多様体を構成するために、位相空間に完全アトラスを導入するところで質問です。 完全アトラスを導入するメリットとして、この文章の下線部を「異なる座標系を用いたのに同じ計算ができてしまうという問題が解消される」解釈したのですが、そこがよくわかりません。座標系を変えて計算する... 続きを読む

1 Two n-dimensional coordinate systems & and ŋ in S overlap smoothly provided the functions on¯¹ and ŋo §¯¹ are both smooth. Explicitly, if : U → R" and ŋ: R", then ŋ 1 is defined on the open set ε (ur) → ° (UV) V and carries it to n(u)—while its inverse function § 4-1 runs in the opposite direction (see Figure 1). These functions are then required to be smooth in the usual Euclidean sense defined above. This condition is con- sidered to hold trivially if u and do not meet. Č (UV) R" Ĕ(U) n(UV) R" S n(v) Figure 1. 1. Definition. An atlas A of dimension n on a space S is a collection of n-dimensional coordinate systems in S such that (A1) each point of S is contained in the domain of some coordinate system in, and (A2) any two coordinate systems in ✅ overlap smoothly. An atlas on S makes it possible to do calculus consistently on all of S. But different atlases may produce the same calculus, a technical difficulty eliminated as follows. Call an atlas Con S complete if C contains each co- ordinate system in S that overlaps smoothly with every coordinate system in C. 2. Lemma. Each atlas ✅ on S is contained in a unique complete atlas. Proof. If has dimension n, let A' be the set of all n-dimensional coordinate systems in S that overlap smoothly with every one contained in A. (a) A' is an atlas (of the same dimension as ✅).

画像の4.2の問題の解き方を教えてください。

106 K M X(T) M. F sin (NT) (1)X 100 -100 ( XImax 80 0 0 4 Dimensional Scaling Analysis + KX = F sin (2T), X(0) = Xo, 1 n 2 10 T 3 Fig. 4.1 The elementary problem of a mass on spring with an applied force: (Left) dimensional parameters, (Right) solutions X(T) for various parameters and (Inset) the amplitude in relation to the forcing frequency ada 4.2 The governing equation for the linear mass-spring system shown in Fig. 4.1 is d²X dT² dX dT\T=0 20 = Vo, where X(T) [m] is the position of the mass as a function of time with mass M [kg], and spring coefficient K [N/m], magnitude of the applied force, F [N], forcing frequency, 2 [s], as well as general initial conditions, Nondimensionalize and select length- and time-scales L, T to normalise the coef- ficients of the terms on the left side of the ODE and the initial condition for position. Write and solve the scaled problem, and identify the dimensionless parameter for the ratio of the forcing frequency to resonant frequency, where the solution's amplitude grows without bound, as shown for 22 in Fig. 4.1. 4.3 Consider the initial value problem for a damped driven nonlinear oscillator:

画像の問題を教えてください！

106 K M X(T) M. F sin (NT) (1)X 100 -100 ( XImax 80 0 0 4 Dimensional Scaling Analysis + KX = F sin (2T), X(0) = Xo, 1 n 2 10 T 3 Fig. 4.1 The elementary problem of a mass on spring with an applied force: (Left) dimensional parameters, (Right) solutions X(T) for various parameters and (Inset) the amplitude in relation to the forcing frequency ada 4.2 The governing equation for the linear mass-spring system shown in Fig. 4.1 is d²X dT² dX dT\T=0 20 = Vo, where X(T) [m] is the position of the mass as a function of time with mass M [kg], and spring coefficient K [N/m], magnitude of the applied force, F [N], forcing frequency, 2 [s], as well as general initial conditions, Nondimensionalize and select length- and time-scales L, T to normalise the coef- ficients of the terms on the left side of the ODE and the initial condition for position. Write and solve the scaled problem, and identify the dimensionless parameter for the ratio of the forcing frequency to resonant frequency, where the solution's amplitude grows without bound, as shown for 22 in Fig. 4.1. 4.3 Consider the initial value problem for a damped driven nonlinear oscillator:

加法定理です！ 基本165の問題が分からないことがあります。 αは鋭角であるから、と答えにあるのですが、鋭角と鈍角はどうやって見分けるのでしょうか？また、Sinα=‪√‬1-cos２乗αの式はどの公式をつかっているのでしょうか？ お願いしますm(_ _)m

