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Journal articles on the topic 'Space interpretation'

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Published: 4 June 2021
Last updated: 6 February 2022

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1

R. Mukhametzyanova, Lily. "Neogothic Space Interpretation." HELIX 8, no. 1 (January 1, 2018): 2873–76. http://dx.doi.org/10.29042/2018-2873-2876.

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2

Ardenghi, Juan Sebastián, and Olimpia Lombardi. "The Modal-Hamiltonian Interpretation of Quantum Mechanics as a Kind of “Atomic” Interpretation." Physics Research International 2011 (October 30, 2011): 1–10. http://dx.doi.org/10.1155/2011/379604.

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Modal interpretations are non-collapse interpretations, where the quantum state of a system describes its possible properties rather than the properties that it actually possesses. Among them, the atomic modal interpretation (AMI) assumes the existence of a special set of disjoint systems that fixes the preferred factorization of the Hilbert space. The aim of this paper is to analyze the relationship between the AMI and our recently presented modal-hamiltonian interpretation (MHI), by showing that the MHI can be viewed as a kind of “atomic” interpretation in two different senses. On the one hand, the MHI provides a precise criterion for the preferred factorization of the Hilbert space into factors representing elemental systems. On the other hand, the MHI identifies the atomic systems that represent elemental particles on the basis of the Galilei group. Finally, we will show that the MHI also introduces a decomposition of the Hilbert space of any elemental system, which determines with precision what observables acquire definite actual values.
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3

Baiasu, Sorin. "Space, Time and Mind-Dependence." Kantian Review 16, no. 2 (June 16, 2011): 175–90. http://dx.doi.org/10.1017/s1369415411000045.

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AbstractThe interpretation of Kant's Critical philosophy as a version of traditional idealism has a long history. In spite of Kant's and his commentators’ various attempts to distinguish between traditional and transcendental idealism, his philosophy continues to be construed as committed (whether explicitly or implicitly and whether consistently or inconsistently) to various features usually associated with the traditional idealist project. As a result, most often, the accusation is that his Critical philosophy makes too strong metaphysical and epistemological claims.In his The Revolutionary Kant, Graham Bird engages in a systematic and thorough evaluation of the traditionalist interpretation, as part of perhaps the most comprehensive and compelling defence of a revolutionary reading of Kant's thought. In the third part of this special issue, the exchanges between, on the one hand, Graham Bird and, on the other, Gary Banham, Gordon Brittan, Manfred Kuehn, Adrian Moore and Kenneth Westphal focus on specific aspects of Bird's interpretation of Kant's first Critique. More exactly, the emphasis is on specific aspects of Bird's interpretation of the Introduction, Analytic of Principles and Transcendental Dialectic of Kant's first Critique.The second part of the special issue is devoted to discussions of particular topics in Bird's construal of the remaining significant parts of the first Critique, namely, of the Transcendental Aesthetic and the Analytic of Concepts. Written by Sorin Baiasu and Michelle Grier, these articles examine specific issues in these two remaining parts of the Critique, from the perspective of the debate between the traditionalist and revolutionary interpretation. The special issue begins with an Introduction by the guest co-editors. This provides a summary of the exchanges between Bird and his critics, with a particular focus on the debates stemming from the differences between traditional and revolutionary interpretations of Kant.
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4

Smith, Bruce L. "Rorschach Interpretation." Rorschachiana 38, no. 1 (July 1, 2017): 12–21. http://dx.doi.org/10.1027/1192-5604/a000085.

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Abstract. This article presents an object relations theory interpretation of the protocol of Ms. B. Object relations theory is defined and the concepts of potential space and the introjective–anaclitic dimension are highlighted. The author suggests that Ms. B.’s protocol manifests a dissociative collapse of potential space, an introjective orientation toward defenses and coping, and a borderline level of object representation. The Rorschach data for these interpretations are discussed and the implications for treatment are highlighted.
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Dias, Nuno Costa, and João Nuno Prata. "Causal interpretation and quantum phase space." Physics Letters A 291, no. 6 (December 2001): 355–66. http://dx.doi.org/10.1016/s0375-9601(01)00747-2.

