Difference between revisions of "User:Maximilian Janisch/latexlist/latex/NoNroff/50"
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8. https://www.encyclopediaofmath.org/legacyimages/w/w120/w120210/w12021023.png ; $\{ A _ { i } \} _ { i = 1 } ^ { k }$ ; confidence 0.642 | 8. https://www.encyclopediaofmath.org/legacyimages/w/w120/w120210/w12021023.png ; $\{ A _ { i } \} _ { i = 1 } ^ { k }$ ; confidence 0.642 | ||
− | 9. https://www.encyclopediaofmath.org/legacyimages/l/l120/l120200/l12020010.png ; $R P ^ { n } \geq n + 1$ ; confidence 0.642 | + | 9. https://www.encyclopediaofmath.org/legacyimages/l/l120/l120200/l12020010.png ; $\operatorname{cat}_{\mathbf{R} P ^ { n }} \mathbf{R}P^n \geq n + 1$ ; confidence 0.642 |
10. https://www.encyclopediaofmath.org/legacyimages/d/d120/d120070/d1200704.png ; $\sigma _ { 1 } , \ldots , \sigma _ { t }$ ; confidence 0.642 | 10. https://www.encyclopediaofmath.org/legacyimages/d/d120/d120070/d1200704.png ; $\sigma _ { 1 } , \ldots , \sigma _ { t }$ ; confidence 0.642 | ||
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13. https://www.encyclopediaofmath.org/legacyimages/s/s120/s120250/s12025030.png ; $\sqrt { 1 - x ^ { 2 } } w ( x ) > 0$ ; confidence 0.642 | 13. https://www.encyclopediaofmath.org/legacyimages/s/s120/s120250/s12025030.png ; $\sqrt { 1 - x ^ { 2 } } w ( x ) > 0$ ; confidence 0.642 | ||
− | 14. https://www.encyclopediaofmath.org/legacyimages/h/h048/h048070/h04807042.png ; $S = \frac { 1 } { n - 1 } \sum _ { i = 1 } ^ { n } ( X _ { i } - X ) ( X _ { i } - X ) ^ { \prime }$ ; confidence 0.642 | + | 14. https://www.encyclopediaofmath.org/legacyimages/h/h048/h048070/h04807042.png ; $S = \frac { 1 } { n - 1 } \sum _ { i = 1 } ^ { n } ( X _ { i } - X ) ( X _ { i } - X ) ^ { \prime },$ ; confidence 0.642 |
− | 15. https://www.encyclopediaofmath.org/legacyimages/b/b017/b017380/b01738052.png ; $\ | + | 15. https://www.encyclopediaofmath.org/legacyimages/b/b017/b017380/b01738052.png ; $\phi_j$ ; confidence 0.642 |
− | 16. https://www.encyclopediaofmath.org/legacyimages/c/c130/c130260/c13026030.png ; $\langle [ A ] , \phi \ | + | 16. https://www.encyclopediaofmath.org/legacyimages/c/c130/c130260/c13026030.png ; $\langle [ A ] , \phi \rangle = \int _ { \operatorname { reg } A } \phi.$ ; confidence 0.642 |
17. https://www.encyclopediaofmath.org/legacyimages/a/a130/a130240/a13024048.png ; $s \times p$ ; confidence 0.642 | 17. https://www.encyclopediaofmath.org/legacyimages/a/a130/a130240/a13024048.png ; $s \times p$ ; confidence 0.642 | ||
− | 18. https://www.encyclopediaofmath.org/legacyimages/a/a110/a110580/a11058065.png ; $ | + | 18. https://www.encyclopediaofmath.org/legacyimages/a/a110/a110580/a11058065.png ; $l_2$ ; confidence 0.642 |
− | 19. https://www.encyclopediaofmath.org/legacyimages/f/f120/f120110/f12011090.png ; $F _ { \sigma } \in \ | + | 19. https://www.encyclopediaofmath.org/legacyimages/f/f120/f120110/f12011090.png ; $F _ { \sigma } \in \widetilde { O } ( ( \Omega + \Gamma _ { \sigma } ) \cap U ).$ ; confidence 0.642 |
20. https://www.encyclopediaofmath.org/legacyimages/e/e035/e035000/e03500038.png ; $N _ { \epsilon } ( C )$ ; confidence 0.642 | 20. https://www.encyclopediaofmath.org/legacyimages/e/e035/e035000/e03500038.png ; $N _ { \epsilon } ( C )$ ; confidence 0.642 | ||
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22. https://www.encyclopediaofmath.org/legacyimages/d/d030/d030290/d03029013.png ; $Q \in [ \alpha , b ]$ ; confidence 0.642 | 22. https://www.encyclopediaofmath.org/legacyimages/d/d030/d030290/d03029013.png ; $Q \in [ \alpha , b ]$ ; confidence 0.642 | ||
− | 23. https://www.encyclopediaofmath.org/legacyimages/m/m130/m130060/m1300601.png ; $f _ { 1 } : = x _ { 1 } ^ { d }$ ; confidence 0.642 | + | 23. https://www.encyclopediaofmath.org/legacyimages/m/m130/m130060/m1300601.png ; $f _ { 1 } : = x _ { 1 } ^ { d },$ ; confidence 0.642 |
24. https://www.encyclopediaofmath.org/legacyimages/s/s120/s120220/s12022037.png ; $t \searrow 0$ ; confidence 0.641 | 24. https://www.encyclopediaofmath.org/legacyimages/s/s120/s120220/s12022037.png ; $t \searrow 0$ ; confidence 0.641 | ||
