}(t)}$ is normal to the surface at v(t), ya'ni P(v(t))v(t)=0.

This always has a unique solution, called the parallel transport of v₀ birga v.

The existence of parallel transport can be deduced using the analytic method described for SO(3)/SO(2), which from a path into the rank two projectionsQ(t) starting at Q₀ produced a path g(t) in SO(3) starting at Men shu kabi

{displaystyle Q=gQ_{0}g^{-1},,,,Q_{0}g^{-1}{dot {g}}Q_{0}=0.}

g(t) is the unique solution of the transport equation

g_tg⁻¹ = ½ F_t F

bilan g(0) = Men va F = 2Q − I. Applying this with Q(t) = P(v(t)), it follows that, given a tangent vector v₀ in the tangent space to M da v(0), the vector v(t)=g(t)v₀ lies in the tangent space to M da v(t) and satisfies the equation

{displaystyle P(c(t)){dot {v}}(t)=0.}

It therefore is exactly the parallel transport of v egri chiziq bo'ylab v.^[49] In this case the length of the vector v(t) doimiydir. More generally if another initial tangent vector siz₀ is taken instead of v₀, ichki mahsulot (v(t),siz(t)) is constant. The tangent spaces along the curve v(t) are thus canonically identified as inner product spaces by parallel transport so that parallel transport gives an isometry between the tangent planes. The condition on the velocity vector ${displaystyle {dot {v}}(t)}$ may be rewritten in terms of the covariant derivative as^[16]^[55]

{displaystyle abla _{dot {c}}v=0}

the defining equation for parallel transport.

The kinematik way of understanding parallel transport for the sphere applies equally well to any closed surface in E³ regarded as a rigid body in three-dimensional space rolling without slipping or twisting on a horizontal plane. The point of contact will describe a curve in the plane and on the surface. As for the sphere, the usual egrilik of the planar curve equals the geodesic curvature of the curve traced on the surface.

This geometric way of viewing parallel transport can also be directly expressed in the language of geometry.^[56] The konvert of the tangent planes to M egri chiziq bo'ylab v is a surface with vanishing Gaussian curvature, which by Minding's theorem, must be locally isometric to the Euclidean plane. This identification allows parallel transport to be defined, because in the Euclidean plane all tangent planes are identified with the space itself.

There is another simple way of constructing the connection form ω using the embedding of M yilda E³.^[57]

The tangent vectors e₁ va e₂ of a frame on M define smooth functions from E qiymatlari bilan R³, so each gives a 3-vector of functions and in particular de₁ is a 3-vector of 1-forms on E.

The connection form is given by

{displaystyle omega =de_{1}cdot e_{2}}

taking the usual scalar product on 3-vectors.

Gauss-Kodassi tenglamalari

Qachon M is embedded in E³, two other 1-forms ψ and χ can be defined on the frame bundle E using the shape operator.^[58]^[59]^[60] Indeed, the Gauss map induces a K-equivariant map of E into SO(3), the frame bundle of S² = SO(3)/SO(2). The form ω is the orqaga tortish of one of the three right invariant Maurer–Cartan forms on SO(3). The 1-forms ψ and χ are defined to be the pullbacks of the other two.

These 1-forms satisfy the following structure equations:

{displaystyle psi wedge heta _{1}+chi wedge heta _{2}=0}

(symmetry equation)

{displaystyle domega =psi wedge chi }

(Gauss tenglamasi)

{displaystyle dpsi =chi wedge omega ,,,dchi =omega wedge psi }

(Codazzi equations)

The Gauss-Kodassi tenglamalari for χ, ψ and ω follow immediately from the Maurer–Cartan equations for the three right invariant 1-forms on SO(3).

Reading guide

One of the most comprehensive introductory surveys of the subject, charting the historical development from before Gauss to modern times, is by Berger (2004). Graduate-level treatments of the Riemann aloqasi topish mumkin Singer & Thorpe (1967), do Carmo (1976) va O'Neill (1997). Accessible introductions to Cartan's approach to connections using moving frames can be found in Ivey & Landsberg (2003) va Sharpe (1997). The classic treatment of connections can be found in Kobayashi & Nomizu (1963).