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6

Lerner, Robert M., and Robert C. Waag. "Wave space interpretation of scattered ultrasound." Ultrasound in Medicine & Biology 14, no. 2 (January 1988): 97–102. http://dx.doi.org/10.1016/0301-5629(88)90175-5.

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7

Gallardo, Patricio, and Noah Giansiracusa. "Modular Interpretation of a Non-Reductive Chow Quotient." Proceedings of the Edinburgh Mathematical Society 61, no. 2 (February 27, 2018): 457–77. http://dx.doi.org/10.1017/s0013091517000293.

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AbstractThe space of n distinct points and adisjoint parametrized hyperplane in projective d-space up to projectivity – equivalently, configurations of n distinct points in affine d-space up to translation and homothety – has a beautiful compactification introduced by Chen, Gibney and Krashen. This variety, constructed inductively using the apparatus of Fulton–MacPherson configuration spaces, is a parameter space of certain pointed rational varieties whose dual intersection complex is a rooted tree. This generalizes $\overline M _{0,n}$ and shares many properties with it. In this paper, we prove that the normalization of the Chow quotient of (ℙd)n by the diagonal action of the subgroup of projectivities fixing a hyperplane, pointwise, is isomorphic to this Chen–Gibney–Krashen space Td, n. This is a non-reductive analogue of Kapranov's famous quotient construction of $\overline M _{0,n}$, and indeed as a special case we show that $\overline M _{0,n}$ is the Chow quotient of (ℙ1)n−1 by an action of 𝔾m ⋊ 𝔾a.
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8

NIKOLIĆ, HRVOJE. "TIME IN RELATIVISTIC AND NONRELATIVISTIC QUANTUM MECHANICS." International Journal of Quantum Information 07, no. 03 (April 2009): 595–602. http://dx.doi.org/10.1142/s021974990900516x.

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The kinematic time operator can be naturally defined in relativistic and nonrelativistic quantum mechanics (QM) by treating time on an equal footing with space. The space–time position operator acts in the Hilbert space of functions of space and time. Dynamics, however, makes eigenstates of the time operator unphysical. This poses a problem for the standard interpretation of QM and reinforces the role of alternative interpretations such as the Bohmian one. The Bohmian interpretation, despite of being nonlocal in accordance with the Bell theorem, is shown to be relativistic covariant.
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9

Lobo, Iarley P., and Giovanni Palmisano. "Geometric interpretation of Planck-scale-deformed co-products." International Journal of Modern Physics: Conference Series 41 (January 2016): 1660126. http://dx.doi.org/10.1142/s2010194516601265.

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For theories formulated with a maximally symmetric momentum space we propose a general characterization for the description of interactions in terms of the isometry group of the momentum space. The well known cases of [Formula: see text]-Poincaré-inspired and (2+1)-dimensional gravity-inspired composition laws both satisfy our condition. Future applications might include the proposal of a class of models based on momenta spaces with anti-de Sitter geometry.
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10

곽은주. "An Interpretation Domain in Vector Space Semantics." Studies in English Language & Literature 34, no. 3 (August 2008): 289–310. http://dx.doi.org/10.21559/aellk.2008.34.3.015.

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11

Shan-Noon Yie. "Alternative Interpretation of Nature by Space Invariance." Physics Essays 17, no. 1 (March 1, 2004): 24–40. http://dx.doi.org/10.4006/1.3025628.

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12

Pasha Hosseinbor, A., Moo K. Chung, Yu-Chien Wu, Barbara B. Bendlin, and Andrew L. Alexander. "A 4D hyperspherical interpretation of q-space." Medical Image Analysis 21, no. 1 (April 2015): 15–28. http://dx.doi.org/10.1016/j.media.2014.11.013.

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13

Burkardt, M. "Position space interpretation for generalized parton distributions." Nuclear Physics A 711, no. 1-4 (December 2002): 127–32. http://dx.doi.org/10.1016/s0375-9474(02)01203-4.

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14

Semichaevsky, Andrey, and Markus Testorf. "Phase-space interpretation of deterministic phase retrieval." Journal of the Optical Society of America A 21, no. 11 (November 1, 2004): 2173. http://dx.doi.org/10.1364/josaa.21.002173.