− | 25. https://www.encyclopediaofmath.org/legacyimages/t/t120/t120060/t12006026.png ; $E ^ { TF } ( N ) = \operatorname { inf } \{ E ( \rho ) : \rho \in L ^ { 5 / 3 } , \int \rho = N , \rho \geq 0 \}$ ; confidence 0.641 | + | 25. https://www.encyclopediaofmath.org/legacyimages/t/t120/t120060/t12006026.png ; $E ^ { TF } ( N ) = \operatorname { inf } \{ \mathcal{E} ( \rho ) : \rho \in L ^ { 5 / 3 } , \int \rho = N , \rho \geq 0 \},$ ; confidence 0.641 |
26. https://www.encyclopediaofmath.org/legacyimages/f/f130/f130100/f13010058.png ; $L _ { C } ^ { p } ( G )$ ; confidence 0.641 | 26. https://www.encyclopediaofmath.org/legacyimages/f/f130/f130100/f13010058.png ; $L _ { C } ^ { p } ( G )$ ; confidence 0.641 | ||
− | 27. https://www.encyclopediaofmath.org/legacyimages/t/t094/t094080/t09408036.png ; $\pi _ { n } ( X ; A , B , * ) = \pi _ { n - 1 } ( \Omega ( X ; A , B ) , * )$ ; confidence 0.641 | + | 27. https://www.encyclopediaofmath.org/legacyimages/t/t094/t094080/t09408036.png ; $\pi _ { n } ( X ; A , B , * ) = \pi _ { n - 1 } ( \Omega ( X ; A , B ) , * ).$ ; confidence 0.641 |
− | 28. https://www.encyclopediaofmath.org/legacyimages/b/b120/b120210/b12021045.png ; $p \subset a$ ; confidence 0.641 | + | 28. https://www.encyclopediaofmath.org/legacyimages/b/b120/b120210/b12021045.png ; $\mathfrak{p} \subset \mathfrak{a}$ ; confidence 0.641 |
29. https://www.encyclopediaofmath.org/legacyimages/b/b015/b015660/b01566019.png ; $h = 1$ ; confidence 0.641 | 29. https://www.encyclopediaofmath.org/legacyimages/b/b015/b015660/b01566019.png ; $h = 1$ ; confidence 0.641 | ||
− | 30. https://www.encyclopediaofmath.org/legacyimages/c/c120/c120050/c12005017.png ; $f \rightarrow \frac { 1 } { 2 \pi } \int _ { 0 } ^ { 2 \pi } \operatorname { Re } \frac { e ^ { i t } + z } { e ^ { t t } - z } f ( e ^ { i t } ) d t$ ; confidence 0.641 | + | 30. https://www.encyclopediaofmath.org/legacyimages/c/c120/c120050/c12005017.png ; $f \rightarrow \frac { 1 } { 2 \pi } \int _ { 0 } ^ { 2 \pi } \operatorname { Re } \frac { e ^ { i t } + z } { e ^ { t t } - z } f ( e ^ { i t } ) d t,$ ; confidence 0.641 |
31. https://www.encyclopediaofmath.org/legacyimages/f/f110/f110010/f11001056.png ; $e \leq x$ ; confidence 0.641 | 31. https://www.encyclopediaofmath.org/legacyimages/f/f110/f110010/f11001056.png ; $e \leq x$ ; confidence 0.641 | ||
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32. https://www.encyclopediaofmath.org/legacyimages/l/l057/l057000/l0570009.png ; $x \in \Lambda$ ; confidence 0.641 | 32. https://www.encyclopediaofmath.org/legacyimages/l/l057/l057000/l0570009.png ; $x \in \Lambda$ ; confidence 0.641 | ||
− | 33. https://www.encyclopediaofmath.org/legacyimages/b/b110/b110020/b11002029.png ; $\| | + | 33. https://www.encyclopediaofmath.org/legacyimages/b/b110/b110020/b11002029.png ; $\| u_f \| \leq \| f \| / c$ ; confidence 0.641 |
34. https://www.encyclopediaofmath.org/legacyimages/e/e120/e120230/e12023089.png ; $E ^ { k } = M \times F \times F ^ { ( 1 ) } \times \ldots F ^ { ( k ) }$ ; confidence 0.641 | 34. https://www.encyclopediaofmath.org/legacyimages/e/e120/e120230/e12023089.png ; $E ^ { k } = M \times F \times F ^ { ( 1 ) } \times \ldots F ^ { ( k ) }$ ; confidence 0.641 | ||
− | 35. https://www.encyclopediaofmath.org/legacyimages/a/a130/a130320/a13032042.png ; $E _ { \theta } ( N ) = \frac { P _ { \theta } ( S _ { N } = K ) K - P _ { \theta } ( S _ { N } = - J ) J } { 2 \theta - 1 }$ ; confidence 0.641 | + | 35. https://www.encyclopediaofmath.org/legacyimages/a/a130/a130320/a13032042.png ; $E _ { \theta } ( N ) = \frac { P _ { \theta } ( S _ { N } = K ) K - P _ { \theta } ( S _ { N } = - J ) J } { 2 \theta - 1 }.$ ; confidence 0.641 |
− | 36. https://www.encyclopediaofmath.org/legacyimages/s/s090/s090670/s0906703.png ; $U : C \rightarrow Set$ ; confidence 0.641 | + | 36. https://www.encyclopediaofmath.org/legacyimages/s/s090/s090670/s0906703.png ; $U : \mathcal{C} \rightarrow \operatorname{Set}$ ; confidence 0.641 |
37. https://www.encyclopediaofmath.org/legacyimages/l/l120/l120070/l12007034.png ; $s = 1 + p _ { 1 } / r + \ldots + p _ { 1 } \ldots p _ { k - 1 } / r ^ { k - 1 }$ ; confidence 0.641 | 37. https://www.encyclopediaofmath.org/legacyimages/l/l120/l120070/l12007034.png ; $s = 1 + p _ { 1 } / r + \ldots + p _ { 1 } \ldots p _ { k - 1 } / r ^ { k - 1 }$ ; confidence 0.641 | ||
