Virtual joy almashish

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Analitik mexanikada amaliy matematika va fizikaning bir boʻlimi, virtual siljish (yoki cheksiz kichik oʻzgarish) ${\displaystyle \delta \gamma }$ Mexanik tizimning trayektoriyasi gipotetik (shuning uchun virtual atamasi) haqiqiy traektoriyadan qanday qilib biroz chetga chiqishi mumkinligini koʻrsatadi. ${\displaystyle \gamma }$ tizimning cheklovlarini buzmasdan^{[1] [2] [3]}. Har lahza uchun ${\displaystyle t,}$${\displaystyle \delta \gamma (t)}$ nuqtadagi konfiguratsiya fazosiga tangensial vektordir ${\displaystyle \gamma (t).}$ Vektorlar ${\displaystyle \delta \gamma (t)}$ qaysi yoʻnalishlarni koʻrsating ${\displaystyle \gamma (t)}$ cheklovlarni buzmasdan „borish“ mumkin.

Misol uchun, ikki oʻlchovli sirtdagi bitta zarrachadan tashkil topgan tizimning virtual siljishlari, qoʻshimcha cheklovlar yoʻq deb hisoblab, butun tangens tekisligini toʻldiradi.

Biroq, cheklovlar barcha trayektoriyalarni talab qilsa ${\displaystyle \gamma }$ berilgan nuqtadan oʻting ${\displaystyle 𝐪}$ berilgan vaqtda ${\displaystyle \tau ,}$ yaʼni ${\displaystyle \gamma (\tau )=𝐪,}$ keyin ${\displaystyle \delta \gamma (\tau )=0.}$

Mayli ${\displaystyle M}$ mexanik tizimning konfiguratsiya maydoni boʻlsin, ${\displaystyle t_0,t_1\in ℝ}$ vaqt lahzalari boʻlsin, ${\displaystyle q_0,q_1\in M,}$${\displaystyle C^{\mathrm{\infty }}[t_0,t_1]}$ ustidagi silliq funksiyalardan iborat.

Cheklovlar ${\displaystyle \gamma (t_0)=q_0,}$${\displaystyle \gamma (t_1)=q_1}$ Bu yerda faqat tasvir uchun. Amalda, har bir alohida tizim uchun individual cheklovlar toʻplami talab qilinadi.

Har bir yoʻl uchun ${\displaystyle \gamma \in P(M)}$ va ${\displaystyle {ϵ}_0>0,}$ ning oʻzgarishi ${\displaystyle \gamma }$ funksiya hisoblanadi ${\displaystyle \mathrm{\Gamma }:[t_0,t_1]\times [-{ϵ}_0,{ϵ}_0]\to M}$ shunday, har bir uchun ${\displaystyle ϵ\in [-{ϵ}_0,{ϵ}_0],}$${\displaystyle \mathrm{\Gamma }(\cdot ,ϵ)\in P(M)}$ va ${\displaystyle \mathrm{\Gamma }(t,0)=\gamma (t).}$ Virtual joy almashish ${\displaystyle \delta \gamma :[t_0,t_1]\to TM}$${\displaystyle (TM}$ ning tangens toʻplamidir ${\displaystyle M)}$ oʻzgarishiga mos keladi ${\displaystyle \mathrm{\Gamma }}$ har biriga quyidagini belgilaydi ${\displaystyle t\in [t_0,t_1]}$ tangens vektori

${\displaystyle \delta \gamma (t)=\frac{d\mathrm{\Gamma }(t,ϵ)}{dϵ}{|}_{ϵ=0}\in T_{\gamma (t)}M.}$

Tangens xaritasi nuqtai nazaridan,

${\displaystyle \delta \gamma (t)={\mathrm{\Gamma }}_{*}^t\left(\frac{d}{dϵ}{|}_{ϵ=0}\right).}$

Bu yerda ${\displaystyle {\mathrm{\Gamma }}_{*}^t:T_0[-ϵ,ϵ]\to T_{\mathrm{\Gamma }(t,0)}M=T_{\gamma (t)}M}$ ning tangens xaritasi hisoblanadi ${\displaystyle {\mathrm{\Gamma }}^t:[-ϵ,ϵ]\to M,}$ bu yerda ${\displaystyle {\mathrm{\Gamma }}^t(ϵ)=\mathrm{\Gamma }(t,ϵ),}$ va ${\displaystyle \frac{d}{dϵ}{|}_{ϵ=0}\in T_0[-ϵ,ϵ].}$

• Koordinatali vakillik. Agar ${\displaystyle \{q_i{\}}_{i=1}^n}$ ixtiyoriy diagrammadagi koordinatalar ${\displaystyle M}$ va ${\displaystyle n=\mathrm{d}\mathrm{i}\mathrm{m}M,}$ keyin

${\displaystyle \delta \gamma (t)={\displaystyle \sum _{i=1}^n}\frac{d[q_i(\mathrm{\Gamma }(t,ϵ))]}{dϵ}{|}_{ϵ=0}\cdot \frac{d}{d{q}_i}{|}_{\gamma (t)}.}$

• Agar, bir zumda ${\displaystyle \tau }$ va har bir ${\displaystyle \gamma \in P(M),}$${\displaystyle \gamma (\tau )=\text{const},}$ keyin, har biri uchun ${\displaystyle \gamma \in P(M),}$${\displaystyle \delta \gamma (\tau )=0.}$

• Agar ${\displaystyle \gamma ,\frac{d\gamma }{dt}\in P(M),}$ keyin ${\displaystyle \delta \frac{d\gamma }{dt}=\frac{d}{dt}\delta \gamma .}$

