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hyunjongkimmath
/
notation_linking_rag_sentence_transformers_all_MiniLM_L6_v2

Sentence Similarity
sentence-transformers
Safetensors
bert
feature-extraction
Generated from Trainer
dataset_size:264888
loss:CosineSimilarityLoss
Eval Results (legacy)
text-embeddings-inference
Model card Files Files and versions
xet
Community

Instructions to use hyunjongkimmath/notation_linking_rag_sentence_transformers_all_MiniLM_L6_v2 with libraries, inference providers, notebooks, and local apps. Follow these links to get started.

  • Libraries
  • sentence-transformers

    How to use hyunjongkimmath/notation_linking_rag_sentence_transformers_all_MiniLM_L6_v2 with sentence-transformers:

    from sentence_transformers import SentenceTransformer
    
    model = SentenceTransformer("hyunjongkimmath/notation_linking_rag_sentence_transformers_all_MiniLM_L6_v2")
    
    sentences = [
        "latex_in_original_or_summarized: K(M, n)\n\n[SEP]\n\nsummarized: $K(M, n)$\n\n[SEP]\n\nmain_note_content: Chain complexes and  spaces.   [59], that for  simplicial sheaf   $\\text{X}$ we denote by $C_{*}(\\mathcal{X})$ the (normalized) chain complex  $C_{*}(\\mathcal{A}$  associated to the   sheaf  abelian groups   $\\mathbb{X}$. This  defines a functor\n\n$$  C_{*}: \\Delta^{o p} S h v_{N i s}\\left(S m_{k}\\right)  C_{*}(\\text{A} b(k))  $$$ ^f7eebc\n\nwhich is well  (see $[44,59]$  instance) to have a right adjoint\n\n6.2 \\mathbb{A}^{1}$-Derived Category   Spaces\n161\n\n$$  K: C_{*}(\\mathcal{A} b(k)) \\rightarrow \\phi^{o p} S h v_{N i s}\\left(S   $$ \n\n\ncalled the  space \n\nFor an abelian  $M   b(k)$ and an integer $n$ we define the pointed simplicial sheaf $K(M, n)$ (see [59, page 56])   $K$ to the shifted complex $M[n]$,  the complex $M$ placed in degree 0 . If n< 0, the space $K(M, n)$ is a point. If $n \\geq 0$ then $K(M, n)$ has only one non-trivial  sheaf which is the  and which is canonically isomorphic to $M$. More generally, for a chain  $C_{*}$,   $K C_{*}$ has   homotopy sheaf 0  $n< 0$, and the $n$-th homology sheaf $H_{n}\\left(C_{*}\\right)$ for $n \\geq 0$.\n\nIt is clear that $C_{*}: \\Delta^{o p} S h  i s}\\left(S m_{k}\\right) \\rightarrow  b(k))$ sends simplicial weak equivalences to quasi-isomorphisms and $K: C_{*}(A b(k)) \\rightarrow \\Delta^{o p} S h v_{N i s}\\left(S m_{k}\\right)$ maps quasi-isomorphisms to simplicial  equivalences. If $C_{*}$  fibrant, it follows that $K\\left(C_{*}\\right)$ is simplicially  Thus the two functors induce a pair of adjoint functors\n\n$$  C_{*}: \\mathcal{H}{s}(k) \\rightarrow D(\\mathcal{A} b(k))  $$ ^c4a825\n\n\n\n$$  K: D(\\mathrm{A} b(k)) \\rightarrow \\mathcal{H}_{s}(k)  $$ \n\nAs a consequence it is clear that   is an $\\mathscr{A}^{1}$-local complex,  space $K\\left(C_{*}\\right)$ is an $\\mathbb{A}^{1}$-local space. Thus $C_{}: \\mathbf{H}_{s}(k) \\rightarrow   maps $\\mathcal{A}^{1}$-weak  to $\\mathrm{A}^{1}$-quasi  and induces a functor\n\n    \\rightarrow D_{\\mathbb{A}^{1}}(A b(k))  $$ \n\nwhich in concrete terms, maps a space $\\operatorname{X}$ to the $\\mathbb{A}^{1}$-localization of $C_{*}(\\mathcal{X})$. We denote the latter by $C_{*}^{A^{1}}(\\mathbb{X})$ and call it the $\\mathbb{A}^{1}$-chain  of $\\mathcal{X}$.  functor $C_{*}^{\\operatorname{A}^{1}}: \\mathfrak{H}(k) \\rightarrow  b(k))$ admits as right adjoint the functor $K^{\\mathbb{A}^{1}}: D_{\\mathbb{A}^{1}}(\\mathcal{A} b(k)) \\rightarrow \\mathcal{H}(k)$ induced by $C_{*} \\mapsto K\\left(L_{\\mathbb{A}^{1}}\\left(C_{*}\\right)\\right)$. We  that for an $\\mathbb{A}^{1}$-local complex  the space $K\\left(C_{*}\\right)$ is automatically $\\mathbb{A}^{1}$-local and thus simplicially equivalent to the space \n\n\n[SEP]\n\nprocessed_content: the pointed simplicial  where $M$ \\in  b(k)$ and $n$ is  integer. It is defined by applying  to the  complex $M[n]$, of the complex    degree 0 .",
        "latex_in_original_or_summarized: \\gamma_1=(m_1,N_1,a_1)\n\n[SEP]\n\nsummarized: $\\gamma_1=(m_1,N_1,a_1)$\n\n[SEP]\n\nmain_note_content: \\begin{notation}\\label{Dep1}\nLet $\\gamma_1=(m_1,N_1,a_1)$,  $\\gamma_2=(m_2,N_2,a_2)$ be an ordered pair of \n(generalized) monodromy data which  hypothesis (A). Assume that $m_1|m_2$.\nSet $d:=m_2/m_1$ and $r:=\\gcd(m_1, a_1(N_1))$.  \nThen, \\eqref{Dep}  to \n$\\epsilon=d(r-1)$ and $g_3=dg_1+g_2+\\epsilon$.\nIn particular, $\\epsilon=0$ if and  if $r=1$. \n\\end{notation}\n\n\n[SEP]\n\nprocessed_content: ",
        "latex_in_original_or_summarized: \\langle u\\rangle  G W(F)\n\n[SEP]\n\nsummarized: $\\langle u\\rangle \\in G W(F)$\n\n[SEP]\n\nmain_note_content: Let us denote (in  characteristic) by $G W(F)$ the Grothendieck-Witt ring of isomorphism classes of non-degenerate symmetric bilinear forms [48]: this is the group completion of the commutative monoid of isomorphism classes of non-degenerate symmetric  forms for the direct sum.\n\nFor $u \\in F^{\\times}$, we denote by $\\langle u\\rangle  G W(F)$ the form on  vector space of rank one  given by $F^{2}  F,(x,  \\mapsto u x y .$ By the results of loc.   \\langle u\\rangle$ generate $G  as a group. The following Lemma is (essentially) [48, Lemma (1.1) Chap. IV]:\n\n\n[SEP]\n\nprocessed_content: ",
        "latex_in_original_or_summarized: $\\varepsilon_{\\infty}$\n\n[SEP]\n\nsummarized: $\\varepsilon_{\\infty}$\n\n[SEP]\n\nmain_note_content: To compute the genus of $X(\\kappa)$, further specialize to $\\Gamma_{1}=\\Gamma$ and $\\Gamma_{2}=$ $\\mathfrak{SL}_{2}(\\mathbb{Z}) . Let $y_{2}=\\mathrm{SL}_{2}(\\mathbb{Z}) i, y_{3}=\\mathrm{SL}_{2}(\\mathbb{Z}) \\mu_{3}$, and $y_{\\infty}=\\mathfrak{SL}_{2}(\\mathbb{Z}) \\infty$ be the elliptic point of period 2, the elliptic point of period 3, and the cusp of $X(1)=$ SL_{2}(\\mathbb{Z}) \\backslash \\mathcal{H}^{*} .$ Let $\\varepsilon_{2}$ and $\\varepsilon_{3}$ be the number of elliptic points of $\\Gamma$ in $f^{-1}\\left(y_{2}\\right)$$ and of^{-1}\\left(y_{3}\\right)$, i.e., the number of elliptic points of period 2 and 3 in $X(\\Gamma)$, and let $\\varepsilon_{\\infty}$ be the number of cusps of X(\\Gamma) .$ Then recalling that $d=\\operatorname{deg}(f)$ and letting $h=2$ or $h=3$, the formula for $d$ at the beginning of the section and then the formula for $e_{\\pi_{1}(\\tau)}$ at the nonelliptic points and the elliptic points over $\\mathrm{SL}_{2}(\\mathscr{Z}) y_{h}$ show that (Exercise 3.1.3(a))\n\n$$ d=\\sum_{x \\in f^{-1}\\left(y_{h}\\right)} e_{x}=h \\cdot\\left(\\left|f^{-1}\\left(y_{h}\\right)\\right|-\\varepsilon_{h}\\right)+1 \\cdot \\varepsilon_{h} $$\n\nand using these equalities twice gives\n$$ \\sum_{x \\in f^{-1}\\left(y_{h}\\right)}\\left(e_{x}-1\\right)=(h-1)\\left(\\left|f^{-1}\\left(y_{h}\\right)\\right|-\\varepsilon_{h}\\right)=\\frac{h-1}{h}\\left(d-\\varepsilon_{h}\\right) $$\n\n$68 \\quad 3$ Dimension Formulas\n\nAlso.\n$$ \\sum_{x \\in f^{-1}\\left(y_{\\infty}\\right)}\\left(e_{x}-1\\right)=d-\\varepsilon_{\\infty} $$\nSince $X(1)$ has genus 0, the Riemann-Hurwitz formula now shows\n\n\n[SEP]\n\nprocessed_content: "
    ]
    embeddings = model.encode(sentences)
    