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39. https://www.encyclopediaofmath.org/legacyimages/c/c130/c130190/c13019048.png ; $A = \operatorname { diag } ( \lambda _ { 1 } , \dots , \lambda _ { n } )$ ; confidence 0.641 | 39. https://www.encyclopediaofmath.org/legacyimages/c/c130/c130190/c13019048.png ; $A = \operatorname { diag } ( \lambda _ { 1 } , \dots , \lambda _ { n } )$ ; confidence 0.641 | ||
− | 40. https://www.encyclopediaofmath.org/legacyimages/l/l120/l120170/l120170281.png ; $d _ { 2 } ( | + | 40. https://www.encyclopediaofmath.org/legacyimages/l/l120/l120170/l120170281.png ; $d _ { 2 } ( \theta _ { 2 } ^ { j } )$ ; confidence 0.640 |
41. https://www.encyclopediaofmath.org/legacyimages/m/m130/m130050/m1300501.png ; $a \leftrightarrow b a b ^ { - 1 }$ ; confidence 0.640 | 41. https://www.encyclopediaofmath.org/legacyimages/m/m130/m130050/m1300501.png ; $a \leftrightarrow b a b ^ { - 1 }$ ; confidence 0.640 | ||
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42. https://www.encyclopediaofmath.org/legacyimages/c/c020/c020570/c02057069.png ; $\phi _ { p }$ ; confidence 0.640 | 42. https://www.encyclopediaofmath.org/legacyimages/c/c020/c020570/c02057069.png ; $\phi _ { p }$ ; confidence 0.640 | ||
− | 43. https://www.encyclopediaofmath.org/legacyimages/f/f120/f120040/f12004047.png ; $( R _ { + } \backslash \{ 0 \} , | + | 43. https://www.encyclopediaofmath.org/legacyimages/f/f120/f120040/f12004047.png ; $( \mathbf{R} _ { + } \backslash \{ 0 \} , \times , \leq )$ ; confidence 0.640 |
− | 44. https://www.encyclopediaofmath.org/legacyimages/c/c120/c120180/c120180277.png ; $\in \ | + | 44. https://www.encyclopediaofmath.org/legacyimages/c/c120/c120180/c120180277.png ; $\in \bigotimes \square ^ { p + q + 1 } \mathcal{E}$ ; confidence 0.640 |
− | 45. https://www.encyclopediaofmath.org/legacyimages/h/h130/h130020/h13002064.png ; $R \subseteq A ^ { | + | 45. https://www.encyclopediaofmath.org/legacyimages/h/h130/h130020/h13002064.png ; $R \subseteq A ^ { n }$ ; confidence 0.640 |
− | 46. https://www.encyclopediaofmath.org/legacyimages/b/b120/b120150/b12015037.png ; $E _ { P } ( d _ { 0 } ) = 0$ ; confidence 0.640 | + | 46. https://www.encyclopediaofmath.org/legacyimages/b/b120/b120150/b12015037.png ; $\text{E} _ { P } ( d _ { 0 } ) = 0$ ; confidence 0.640 |
47. https://www.encyclopediaofmath.org/legacyimages/c/c130/c130100/c13010027.png ; $( C ) \int _ { A } f d m = ( C ) \int f \cdot \chi _ { A } d m$ ; confidence 0.640 | 47. https://www.encyclopediaofmath.org/legacyimages/c/c130/c130100/c13010027.png ; $( C ) \int _ { A } f d m = ( C ) \int f \cdot \chi _ { A } d m$ ; confidence 0.640 | ||
− | 48. https://www.encyclopediaofmath.org/legacyimages/b/b120/b120090/b12009020.png ; $0 | + | 48. https://www.encyclopediaofmath.org/legacyimages/b/b120/b120090/b12009020.png ; $0 \leq t < \infty$ ; confidence 0.640 |
− | 49. https://www.encyclopediaofmath.org/legacyimages/p/p120/p120170/p12017037.png ; $\ | + | 49. https://www.encyclopediaofmath.org/legacyimages/p/p120/p120170/p12017037.png ; $\widehat { B^* } $ ; confidence 0.640 |
50. https://www.encyclopediaofmath.org/legacyimages/a/a130/a130320/a1303205.png ; $E _ { \theta } ( X _ { i } ) = P _ { \theta } ( X _ { i } = 1 ) = \theta = 1 - P _ { \theta } ( X _ { i } = 0 )$ ; confidence 0.640 | 50. https://www.encyclopediaofmath.org/legacyimages/a/a130/a130320/a1303205.png ; $E _ { \theta } ( X _ { i } ) = P _ { \theta } ( X _ { i } = 1 ) = \theta = 1 - P _ { \theta } ( X _ { i } = 0 )$ ; confidence 0.640 |
Revision as of 19:23, 3 May 2020
List
1. ; $f , g \in C [ \mathbf{R} ]$ ; confidence 0.643
2. ; $o : 1 \rightarrow N$ ; confidence 0.643
3. ; $r ( K _ { X } + B )$ ; confidence 0.643
4. ; $1$ ; confidence 0.643
5. ; $\widetilde { F B }$ ; confidence 0.643
6. ; $\pi _ { 0 } : N _ { 0 } \rightarrow N$ ; confidence 0.643
7. ; $x \in A ^ { + }$ ; confidence 0.643
8. ; $\{ A _ { i } \} _ { i = 1 } ^ { k }$ ; confidence 0.642
9. ; $\operatorname{cat}_{\mathbf{R} P ^ { n }} \mathbf{R}P^n \geq n + 1$ ; confidence 0.642
10. ; $\sigma _ { 1 } , \ldots , \sigma _ { t }$ ; confidence 0.642
11. ; $C ( S \times T )$ ; confidence 0.642