Yagona zarracha erkin harakatlanadi ${\displaystyle {ℝ}^3}$ 3 erkinlik darajasiga ega. Konfiguratsiya maydoni ${\displaystyle M={ℝ}^3,}$ va ${\displaystyle P(M)=C^{\mathrm{\infty }}([t_0,t_1],M).}$ Har bir yoʻl uchun ${\displaystyle \gamma \in P(M)}$ va variatsiya ${\displaystyle \mathrm{\Gamma }(t,ϵ)}$ ning ${\displaystyle \gamma ,}$ noyobi mavjud ${\displaystyle \sigma \in T_0{ℝ}^3}$ shu kabi ${\displaystyle \mathrm{\Gamma }(t,ϵ)=\gamma (t)+\sigma (t)ϵ+o(ϵ),}$ kabi ${\displaystyle ϵ\to 0.}$ Taʼrifga koʻra,

${\displaystyle \delta \gamma (t)=\left(\frac{d}{dϵ}\right(\gamma (t)+\sigma (t)ϵ+o(ϵ)\left)\right){|}_{ϵ=0}}$

olib keladi

${\displaystyle \delta \gamma (t)=\sigma (t)\in T_{\gamma (t)}{ℝ}^3.}$

${\displaystyle N}$ ikki oʻlchovli sirtda erkin harakatlanadigan zarralar ${\displaystyle S\subset {ℝ}^3}$ bor ${\displaystyle 2N}$ erkinlik darajasi. Bu yerda konfiguratsiya maydoni

${\displaystyle M=\{({𝐫}_1,\dots ,{𝐫}_N)\in {ℝ}^{3N}\mid {𝐫}_i\in {ℝ}^3;{𝐫}_i\ne {𝐫}_j\text{if}i\ne j\},}$

bu yerda ${\displaystyle {𝐫}_i\in {ℝ}^3}$ ning radius vektori ${\displaystyle i^{\text{th}}}$ zarracha. Bundan quyidagi kelib chiqadi

${\displaystyle T_{({𝐫}_1,\dots ,{𝐫}_N)}M=T_{{𝐫}_1}S\oplus \dots \oplus T_{{𝐫}_N}S,}$

va har bir yoʻl ${\displaystyle \gamma \in P(M)}$ radius vektorlari yordamida tasvirlanishi mumkin ${\displaystyle {𝐫}_i}$ har bir alohida zarrachaning, yaʼni

${\displaystyle \gamma (t)=({𝐫}_1(t),\dots ,{𝐫}_N(t)).}$

Bu shuni anglatadiki, har bir kishi uchun ${\displaystyle \delta \gamma (t)\in T_{({𝐫}_1(t),\dots ,{𝐫}_N(t))}M,}$

${\displaystyle \delta \gamma (t)=\delta {𝐫}_1(t)\oplus \dots \oplus \delta {𝐫}_N(t),}$

bu yerda ${\displaystyle \delta {𝐫}_i(t)\in T_{{𝐫}_i(t)}S.}$ Baʼzi mualliflar buni shunday ifodalaydilar

${\displaystyle \delta \gamma =(\delta {𝐫}_1,\dots ,\delta {𝐫}_N).}$

Qoʻshimcha cheklovlarsiz qoʻzgʻalmas nuqta atrofida aylanadigan qattiq jism 3 daraja erkinlikka ega. Bu yerda konfiguratsiya maydoni ${\displaystyle M=SO(3),}$ 3 oʻlchovli maxsus ortogonal guruh (aks holda 3D aylanish guruhi deb nomlanadi) va ${\displaystyle P(M)=C^{\mathrm{\infty }}([t_0,t_1],M).}$ Biz standart belgidan foydalanamiz ${\displaystyle 𝔰𝔬(3)}$ barcha egri-simmetrik uch oʻlchovli matritsalarning uch oʻlchovli chiziqli fazosiga murojaat qilish. Eksponensial xarita ${\displaystyle \exp :𝔰𝔬(3)\to SO(3)}$ mavjudligini kafolatlaydi ${\displaystyle {ϵ}_0>0}$ Shunday qilib, har bir yoʻl uchun ${\displaystyle \gamma \in P(M),}$ uning oʻzgarishi ${\displaystyle \mathrm{\Gamma }(t,ϵ),}$ va ${\displaystyle t\in [t_0,t_1],}$ oʻziga xos yoʻl bor ${\displaystyle {\mathrm{\Theta }}^t\in C^{\mathrm{\infty }}([-{ϵ}_0,{ϵ}_0],𝔰𝔬(3))}$ shu kabi ${\displaystyle {\mathrm{\Theta }}^t(0)=0}$ va har biri uchun ${\displaystyle ϵ\in [-{ϵ}_0,{ϵ}_0],}$${\displaystyle \mathrm{\Gamma }(t,ϵ)=\gamma (t)\exp ({\mathrm{\Theta }}^t(ϵ)).}$ Taʼrifga koʻra,

${\displaystyle \delta \gamma (t)=\left(\frac{d}{dϵ}\right(\gamma (t)\exp ({\mathrm{\Theta }}^t(ϵ))\left)\right){|}_{ϵ=0}=\gamma (t)\frac{d{\mathrm{\Theta }}^t(ϵ)}{dϵ}{|}_{ϵ=0}.}$

Chunki, baʼzi funksiyalar uchun ${\displaystyle \sigma :[t_0,t_1]\to 𝔰𝔬(3),}$${\displaystyle {\mathrm{\Theta }}^t(ϵ)=ϵ\sigma (t)+o(ϵ)}$, kabi ${\displaystyle ϵ\to 0}$ ,

${\displaystyle \delta \gamma (t)=\gamma (t)\sigma (t)\in T_{\gamma (t)}SO(3).}$

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