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15

Vidyasagar, M. "A state-space interpretation of simultaneous stabilization." IEEE Transactions on Automatic Control 33, no. 5 (May 1988): 506–8. http://dx.doi.org/10.1109/9.1241.

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16

Liebchen, Benno, Robert Büchner, Christoph Petri, Fotis K. Diakonos, Florian Lenz, and Peter Schmelcher. "Phase space interpretation of exponential Fermi acceleration." New Journal of Physics 13, no. 9 (September 29, 2011): 093039. http://dx.doi.org/10.1088/1367-2630/13/9/093039.

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17

Goretti, Giovanna. "Lo Spazio dell’interpretazione [The Space of Interpretation]." International Journal of Psychoanalysis 93, no. 2 (April 2012): 471–76. http://dx.doi.org/10.1111/j.1745-8315.2011.00472.x.

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18

Stoffelen, Ad, and David Anderson. "Scatterometer Data Interpretation: Measurement Space and Inversion." Journal of Atmospheric and Oceanic Technology 14, no. 6 (December 1997): 1298–313. http://dx.doi.org/10.1175/1520-0426(1997)014<1298:sdimsa>2.0.co;2.

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19

Vostokova, Ye A. "PRINCIPLES OF ECOLOGICAL INTERPRETATION OF SPACE IMAGERY." Mapping Sciences and Remote Sensing 28, no. 1 (January 1991): 35–36. http://dx.doi.org/10.1080/07493878.1991.10641825.

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20

Lee, Jay H., Manfred Morari, and Carlos E. Garcia. "State-space interpretation of model predictive control." Automatica 30, no. 4 (April 1994): 707–17. http://dx.doi.org/10.1016/0005-1098(94)90159-7.

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21

Adler, D., and S. Raz. "Legal Wigner space filtering and its interpretation." Signal Processing 39, no. 1-2 (September 1994): 179–91. http://dx.doi.org/10.1016/0165-1684(94)90132-5.

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22

Korniienko, Inokentii O., and Beata V. Barchi. "Youth’s Life Space Narrative Research." Journal of Intellectual Disability - Diagnosis and Treatment 9, no. 3 (June 1, 2021): 172–81. http://dx.doi.org/10.6000/2292-2598.2021.09.02.3.

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The current study aims to distinguish objects and events, which teens and adolescents include in their life's spaces, explore differences in attitudes towards life spaces, and determine the level of life's space satisfaction of the youth via narrative psycholinguistic research. Methods: Methodological approaches inhered in interviewing and content analysis of the texts by calculating the frequency and investigating the components of the life's space category references that were defined based on the narrative compositions. The validity of categorisation was proved by propositional analysis. Spearman's rank correlation method was used. Results: The research results showed that stories people tell us holds powerful sway over their memories, behaviours, and identities. The youth's space was analysed within three content blocks: structural, interpretational, and evaluative. The structural block defined categories: people; city; habitable space; educational institution; social environment and information; activity; nature; state and patriotism; the inner world. The interpretational block analysis defined interpretational judgments and attributions of the responsibility for actions and changes in the participants' lives. The evaluative block analysis revealed the significant differences between teenagers and adolescents and between females and males in terms of life's space evaluation. Conclusions: The structure of teens’ and adolescents’ live space is similar, but its interpretation and evaluation are significantly different. Proceeding from teenage to adolescence is followed by such changes as growing dissatisfaction of the existing life's space and the wish to change it; growing internality, i.e., understanding personal responsibility of the life's space formation.
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23

Ceylan, Salih. "Space, Architecture, and Science Fiction: An Architectural Interpretation of Space Colonization." International Journal of the Constructed Environment 9, no. 2 (2018): 1–17. http://dx.doi.org/10.18848/2154-8587/cgp/v09i02/1-17.

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24

Reyna, Steve. "What is interpretation?" Focaal 2006, no. 48 (December 1, 2006): 131–43. http://dx.doi.org/10.3167/092012906780646389.