12. ; $F ( x , y ) = a p _ { 1 } ^ { z _ { 1 } } \dots p _ { s } ^ { z _ { s } }$ ; confidence 0.642
13. ; $\sqrt { 1 - x ^ { 2 } } w ( x ) > 0$ ; confidence 0.642
14. ; $S = \frac { 1 } { n - 1 } \sum _ { i = 1 } ^ { n } ( X _ { i } - X ) ( X _ { i } - X ) ^ { \prime },$ ; confidence 0.642
15. ; $\phi_j$ ; confidence 0.642
16. ; $\langle [ A ] , \phi \rangle = \int _ { \operatorname { reg } A } \phi.$ ; confidence 0.642
17. ; $s \times p$ ; confidence 0.642
18. ; $l_2$ ; confidence 0.642
19. ; $F _ { \sigma } \in \widetilde { O } ( ( \Omega + \Gamma _ { \sigma } ) \cap U ).$ ; confidence 0.642
20. ; $N _ { \epsilon } ( C )$ ; confidence 0.642
21. ; $X \times Y$ ; confidence 0.642
22. ; $Q \in [ \alpha , b ]$ ; confidence 0.642
23. ; $f _ { 1 } : = x _ { 1 } ^ { d },$ ; confidence 0.642
24. ; $t \searrow 0$ ; confidence 0.641
25. ; $E ^ { TF } ( N ) = \operatorname { inf } \{ \mathcal{E} ( \rho ) : \rho \in L ^ { 5 / 3 } , \int \rho = N , \rho \geq 0 \},$ ; confidence 0.641
26. ; $L _ { C } ^ { p } ( G )$ ; confidence 0.641
27. ; $\pi _ { n } ( X ; A , B , * ) = \pi _ { n - 1 } ( \Omega ( X ; A , B ) , * ).$ ; confidence 0.641
28. ; $\mathfrak{p} \subset \mathfrak{a}$ ; confidence 0.641
29. ; $h = 1$ ; confidence 0.641
30. ; $f \rightarrow \frac { 1 } { 2 \pi } \int _ { 0 } ^ { 2 \pi } \operatorname { Re } \frac { e ^ { i t } + z } { e ^ { t t } - z } f ( e ^ { i t } ) d t,$ ; confidence 0.641
31. ; $e \leq x$ ; confidence 0.641
32. ; $x \in \Lambda$ ; confidence 0.641
33. ; $\| u_f \| \leq \| f \| / c$ ; confidence 0.641
34. ; $E ^ { k } = M \times F \times F ^ { ( 1 ) } \times \ldots F ^ { ( k ) }$ ; confidence 0.641
35. ; $E _ { \theta } ( N ) = \frac { P _ { \theta } ( S _ { N } = K ) K - P _ { \theta } ( S _ { N } = - J ) J } { 2 \theta - 1 }.$ ; confidence 0.641
36. ; $U : \mathcal{C} \rightarrow \operatorname{Set}$ ; confidence 0.641
37. ; $s = 1 + p _ { 1 } / r + \ldots + p _ { 1 } \ldots p _ { k - 1 } / r ^ { k - 1 }$ ; confidence 0.641
38. ; $y _ { 0 } = g ( x _ { 0 } )$ ; confidence 0.641
39. ; $A = \operatorname { diag } ( \lambda _ { 1 } , \dots , \lambda _ { n } )$ ; confidence 0.641
40. ; $d _ { 2 } ( \theta _ { 2 } ^ { j } )$ ; confidence 0.640
41. ; $a \leftrightarrow b a b ^ { - 1 }$ ; confidence 0.640
42. ; $\phi _ { p }$ ; confidence 0.640
43. ; $( \mathbf{R} _ { + } \backslash \{ 0 \} , \times , \leq )$ ; confidence 0.640
44. ; $\in \bigotimes \square ^ { p + q + 1 } \mathcal{E}$ ; confidence 0.640
45. ; $R \subseteq A ^ { n }$ ; confidence 0.640
46. ; $\text{E} _ { P } ( d _ { 0 } ) = 0$ ; confidence 0.640
47. ; $( C ) \int _ { A } f d m = ( C ) \int f \cdot \chi _ { A } d m$ ; confidence 0.640
48. ; $0 \leq t < \infty$ ; confidence 0.640
49. ; $\widehat { B^* } $ ; confidence 0.640
50. ; $E _ { \theta } ( X _ { i } ) = P _ { \theta } ( X _ { i } = 1 ) = \theta = 1 - P _ { \theta } ( X _ { i } = 0 )$ ; confidence 0.640
51. ; $f ^ { em } = q _ { f } E + \frac { 1 } { c } J \times B + ( \nabla E ) P + ( \nabla B ) M +$ ; confidence 0.640
52. ; $( W , V ) = - \operatorname { Re } ( \eta ( W ) d g ( V ) )$ ; confidence 0.640
53. ; $\alpha , b \in \Omega$ ; confidence 0.640
54. ; $x \in Z$ ; confidence 0.640
55. ; $f _ { t , s }$ ; confidence 0.640
56. ; $R = \sum _ { s = 1 } ^ { n } a _ { s } \otimes b _ { s } \in A \otimes _ { k } A$ ; confidence 0.640
57. ; $\overline { m } = \{ m _ { x } \} _ { x = 0 } ^ { \infty }$ ; confidence 0.639
58. ; $S ^ { \lambda }$ ; confidence 0.639
59. ; $S A T$ ; confidence 0.639
60. ; $K$ ; confidence 0.639
61. ; $\lambda \in \Delta$ ; confidence 0.639
62. ; $\pi \in S _ { y }$ ; confidence 0.639
63. ; $T + T = I = T T +$ ; confidence 0.639
64. ; $U _ { n + 1 } ( x ) = \sum _ { j = 0 } ^ { [ n / 2 ] } \frac { ( n - j ) ! } { j ! ( n - 2 j ) ! } x ^ { n - 2 j } , n = 0,1$ ; confidence 0.639
65. ; $\operatorname { Re } h ( z ) > 0$ ; confidence 0.639
66. ; $\langle A \rangle _ { T } = Z ^ { - 1 } \operatorname { Tr } [ \operatorname { exp } ( - \frac { H } { k _ { B } T } ) A ]$ ; confidence 0.639
67. ; $( X _ { n } ) _ { n \in Z }$ ; confidence 0.639
68. ; $Z ( C )$ ; confidence 0.639
69. ; $f _ { 1 } , \ldots , f _ { d }$ ; confidence 0.639
70. ; $V _ { ( n ) } < \infty$ ; confidence 0.639
71. ; $Z ]$ ; confidence 0.638
72. ; $( b )$ ; confidence 0.638