Shuningdek qarang

Sirtlarning differentsial geometriyasi

Izohlar

^ Eyzenhart 2004 yil
^ Kreyszig 1991
^ Berger 2004 yil
^ Uilson 2008 yil
^ do Carmo 1976
^ O'Nil 1997 yil
^ ^a ^b ^v ^d Singer & Thorpe 1967
^ Kobayashi va Nomizu 1969 yil, Chapter XII.
^ Kobayashi & Nomizu 1967, p. 287
^ ^a ^b Levi-Civita 1917
^ Darboux & 1887,1889,1896
^ Kobayashi va Nomizu 1969 yil
^ Ivey & Landsberg 2003 This approach, together with its higher-dimensional generalisations, is discussed in great detail in Chapters 1 and 2.
^ Kobayashi va Nomizu 1963 yil, p. 160
^ do Carmo 1976, p. 55
^ ^a ^b ^v ^d ^e Kobayashi va Nomizu 1963 yil
^ do Carmo 1992, p. 89
^ do Carmo 1992, p. 91
^ do Carmo 1992, p. 61-62
^ Berger 2004 yil, p. 127
^ Berger 2004 yil, p. 129
^ A fuller discussion is given in the section on embedded surfaces.
^ Arnold 1982, 301-306 betlar, I ilova.
^ Berger 2004 yil, pp. 263–264
^ Arnold's method of approximation also applies to higher-dimensional Riemannian manifolds, after having given an appropriate geometric description of parallel transport along a geodesic. Parallel transport can be shown to be a continuous function on the Sobolev space of paths of finite energy, introduced in Klingenberg (1982). In this case the ordinary differential equation ${displaystyle heta _{t}=a(t)}$ is solved by an integral which depends continuously on a kabi a varies through piecewise continuous or even just square integrable functions. The higher-dimensional case requires the transport equation g_t = A g and an extension of the analysis in Nelson (1969).
^ do Carmo 1992, 56-57 betlar
^ Kobayashi va Nomizu 1963 yil, 68-71 bet
^ Singer & Thorpe 1967, pp. 181–184
^ ^a ^b Sasaki 1958
^ Kobayashi 1956
^ Ivey & Landsberg 2003
^ The definition presented here is due essentially to Charles Ehresmann. However, it is different from, though related to, what is commonly called an Ehresmann aloqasi. It is also different from, though related to, what is commonly called a Karton aloqasi. Qarang Kobayashi (1957) va Sharpe (1997) for a survey of some of the various types of connections and the relations between them.
^ Kobayashi va Nomizu 1963 yil, 63-64 bet
^ Berger 2004 yil, 727-788 betlar
^ A general connection on a principal bundle E tuzilish guruhi bilan H is described by a 1-form on E qiymatlari bilan ${ displaystyle { mathfrak {h}}}$ invariant under the tensor product of the action of H on 1-forms and the adjoint action. For surfaces, H is Abelian and 1-dimensional, so the connection 1-form is essentially given by an invariant 1-form on E.
^ Bo'sh joy p-forms can be identified with the space of alternating p-fold C^∞(E)-multilinear maps on the module of vector fields.For further details see Helgason (1978), pages 19–21.
^ Singer & Thorpe 1967, 185-189 betlar
^ Singer & Thorpe 1967, 190-193 betlar
^ Singer & Thorpe 1967, p. 143
^ Singer & Thorpe 1967, p. 191
^ Singer & Thorpe 1967, p. 195
^ do Carmo 1992
^ The Lie algebra of a closed connected subgroup G of a real or complex umumiy chiziqli guruh barcha matritsalardan iborat X such that exp tX yotadi G hamma uchun haqiqiy t; qarang Adams (1983) yoki Varadarajan (1984).
^ Geometrically this double cover corresponds to a spin tuzilishi kuni S².
^ Klingenberg & Sasaki 1975
^ Arnold 1978, Appendix 2: Geodesics of left-invariant metrics on Lie groups and the hydrodynamics of ideal fluids.
^ Varadarajan 1984, p. 138
^ Kobayashi va Nomizu 1963 yil, p. 69
^ ^a ^b This standard treatment of parallel transport can be found for example in Driver (1995, p. 25).
^ In mathematical physics, the solution of this differential equation is often expressed as a yo'l bilan buyurtma qilingan eksponent; masalan qarang Nelson (1969).
^ A similar argument applies to the transitive action by conjugation of SU(2) on matrices F = 2Q − Men bilan Q a rank one projection in M₂(C). This action is trivial on ± Men, so passes to a transitive action of SO(3) with stabilizer subgroup SO(2), showing that these matrices provide another model for S². This is standard material in o'lchov nazariyasi on SU(2); masalan qarang Narasimhan & Ramadas (1979).
^ Sharpe 1997, pp. 375–388, Appendix B: Rolling without Slipping or Twisting
^ Berger 2004 yil, p. 130
^ Kobayashi 1956, Theorem II.
^ do Carmo 1992, p. 52
^ do Carmo 1976, p. 244
^ Singer & Thorpe 1967, 221-223 betlar
^ O'Nil 1997 yil, 256-257 betlar
^ Ivey & Landsberg 2003, 2-bob.
^ Kobayashi va Nomizu 1969 yil, VII bob.