27 加法定理 ① 正弦余弦の加法定理 ① sin (a+β)=sinacosβ+cosasin β ② sin (a-β)=sinacosβ-cos asin β 3 cos (a+8)=cos a cos B-sinasinß ④ cos (a-β)=cosacosβ+sinasin β 正接の加法定理 tana + tan B tan(a+8)=7 1-tanatan B 2直線のなす鋭角 x軸の正の部分から2直線y=mix ...... 図のようにα, βとすると 2直線①、②のなす角0 (0<0<^) [1] 0<α-B <1のとき 0=a-B 13 sin 1x, cos YA a (2) sing= 0 B 13 127, 4 ② tan (α-β)= π, ・①,y=mzx..... tang=m, tanβ=mz = 基本 163 加法定理を用いて, sin 165°, cos 165°tan 165°の値を求めよ。 13 π 3 19 基本 164 1/12=1/7/8/1/1 + 3 5 -π+- 3 12' 4 6 ミル tana-tan 1+tan atan B は次のようになる。 [2] <a-Bのとき 0=-(α-B) YA A 19 tan 12 の値を求めよ。 ITEM a B まで測った角を x であることを用いて, 基本 165αが鋭角, βが鈍角であるとき、次の値を求めよ。 (1) cos a=- sinβ=1のとき sin(a+B), cos(a+B) 1 3' 12 =1/13, cosB=- β= のとき sin(α-β), cos(α-B) 13 (3) tana=5, tanß=-3 M¿‡ tan(a+ß), tan (α-ß)

qiitaのサイト上での質問で失礼します。もし規約違反でしたら申し訳ありません。 サイト作成者の方は最近qiitaにアクセスしておらず、質問ができない状況です。 https://qiita.com/u_1roh/items/a8a8761b23e2b8381ebe ... 続きを読む

e₁ V₁ 開区間 (i,j) Vj

多様体の接空間に関する基底定理の証明です。g(q)=∫〜と定義した関数を微積分学の基本定理を用いながら変形してg(q)=g(0)+∑gᵢuⁱと導出するのですが、これがうまくいきません。 自分は、g(q)の式をまず両辺tで微分して、次に両辺uⁱで積分して、最後に両辺tで積分... 続きを読む

12. Theorem.If{ = (x', , x") is a coordinate system in M at p, then its coordinate vectors d, lp, …… 0,l, forma basis for the tangent space T,(M); and D= E(x) 。 i=1 for all ve T(M). Proof. By the preceding remarks we can work solely on the coordinate neighborhood of G. Since u(c) = Othere is no loss of generality in assuming ど(p) = 0eR". Shrinking W if necessary gives E(W) = {qe R":|q| < } for some 8. Ifg is a smooth function on E(W) then for each 1 <isndefine og (tq) dt du g(9) = for all qe {(W). It follows using the fundamental theorem of calculus that g= g(0) + E&,u' on (W). Thus if fe &(M), setting g = f。' yields f= f(P) + Ex on U. Applying d/ax' gives f(p) = (f /0x)(P). Thus applying the tangent vector e to the formula gives (f) = 0+ E(x'(p) + E Ap)u(x) = E(Px). ず ax Since this holds for all f e &(M), the tangent vectors v and Z Ux') d,l, are equal. It remains to show that the coordinate vectors are linearly independent. But if ) a, o.l, = 0, then application to x' yields dxi 0=24 (P) = 2q d」= 4. In particular the (vector space) dimension of T,(M) is the same as the dimension of M.

よくわかっていないなりに教科書を見ながら解いてみたのですが全体的に自信がありません💦 そこで、私の解答が合っているか確認して頂きたいです 回答よろしくお願いします🙇‍♀️

ee ウ2ービズ 2 27で-ex ex(2で-1) ズ 2ー1 (2x-12.6 0 2 2x-1 -0 2ズ-1 2 2 x? 2 2-700のときダ→0 Jってよ→00 Dビタルの定理より tim ye lim lery Lim 22e 1 2→0 スマー0のとき ズ→00 よって33-0 ロピタルの定理より Lim ye tem le') スラーの 1コ-の Lm 22e 文ラーの

この2つの微分の仕方を教えてください。 ちなみに（1）の答えは−2tan2xで（2）の答えは1/√x²+a²です。

TEME い) 1.g10.v2×| 1-3 1x+Jxィa) 1as0)

留学先の統計学の問題です。 4、5、2問あります。 後、数時間で提出となり、焦っております。 どなたかお力添えをお願いします😭😭😭 時差があり、深夜回答はたいへんありがたいです。 朝までにお願いします。

4. The temperature of the Earth at different sites can be measured in two ways. One, by taking readings using thermometers on the ground (x), which is extremely tedious and time consuming. Second, bylasers positioned on satellites revolving about the Earth (v). which ie a less accurate method and may be biased. The readings for both are given below: Ground Therm., x Satellite Laser, y Site 1 4.6 4.7 2 17.3 19.5 3 12.2 12.5 4 3.6 4.2 5 6.2 6.0 6 14.8 15.4 7 11.4 14.9 8 14.9 17.8 emignaia 9 9.3 9.7 10 10.4 10.5 11 7.2 7.4 You would like to test the claim that the Laser method gives a significantly higher reading than the ground therm. method. You may assume that the difference between pairs of scores is approximately normal. A) Would testing for a difference in means or a paired difference test be better to use here? Why? B) Perform the test you concluded in part A). 200 seetV C) Would you have any reservations about yourinference? Why?

arccos(x) のn回微分は これであってますか？

(っM) 和夫Tr た 人 らい ーー ーーたVWーョのeidig ロ CD Tetem-1 (Cw=-のrr用ィ