73. ; $\operatorname { gcd } ( p _ { 1 } \ldots p _ { k } , q ) = 1$ ; confidence 0.638
74. ; $U _ { t } ^ { j } = u _ { j } ( B _ { \operatorname { min } } ( t , \tau ) )$ ; confidence 0.638
75. ; $Y ( T _ { A } ) = \{ N _ { B } : \operatorname { Tor } _ { 1 } ^ { B } ( N , T ) = 0 \}$ ; confidence 0.638
76. ; $\{ 0 , \pm x _ { 1 } , \ldots , \pm x _ { k } \}$ ; confidence 0.638
77. ; $f _ { n } \in H ^ { \otimes n }$ ; confidence 0.638
78. ; $K Q$ ; confidence 0.638
79. ; $H _ { Z } ( t )$ ; confidence 0.638
80. ; $v ( x , \alpha , k ) = A ( \alpha ^ { \prime } , \alpha , k ) \frac { e ^ { i k \gamma } } { r } + o ( \frac { 1 } { r } )$ ; confidence 0.638
81. ; $k S _ { y }$ ; confidence 0.638
82. ; $j = 1 , \ldots , n$ ; confidence 0.638
83. ; $\sum _ { \nu = 1 } ^ { x } \alpha _ { \nu } \leq 2$ ; confidence 0.637
84. ; $c j ( \lambda )$ ; confidence 0.637
85. ; $S = \{ p _ { 1 } , \dots , p _ { s } \} \cup \{ p :$ ; confidence 0.637
86. ; $w = ( w _ { 1 } , \dots , w _ { x } )$ ; confidence 0.637
87. ; $\sum _ { n = 1 } ^ { \infty } y _ { n }$ ; confidence 0.637
88. ; $p ( X ) \approx \overline { E } \square ^ { q } ( S ^ { n } \backslash X ) , p + q = n - 1$ ; confidence 0.637
89. ; $N ( s )$ ; confidence 0.637
90. ; $X ( p ) = \operatorname { Re } \int _ { p _ { 0 } } ^ { p } ( \omega _ { 1 } , \ldots , \omega _ { n } )$ ; confidence 0.637
91. ; $G _ { i } + 1$ ; confidence 0.637
92. ; $q 2 ( x )$ ; confidence 0.637
93. ; $\operatorname { ker } ( \gamma \circ \alpha ^ { \prime } ) \subset \mathfrak { g }$ ; confidence 0.637
94. ; $d \circ e = f$ ; confidence 0.637
95. ; $t$ ; confidence 0.637
96. ; $z _ { i } = 1 , \dots , p - 1$ ; confidence 0.637
97. ; $e _ { 1 } , \dots , e _ { s }$ ; confidence 0.637
98. ; $\operatorname { max } _ { k = m + 1 , \ldots , m + n } | g ( k ) | \geq$ ; confidence 0.637
99. ; $7 + 2$ ; confidence 0.637
100. ; $h ^ { i } ( K _ { X } + j L - \sum _ { k = 1 } ^ { r } [ \frac { j \alpha _ { k } } { N } ] D _ { k } ) = 0$ ; confidence 0.637
101. ; $\alpha , b \in A _ { k }$ ; confidence 0.636
102. ; $S _ { k } = \left( \begin{array} { c } { n } \\ { k } \end{array} \right) \frac { ( n - k ) ! } { n ! }$ ; confidence 0.636
103. ; $\alpha \in Z \alpha _ { 1 } + Z \alpha _ { 2 } +$ ; confidence 0.636
104. ; $C _ { B _ { 2 } } ( L _ { n } )$ ; confidence 0.636
105. ; $\beta ( \phi , \rho ) ( t ) = \int _ { N } u _ { \Phi } \rho$ ; confidence 0.636
106. ; $u ^ { x } = 1$ ; confidence 0.636
107. ; $\nabla _ { Z } R$ ; confidence 0.636
108. ; $V _ { \text { simp } } ( K _ { p } )$ ; confidence 0.636
109. ; $Z ( g ^ { \alpha } h ^ { c } , g ^ { b } h ^ { d } ; z ) = \alpha Z ( g h ; \frac { a z + b } { c z + d } )$ ; confidence 0.636
110. ; $M _ { z }$ ; confidence 0.636
111. ; $a ^ { [ N ] } ( z ) \equiv 1$ ; confidence 0.636
112. ; $v \notin [ 0,1$ ; confidence 0.636
113. ; $\alpha _ { 2 } = 1$ ; confidence 0.636
114. ; $\ddot { x } - \mu ( 1 - x ^ { 2 } ) \dot { x } + x = 0 , \quad \mu = \text { const } > 0 , \quad \dot { x } ( t ) \equiv \frac { d x } { d t }$ ; confidence 0.636
115. ; $Z \sim N _ { p } ( 0 , l )$ ; confidence 0.636
116. ; $x , y , z \in E _ { + }$ ; confidence 0.636
117. ; $L _ { w } ( X , Y )$ ; confidence 0.636
118. ; $D _ { 1 }$ ; confidence 0.636
119. ; $c - 2 \operatorname { deg } l$ ; confidence 0.636
120. ; $i = 1 , \ldots , 4$ ; confidence 0.636
121. ; $S _ { f } ( a _ { 0 } )$ ; confidence 0.636
122. ; $f | _ { K }$ ; confidence 0.635
123. ; $( \alpha _ { 1 } \cup \gamma , \alpha _ { 2 } , \dots , \alpha _ { q } )$ ; confidence 0.635
124. ; $E [ C ]$ ; confidence 0.635
125. ; $C _ { 1 }$ ; confidence 0.635
126. ; $V ( M )$ ; confidence 0.635
127. ; $\left( \begin{array} { c c c c } { 1 } & { 2 } & { 3 } & { 4 } \\ { 5 } & { 6 } & { 7 } & { \square } \\ { 8 } & { \square } & { \square } & { \square } \\ { 9 } & { \square } & { \square } & { \square } \end{array} \right) = \left( \begin{array} { c c c c } { 4 } & { 2 } & { 1 } & { 3 } \\ { 6 } & { 5 } & { 7 } & { \square } \\ { 8 } & { \square } & { \square } & { \square } \\ { 9 } & { \square } & { \square } & { \square } \end{array} \right) \neq$ ; confidence 0.635
128. ; $E _ { 0 }$ ; confidence 0.635
129. ; $A x$ ; confidence 0.635