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Kartan, Elie (1983), Riemann kosmiklarining geometriyasi, Matematik ilmiy matbuot, ISBN 978-0-915692-34-7; translated from 2nd edition of Leçons sur la géométrie des espaces de Riemann (1951) by James Glazebrook.
Kartan, Elie (2001), Riemannian Geometry in an Orthogonal Frame (from lectures delivered by É Cartan at the Sorbonne in 1926–27), World Scientific, ISBN 9810247478, translated from Russian by V. V. Goldberg with a foreword by S. S. Chern.
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Gray, Alfred; Abbena, Elsa; Salamon, Simon (2006), Modern Differential Geometry of Curves And Surfaces With Mathematica, CRC Press, ISBN 1584884487
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Ivey, Thomas A.; Landsberg, J.M. (2003), Cartan for Beginners: Differential Geometry via Moving Frames and Exterior Systems, Matematikadan aspirantura, 61, Amerika matematik jamiyati, ISBN 0-8218-3375-8
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Tashqi havolalar

Calabi, Eugenio, Basics of the differential geometry of surfaces, Part I (PDF), Pensilvaniya universiteti
Calabi, Eugenio, Basics of the differential geometry of surfaces, Part II (PDF), Pensilvaniya universiteti
Calabi, Eugenio, Basics of the differential geometry of surfaces, Part III (PDF), Pensilvaniya universiteti
Calabi, Eugenio, Basics of the differential geometry of surfaces, Part IV (PDF), Pensilvaniya universiteti
Calabi, Eugenio, Basics of the differential geometry of surfaces, Part V (PDF), Pensilvaniya universiteti
Calabi, Eugenio, Basics of the differential geometry of surfaces, Parts VI and VII (PDF), Pensilvaniya universiteti
Calabi, Eugenio, Basics of the differential geometry of surfaces, Part VIII, Pensilvaniya universiteti

[1] Eyzenhart 2004 yil

[2] Kreyszig 1991

[3] Berger 2004 yil

[4] Uilson 2008 yil

[5] Carmo 1976

[6] O'Nil 1997 yil

[Singer-7] v ^d Singer & Thorpe 1967

[8] Kobayashi va Nomizu 1969 yil, Chapter XII.

[9] Kobayashi & Nomizu 1967, p. 287

[LeviCivita-10] Levi-Civita 1917

[11] Darboux & 1887,1889,1896

[12] Kobayashi va Nomizu 1969 yil

[13] Ivey & Landsberg 2003 This approach, together with its higher-dimensional generalisations, is discussed in great detail in Chapters 1 and 2.

[14] Kobayashi va Nomizu 1963 yil, p. 160

[15] Carmo 1976, p. 55

[Kobayashi-16] v ^d ^e Kobayashi va Nomizu 1963 yil

[17] Carmo 1992, p. 89

[18] Carmo 1992, p. 91

[19] Carmo 1992, p. 61-62

[20] Berger 2004 yil, p. 127

[21] Berger 2004 yil, p. 129

[22] A fuller discussion is given in the section on embedded surfaces.

[23] Arnold 1982, 301-306 betlar, I ilova.

[24] Berger 2004 yil, pp. 263–264

[25] Arnold's method of approximation also applies to higher-dimensional Riemannian manifolds, after having given an appropriate geometric description of parallel transport along a geodesic. Parallel transport can be shown to be a continuous function on the Sobolev space of paths of finite energy, introduced in Klingenberg (1982). In this case the ordinary differential equation ${displaystyle heta _{t}=a(t)}$ is solved by an integral which depends continuously on a kabi a varies through piecewise continuous or even just square integrable functions. The higher-dimensional case requires the transport equation g_t = A g and an extension of the analysis in Nelson (1969).