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This essay answers the question: what is interpretation? It does so by proposing that interpretation involves certain brain operations. These utilize perceptual and procedural culture stored in neural networks. The parts of the brain performing interpretation are said to constitute a cultural neurohermenetic system, hypothesized to function according to an interpretive hierarchy. It is argued that such an approach has two benefits. The first of these is to provide a non-sociobiological, non-reductionist way of analyzing interactions between culture and biology. The second benefit is to provide conceptual tools for explaining how the micro-realm within individuals (I-space) makes connections in the macro-realm (E-space) of events in social forms. Conceptualization of such connections forms a basis for a variety of social analysis termed complex string being theory.
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25

Stumpf, Harald. "Covariant Regularization of Nonlinear Spinorfield Quantum Theories and Probability Interpretation." Zeitschrift für Naturforschung A 55, no. 3-4 (April 1, 2000): 415–32. http://dx.doi.org/10.1515/zna-2000-3-408.

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Abstract By a decomposition theorem a higher order nonlinear spinorfield equation can be transformed into a set of first order nonlinear spinorfield equations, i. e. into an auxiliary field formulation which allows canonical quantization. The quantum dynamics of the auxiliary fields is expressed in algebraic Schrödinger representation and admits only unphysical state spaces with indefinite metric. Regularization of the classical theory is transferred into quantum field theory by a noninvertible map from the corresponding auxiliary field state space into an associated physical state space, the metric of which is positive definite. For the effective dynamics in the physical state space probability current conservation is proved, and for physical states which describe composite particle configurations the existence of the state space is demonstrated
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26

Jung, Byung-Seok. "Comprehensive Interpretation and Conflation - Expansion and Continuity of the Space of Zhouyi Interpretation." Korean Journal of Philosophy 129 (November 30, 2016): 1. http://dx.doi.org/10.18694/kjp.2016.11.129.1.

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27

Lee, Ok-Jae, and Moon-Duck Kim. "The Interpretation of Traditional Space Based on the Theory of Ontological Space." Korean Institute of Interior Design Journal 23, no. 4 (August 30, 2014): 94–102. http://dx.doi.org/10.14774/jkiid.2014.23.4.094.

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28

IMAZATO, Satoshi. "Sociosemiotic Approach to an Interpretation of Rural Space." Geographical Review of Japa,. Ser. A, Chirigaku Hyoron 72, no. 5 (1999): 310–34. http://dx.doi.org/10.4157/grj1984a.72.5_310.

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29

Montenegro, Manuel, Ricardo Peña, and Clara Segura. "Space consumption analysis by abstract interpretation: Reductivity properties." Science of Computer Programming 111 (November 2015): 458–82. http://dx.doi.org/10.1016/j.scico.2014.04.014.

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30

Wang, M. S. "Stochastic Interpretation of Quantum Mechanics in Complex Space." Physical Review Letters 79, no. 18 (November 3, 1997): 3319–22. http://dx.doi.org/10.1103/physrevlett.79.3319.

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31

Haasdonk, B. "Feature space interpretation of SVMs with indefinite kernels." IEEE Transactions on Pattern Analysis and Machine Intelligence 27, no. 4 (April 2005): 482–92. http://dx.doi.org/10.1109/tpami.2005.78.

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32

Knipp, Delores J. "Advances in Space Weather Data Interpretation and Simulations." Space Weather 16, no. 3 (March 2018): 198–99. http://dx.doi.org/10.1002/2018sw001824.

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33

SU, Kaile, Yinyin Xiao, Qingliang Chen, and Han Lin. "Semantic interpretation of compositional logic in instantiation space." Frontiers of Computer Science in China 1, no. 2 (May 2007): 191–99. http://dx.doi.org/10.1007/s11704-007-0019-y.

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34

Sharin, Yu A. "Physical interpretation of a curvilinear space with torsion." Russian Physics Journal 52, no. 10 (October 2009): 1113–15. http://dx.doi.org/10.1007/s11182-010-9347-8.

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35

Sharin, Yu A. "Physical interpretation of a curvilinear space with torsion." Soviet Physics Journal 33, no. 10 (October 1990): 861–64. http://dx.doi.org/10.1007/bf00897310.

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36

BURKARDT, MATTHIAS. "IMPACT PARAMETER SPACE INTERPRETATION FOR GENERALIZED PARTON DISTRIBUTIONS." International Journal of Modern Physics A 18, no. 02 (January 20, 2003): 173–207. http://dx.doi.org/10.1142/s0217751x03012370.