130. ; $X = G \wedge H$ ; confidence 0.635
131. ; $X \times X$ ; confidence 0.635
132. ; $A ( D )$ ; confidence 0.635
133. ; $f ^ { em } = \operatorname { div } t ^ { em } - \frac { \partial G ^ { em } } { \partial t }$ ; confidence 0.635
134. ; $z \in D$ ; confidence 0.635
135. ; $H ^ { 2 r + 1 } ( M , C )$ ; confidence 0.635
136. ; $\overline { \delta }$ ; confidence 0.635
137. ; $P \equiv \left( \begin{array} { c c } { \operatorname { exp } ( \frac { J + H } { k _ { B } T } ) } & { \operatorname { exp } ( \frac { - J } { k _ { B } T } ) } \\ { \operatorname { exp } ( \frac { - J } { k _ { B } T } ) } & { \operatorname { exp } ( \frac { J - H } { k _ { B } T } ) } \end{array} \right)$ ; confidence 0.635
138. ; $V _ { 0 }$ ; confidence 0.635
139. ; $\int _ { A } \operatorname { exp } ( h ^ { \prime } \Delta _ { N } ^ { * } ( \theta ) ) d P _ { n , \theta }$ ; confidence 0.635
140. ; $T ^ { k }$ ; confidence 0.635
141. ; $P _ { K } ( 1,0 ) = \alpha _ { 2 }$ ; confidence 0.635
142. ; $D$ ; confidence 0.635
143. ; $\operatorname { max } _ { k = 1 , \ldots , n } ( \frac { 1 } { n } | s _ { k } | ) ^ { 1 / k } > \frac { 1 } { 5 } > \frac { 1 } { 2 + \sqrt { 8 } }$ ; confidence 0.635
144. ; $\rho ( x ) = \sum _ { j = 1 } ^ { N } | u _ { j } ( x ) | ^ { 2 }$ ; confidence 0.635
145. ; $P _ { 0 } \in P$ ; confidence 0.635
146. ; $M _ { n } = \{ P ( X , Y ) = \sum _ { \nu = 0 } ^ { n } a _ { \nu } X ^ { \nu } Y ^ { n - \nu } : a _ { \nu } \in Q \}$ ; confidence 0.635
147. ; $\sigma _ { k - 1 } ( n ) = \sum _ { 0 < d | n } d ^ { k - 1 }$ ; confidence 0.635
148. ; $\operatorname { lim } _ { \tau \rightarrow \infty } \frac { \operatorname { det } ( I + W _ { \tau } ( k ) ) } { G ( a ) ^ { \tau } } = E ( a )$ ; confidence 0.634
149. ; $\| y - X b \| ^ { 2 }$ ; confidence 0.634
150. ; $\operatorname { cap } ( E ) = \operatorname { exp } ( - \operatorname { sup } _ { z \in C ^ { n } } \rho _ { L _ { E } } ( z ) )$ ; confidence 0.634
151. ; $H ^ { n + 1 } ( X , A ; G ) \rightarrow$ ; confidence 0.634
152. ; $E ^ { TF } ( N )$ ; confidence 0.634
153. ; $\frac { 1 } { \beta _ { p } ( a , b ) } | V | ^ { \alpha - ( p + 1 ) / 2 } | I _ { p } + V | ^ { - ( \alpha + b ) }$ ; confidence 0.634
154. ; $\Gamma$ ; confidence 0.634
155. ; $F ( t ) = \int _ { t } ^ { + \infty } p _ { 0 } ( \alpha - t ) \frac { \Pi ( \alpha ) } { \Pi ( \alpha - t ) } d \alpha$ ; confidence 0.634
156. ; $B _ { r _ { 1 } } , B _ { r _ { 2 } }$ ; confidence 0.634
157. ; $Y \in \mathfrak { X } ( M )$ ; confidence 0.634
158. ; $M < d$ ; confidence 0.634
159. ; $G$ ; confidence 0.634
160. ; $k = 1 / 2$ ; confidence 0.633
161. ; $\operatorname { spec } ( M , \Delta ^ { ( 0 ) } ) , \ldots , \operatorname { spec } ( M , \Delta ^ { ( d i m M ) } )$ ; confidence 0.633
162. ; $QS ( T ) = \cup _ { M \geq 1 } M$ ; confidence 0.633
163. ; $E _ { y }$ ; confidence 0.633
164. ; $z \in ( 1 , \dots , M )$ ; confidence 0.633
165. ; $\psi ( \gamma ) = \frac { 2 } { \pi ^ { 2 } \gamma } + O ( \frac { 1 } { \gamma ^ { 3 } } ) \text { as } \gamma \rightarrow + \infty$ ; confidence 0.633
166. ; $S ^ { 3 } / \Gamma$ ; confidence 0.633
167. ; $\{ l _ { n } \} _ { n = 0 } ^ { \infty }$ ; confidence 0.633
168. ; $Q ^ { B }$ ; confidence 0.633
169. ; $A b ^ { Z C }$ ; confidence 0.633
170. ; $Z [ v ^ { \pm 1 } , z ^ { \pm 1 } ]$ ; confidence 0.633
171. ; $y _ { t } ^ { ( l ) }$ ; confidence 0.633
172. ; $H$ ; confidence 0.632
173. ; $\alpha \wedge \beta ^ { x } \neq 0$ ; confidence 0.632
174. ; $R _ { 1414 } = \alpha _ { 1 } , R _ { 2323 } = \alpha _ { 1 } , R _ { 3434 } = \alpha _ { 2 } , R _ { 1234 } = \alpha _ { 1 } , R _ { 1324 } = - \alpha _ { 1 } , R _ { 1423 } = \alpha _ { 2 }$ ; confidence 0.632
175. ; $E ( \varphi , \psi ) = \{ \epsilon _ { i } ( \varphi , \psi ) : i \in I \}$ ; confidence 0.632
176. ; $R _ { n } = I - Q _ { n }$ ; confidence 0.632
177. ; $K \subset C$ ; confidence 0.632
178. ; $m$ ; confidence 0.632
179. ; $g ( z ) = r ( z ) + \sum _ { i = 1 } ^ { \infty } s _ { 2 m + i } z ^ { - ( 2 m + i ) }$ ; confidence 0.632
180. ; $V _ { \pm }$ ; confidence 0.632
181. ; $f = ( f _ { 1 } , \ldots , f _ { M } )$ ; confidence 0.632
182. ; $C$ ; confidence 0.632