[26] Carmo 1992, 56-57 betlar

[27] Kobayashi va Nomizu 1963 yil, 68-71 bet

[28] Singer & Thorpe 1967, pp. 181–184

[Sasaki-29] Sasaki 1958

[30] Kobayashi 1956

[31] Ivey & Landsberg 2003

[32] The definition presented here is due essentially to Charles Ehresmann. However, it is different from, though related to, what is commonly called an Ehresmann aloqasi. It is also different from, though related to, what is commonly called a Karton aloqasi. Qarang Kobayashi (1957) va Sharpe (1997) for a survey of some of the various types of connections and the relations between them.

[33] Kobayashi va Nomizu 1963 yil, 63-64 bet

[34] Berger 2004 yil, 727-788 betlar

[35] A general connection on a principal bundle E tuzilish guruhi bilan H is described by a 1-form on E qiymatlari bilan ${ displaystyle { mathfrak {h}}}$ invariant under the tensor product of the action of H on 1-forms and the adjoint action. For surfaces, H is Abelian and 1-dimensional, so the connection 1-form is essentially given by an invariant 1-form on E.

[36] Bo'sh joy p-forms can be identified with the space of alternating p-fold C^∞(E)-multilinear maps on the module of vector fields.For further details see Helgason (1978), pages 19–21.

[37] Singer & Thorpe 1967, 185-189 betlar

[38] Singer & Thorpe 1967, 190-193 betlar

[39] Singer & Thorpe 1967, p. 143

[40] Singer & Thorpe 1967, p. 191

[41] Singer & Thorpe 1967, p. 195

[42] Carmo 1992

[43] The Lie algebra of a closed connected subgroup G of a real or complex umumiy chiziqli guruh barcha matritsalardan iborat X such that exp tX yotadi G hamma uchun haqiqiy t; qarang Adams (1983) yoki Varadarajan (1984).

[44] Geometrically this double cover corresponds to a spin tuzilishi kuni S².

[45] Klingenberg & Sasaki 1975

[46] Arnold 1978, Appendix 2: Geodesics of left-invariant metrics on Lie groups and the hydrodynamics of ideal fluids.

[47] Varadarajan 1984, p. 138

[48] Kobayashi va Nomizu 1963 yil, p. 69

[Thisstandard-49] This standard treatment of parallel transport can be found for example in Driver (1995, p. 25).

[50] In mathematical physics, the solution of this differential equation is often expressed as a yo'l bilan buyurtma qilingan eksponent; masalan qarang Nelson (1969).

[51] A similar argument applies to the transitive action by conjugation of SU(2) on matrices F = 2Q − Men bilan Q a rank one projection in M₂(C). This action is trivial on ± Men, so passes to a transitive action of SO(3) with stabilizer subgroup SO(2), showing that these matrices provide another model for S². This is standard material in o'lchov nazariyasi on SU(2); masalan qarang Narasimhan & Ramadas (1979).

[52] Sharpe 1997, pp. 375–388, Appendix B: Rolling without Slipping or Twisting

[53] Berger 2004 yil, p. 130

[54] Kobayashi 1956, Theorem II.

[55] Carmo 1992, p. 52

[56] Carmo 1976, p. 244

[57] Singer & Thorpe 1967, 221-223 betlar

[58] O'Nil 1997 yil, 256-257 betlar

[59] Ivey & Landsberg 2003, 2-bob.

[60] Kobayashi va Nomizu 1969 yil, VII bob.

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Ning turli xil tushunchalari egrilik ichida belgilangan differentsial geometriya
Differentsial geometriya egri chiziqlar	Egrilik Egri chiziqning burilishi Frenet-Serret formulalari Egrilik radiusi (ilovalar) Afinaning egriligi Umumiy egrilik Umumiy mutlaq egrilik
Differentsial geometriya yuzalar	Asosiy egriliklar Gauss egriligi O'rtacha egrilik Darboux ramkasi Gauss-Kodassi tenglamalari Birinchi asosiy shakl Ikkinchi asosiy shakl Uchinchi asosiy shakl
Riemann geometriyasi	Riemann manifoldlarining egriligi Riemann egriligi tensori Ricci egriligi Skalyar egrilik Kesmaning egriligi
Ulanishlarning egriligi	Egrilik shakli Torsion tensori Yorug'lik Holonomiya