    similarities = model.similarity(embeddings, embeddings)
    print(similarities.shape)
    # [4, 4]
  • Notebooks
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notation_linking_rag_sentence_transformers_all_MiniLM_L6_v2
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History: 2 commits
hyunjongkimmath's picture
hyunjongkimmath
Add new SentenceTransformer model.
ed1d903 verified over 1 year ago
  • 1_Pooling
    Add new SentenceTransformer model. over 1 year ago
  • .gitattributes
    1.52 kB
    initial commit over 1 year ago
  • README.md
    106 kB
    Add new SentenceTransformer model. over 1 year ago
  • config.json
    720 Bytes
    Add new SentenceTransformer model. over 1 year ago
  • config_sentence_transformers.json
    205 Bytes
    Add new SentenceTransformer model. over 1 year ago
  • model.safetensors
    90.9 MB
    xet
    Add new SentenceTransformer model. over 1 year ago
  • modules.json
    349 Bytes
    Add new SentenceTransformer model. over 1 year ago
  • sentence_bert_config.json
    53 Bytes
    Add new SentenceTransformer model. over 1 year ago
  • special_tokens_map.json
    695 Bytes
    Add new SentenceTransformer model. over 1 year ago
  • tokenizer.json
    712 kB
    Add new SentenceTransformer model. over 1 year ago
  • tokenizer_config.json
    1.46 kB
    Add new SentenceTransformer model. over 1 year ago
  • vocab.txt
    232 kB
    Add new SentenceTransformer model. over 1 year ago