183. ; $\bigwedge _ { j = 1 } ^ { m } \frac { d z _ { j } - d z _ { j } ^ { \prime } } { z _ { j } - z _ { j } ^ { \prime } }$ ; confidence 0.632
184. ; $x _ { 0 } > 0$ ; confidence 0.632
185. ; $P _ { y }$ ; confidence 0.632
186. ; $C \in K$ ; confidence 0.632
187. ; $T _ { 0 }$ ; confidence 0.632
188. ; $\Sigma _ { P } = \{ ( x , \xi ) \in \Omega \times ( R ^ { n } \backslash \{ 0 \} ) : p _ { m } ( x , \xi ) = 0 \}$ ; confidence 0.632
189. ; $D _ { x } ^ { \alpha } = D _ { x _ { 1 } } ^ { \alpha _ { 1 } } \ldots D _ { x _ { n } } ^ { \alpha _ { n } }$ ; confidence 0.632
190. ; $f _ { j k l } = \frac { - i } { 4 } \operatorname { Tr } [ ( \lambda _ { j } \lambda _ { k } - \lambda _ { k } \lambda _ { j } ) \lambda _ { l } ]$ ; confidence 0.632
191. ; $W ^ { X }$ ; confidence 0.632
192. ; $\frac { \partial u ( t , x ) } { \partial t } + \frac { 1 } { 2 } \| d _ { x } u ( t , x ) \| ^ { 2 } = 0 , \quad ( t , x ) \in ( 0 , T ) \times H$ ; confidence 0.632
193. ; $A ( X )$ ; confidence 0.632
194. ; $( \alpha _ { 1 } , \dots , \alpha _ { n } )$ ; confidence 0.632
195. ; $( A , [ , ] )$ ; confidence 0.632
196. ; $\operatorname { lim } _ { n \rightarrow \infty } \frac { T _ { x } - S } { S _ { x } - S } = 0$ ; confidence 0.632
197. ; $\partial _ { S }$ ; confidence 0.631
198. ; $T \in GL ( n , R )$ ; confidence 0.631
199. ; $E \varepsilon _ { t } \varepsilon _ { s } ^ { \prime } = \delta _ { s t } \Sigma$ ; confidence 0.631
200. ; $B ( x _ { 0 } , r ) = \{ x \in R ^ { n } : | x - x _ { 0 } | < r \}$ ; confidence 0.631
201. ; $F _ { K } \circ \Phi$ ; confidence 0.631
202. ; $| x | | y | \bigwedge | y | ^ { 2 } | x | ^ { 2 } = | x | | y |$ ; confidence 0.631
203. ; $E _ { avg } ( \mu , m ) = \int | \epsilon ( p , m ) | d \mu ( p )$ ; confidence 0.631
204. ; $\pi ( a ) M ^ { U } ( [ t , \infty ) ) \subseteq M ^ { U } ( [ t + s , \infty ) )$ ; confidence 0.631
205. ; $( 1 _ { m } - k ^ { 2 } ) f _ { m } = 0$ ; confidence 0.631
206. ; $g _ { j } \in L ^ { 2 } ( [ 0,1 ] )$ ; confidence 0.631
207. ; $E ( Z _ { 3 } ) = 0$ ; confidence 0.631
208. ; $+ O ( \frac { ( \operatorname { log } n ) ^ { 1 / 2 } ( \operatorname { log } \operatorname { log } n ) ^ { 1 / 4 } } { n ^ { 3 / 4 } } )$ ; confidence 0.631
209. ; $\gamma j = 0$ ; confidence 0.631
210. ; $\{ F _ { n } \} _ { n = 0 } ^ { \infty }$ ; confidence 0.631
211. ; $B U _ { q } ( g )$ ; confidence 0.631
212. ; $t _ { \operatorname { min } } < t _ { 1 } < \ldots < t _ { m } < t _ { \operatorname { max } }$ ; confidence 0.631
213. ; $\sigma _ { \pi } ( A , X ) = \sigma _ { \delta } ( A , X ) = \sigma _ { T } ( A , X )$ ; confidence 0.631
214. ; $( g ) = \operatorname { Der } ( g )$ ; confidence 0.631
215. ; $P y$ ; confidence 0.630
216. ; $N ( X )$ ; confidence 0.630
217. ; $1 , \dots , n$ ; confidence 0.630
218. ; $P _ { \Omega } ( , \xi )$ ; confidence 0.630
219. ; $D _ { 1 } \subset R ^ { 2 }$ ; confidence 0.630
220. ; $\zeta _ { \lambda } ^ { \pi }$ ; confidence 0.630
221. ; $A \in S$ ; confidence 0.630
222. ; $L _ { i } \in \Omega ^ { l } ( N ; T N )$ ; confidence 0.630
223. ; $C _ { 1 } N ^ { ( n - 1 ) / 2 } \leq \| S _ { N } \| \leq C _ { 2 } N ^ { ( n - 1 ) / 2 }$ ; confidence 0.630
224. ; $< a$ ; confidence 0.630
225. ; $\{ r _ { 2 } ( A ) \} _ { i = 1 } ^ { n }$ ; confidence 0.630
226. ; $m _ { s } = \operatorname { lim } _ { H \rightarrow 0 } m ( T , H ) > 0$ ; confidence 0.630
227. ; $K I = K ( I , \preceq )$ ; confidence 0.630
228. ; $\sum | c$ ; confidence 0.630
229. ; $( L _ { K } \omega ) ( X _ { 1 } , \dots , X _ { k + 1 } ) =$ ; confidence 0.630
230. ; $A _ { Q }$ ; confidence 0.630
231. ; $1$ ; confidence 0.630
232. ; $a + b \in F$ ; confidence 0.629
233. ; $r ( 1 + 2.78 + \lambda )$ ; confidence 0.629
234. ; $( u = v ) \in S$ ; confidence 0.629
235. ; $R$ ; confidence 0.629
236. ; $\overline { R } = \sum _ { i = 1 } ^ { n } R _ { i } / n = ( n + 1 ) / 2 = \sum _ { i = 1 } ^ { n } S _ { i } / n = \overline { S }$ ; confidence 0.629
237. ; $\overline { H } \square ^ { x }$ ; confidence 0.629
238. ; $G \subset \operatorname { GL } ( V )$ ; confidence 0.629
239. ; $H ^ { n } ( S ^ { n } )$ ; confidence 0.629
240. ; $\tilde { D } = \{ \alpha \in G : \alpha D \alpha ^ { - 1 } \text { is }$ ; confidence 0.629
241. ; $p _ { m } ( z ) = m ! \sum _ { 0 \leq n \leq m - 1 } b _ { m } ( n + 1 ) z ^ { n } , \quad z \in C$ ; confidence 0.629
242. ; $c _ { 1 } ( M ) _ { R } > 0$ ; confidence 0.629
243. ; $x , y , z _ { 1 } , \dots , z _ { s } \in Z$ ; confidence 0.629
244. ; $X ^ { 2 x + 1 }$ ; confidence 0.629
245. ; $k = i k$ ; confidence 0.629
246. ; $H _ { y }$ ; confidence 0.629
247. ; $\Gamma = \operatorname { Gal } ( K / k )$ ; confidence 0.628
248. ; $x = ( x , \ldots , x )$ ; confidence 0.628
249. ; $q : Z ^ { l } \rightarrow Z$ ; confidence 0.628
250. ; $\operatorname { su } ( 2 )$ ; confidence 0.628
251. ; $y _ { x } \geq 0$ ; confidence 0.628
252. ; $R = V _ { 33 } ^ { - 1 } V _ { 32 }$ ; confidence 0.628
253. ; $\rho = ( 1 / 2 ) \sum _ { \alpha \in \Delta ^ { + } } \alpha$ ; confidence 0.628
254. ; $TD [ r , s ]$ ; confidence 0.628
255. ; $\| W _ { k } \| = \| F k \| _ { L } \infty$ ; confidence 0.628
256. ; $2$ ; confidence 0.628
257. ; $f \in A$ ; confidence 0.628
258. ; $n ^ { \text { th } }$ ; confidence 0.628
259. ; $A X B + C \sim E _ { q , n } ( A M B + C , ( A \Sigma A ^ { \prime } ) \otimes ( B ^ { \prime } \Phi B ) , \psi )$ ; confidence 0.628
260. ; $x . D _ { x }$ ; confidence 0.628
261. ; $x \notin - \Delta ^ { \circ }$ ; confidence 0.628
262. ; $\partial _ { t } \eta ( u ) + \operatorname { div } _ { X } G ( u ) \leq 0$ ; confidence 0.627
263. ; $\operatorname { St } _ { G } ( u )$ ; confidence 0.627
264. ; $\frac { 1 } { ( 2 \pi ) ^ { n p / 2 } } | \Sigma | ^ { - n / 2 } \operatorname { etr } \{ - \frac { 1 } { 2 } \Sigma ^ { - 1 } X X ^ { \prime } \} , X \in R ^ { p \times n }$ ; confidence 0.627
265. ; $3 + 2$ ; confidence 0.627
266. ; $P \subset X$ ; confidence 0.627
267. ; $x _ { 0 } \in F ( x _ { 0 } )$ ; confidence 0.627
268. ; $K \subset C ^ { n + 1 }$ ; confidence 0.627
269. ; $W = p ^ { n + 1 } - q _ { 1 } p ^ { n - 1 } - \ldots - q _ { n }$ ; confidence 0.627
270. ; $0 = ( \delta ( x ) x ) \operatorname { vp } \frac { 1 } { x } \neq \delta ( x ) ( x \vee p \frac { 1 } { x } ) = \delta ( x )$ ; confidence 0.627
271. ; $\sigma _ { \delta }$ ; confidence 0.627
272. ; $D _ { j }$ ; confidence 0.627
273. ; $\lambda = ( \lambda _ { 1 } , \dots , \lambda _ { s } , \dots , \lambda _ { t } )$ ; confidence 0.627
274. ; $\Gamma \subset \Omega \times ( R ^ { n } \backslash \{ 0 \} )$ ; confidence 0.627
275. ; $c _ { t } ^ { \prime } > c _ { t }$ ; confidence 0.627
276. ; $a _ { n } i = ( a _ { n } )$ ; confidence 0.627
277. ; $G \nmid G$ ; confidence 0.627
278. ; $l ^ { 2 } ( \Gamma )$ ; confidence 0.627
279. ; $i m + 1$ ; confidence 0.627
280. ; $\rho \otimes x$ ; confidence 0.627
281. ; $S _ { i } > 0 , i = 1 , \dots , r$ ; confidence 0.627
282. ; $y _ { j } < y _ { k }$ ; confidence 0.627
283. ; $= \pi ^ { 2 } \sqrt { \frac { \pi } { 2 } } \int _ { 0 } ^ { \infty } \tau \frac { \operatorname { sinh } ( \pi \tau ) } { \operatorname { cosh } ^ { 3 } ( \pi \tau ) } P _ { i \tau - 1 / 2 } ( x ) F ( \tau ) G ( \tau ) d \tau$ ; confidence 0.627
284. ; $f ( k - 1 )$ ; confidence 0.627
285. ; $p _ { i } ( \theta ) = P \{ X _ { i } \in ( x _ { i } - 1 , x _ { i } ] \} > 0$ ; confidence 0.626
286. ; $k ( X ) = r$ ; confidence 0.626
287. ; $\rho : G / Q \rightarrow GL ( M )$ ; confidence 0.626
288. ; $\rho _ { atom } ^ { TF } ( x , N = Z , Z ) \sim \gamma ^ { 3 } ( \frac { 3 } { \pi } ) ^ { 3 } | x | ^ { - 6 }$ ; confidence 0.626
289. ; $\forall x \forall y \exists z \forall v ( v \in z \leftrightarrow ( v = x \vee v = y ) )$ ; confidence 0.626
290. ; $Ch ( [ a ] ) T ( M )$ ; confidence 0.626
291. ; $i = 1 , \ldots , k$ ; confidence 0.626
292. ; $CL ( X )$ ; confidence 0.626
293. ; $( q _ { 1 } , \dots , q _ { m } )$ ; confidence 0.626
294. ; $B + A$ ; confidence 0.626
295. ; $A \Theta B$ ; confidence 0.626
296. ; $s = ( s _ { 1 } , \dots , s _ { n } ) : \partial D \times D \rightarrow C ^ { n }$ ; confidence 0.626
297. ; $G _ { X } ( X - Y \leq \rho ^ { 2 } \Rightarrow G _ { Y } \leq C G _ { X }$ ; confidence 0.626
298. ; $F _ { j k } =$ ; confidence 0.626
299. ; $M$ ; confidence 0.626
300. ; $U _ { q } ( \mathfrak { g } )$ ; confidence 0.626
Maximilian Janisch/latexlist/latex/NoNroff/50. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Maximilian_Janisch/latexlist/latex/NoNroff/50&oldid=45696