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The Fourier transform of generalized parton distribution functions at ξ = 0 describes the distribution of partons in the transverse plane. The physical significance of these impact parameter dependent parton distribution functions is discussed. In particular, it is shown that they satisfy positivity constraints which justify their physical interpretation as a probability density. The generalized parton distribution H is related to impact parameter distribution of unpolarized quarks for an unpolarized nucleon, [Formula: see text] is related to the distribution of longitudinally polarized quarks in a longitudinally polarized nucleon, and E is related to the distortion of the unpolarized quark distribution in the transverse plane when the nucleon has transverse polarization. The magnitude of the resulting transverse flavor dipole moment can be related to the anomalous magnetic moment for that flavor in a model independent way.
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37

Neto, Henrique. "An Alternative Interpretation of Planks Law." Applied Physics Research 8, no. 6 (November 27, 2016): 75. http://dx.doi.org/10.5539/apr.v8n6p75.

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It is possible to interpret Planck’s law as describing the energy content of the elements of a discrete space. From this conclusion, one can construct physical theory with recourse to not more then one single particle and one single law. This one article concerns the dark matter and dark energy problems, which seem to be both simply explainable if Planck oscillators (as elements of a discrete space) which possess a positive potential energy. Furthermore, it is shown that there exists a one to one correspondence between the distribution of this energy density and the geometry of space, a result that can eventually generate new insights on the geometry of space-time from a natural quantum perspective.
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38

Połacik, Tomasz. "Propositional quantification in the monadic fragment of intuitionistic logic." Journal of Symbolic Logic 63, no. 1 (March 1998): 269–300. http://dx.doi.org/10.2307/2586601.

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AbstractWe study the monadic fragment of second order intuitionistic propositional logic in the language containing the standard propositional connectives and propositional quantifiers. It is proved that under the topological interpretation over any dense-in-itself metric space, the considered fragment collapses to Heyting calculus. Moreover, we prove that the topological interpretation over any dense-in-itself metric space of fragment in question coincides with the so-called Pitts' interpretation. We also prove that all the nonstandard propositional operators of the form q ↦ ∃p (q ↔ F(p)), where F is an arbitrary monadic formula of the variable p, are definable in the language of Heyting calculus under the topological interpretation of intuitionistic logic over sufficiently regular spaces.
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39

Gentry, Robert V. "A New Redshift Interpretation." Modern Physics Letters A 12, no. 37 (December 7, 1997): 2919–25. http://dx.doi.org/10.1142/s0217732397003034.

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A nonhomogeneous universe with vacuum energy, but without space–time expansion, is utilized together with gravitational and Doppler redshifts as the basis for proposing a new interpretation of the Hubble relation and the 2.7 K Cosmic Blackbody Radiation.
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40

Kantrowitz, Robert, and Michael M. Neumann. "More of Dedekind: His Series Test in Normed Spaces." International Journal of Mathematics and Mathematical Sciences 2016 (2016): 1–3. http://dx.doi.org/10.1155/2016/2508172.

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41

Liu, Hong Lan, and De Zheng Zhang. "A Probabilistic Propositional Logic System is an Event Semantics for Classical Formal System of Propositional Calculus." Applied Mechanics and Materials 427-429 (September 2013): 1917–23. http://dx.doi.org/10.4028/www.scientific.net/amm.427-429.1917.

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The well formed formulas (wffs) in classical formal system of propositional calculus (CPC) are only some formal symbols, whose meanings are given by an interpretation. A probabilistic logic system, based on a probabilistic space, is an event semantics for CPC, in which set operations are the semantic interpretations for connectives, event functions are the semantic interpretations for wffs, the event (set) inclusion is the semantic interpretation for tautological implication, and the event equality = is the semantic interpretation for tautological equivalence. CPC is applicable to probabilistic propositions completely. Event calculus instead of truth value (probability) calculus can be performed in CPC because there arent truth value functions (operators) to interpret all connectives correctly.
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42

Inoguchi, Jun-Ichi. "Biharmonic curves in Minkowski3-space." International Journal of Mathematics and Mathematical Sciences 2003, no. 21 (2003): 1365–68. http://dx.doi.org/10.1155/s016117120320805x.

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43

Heidel, Andreas-Christian. "Between Times and Spaces." Novum Testamentum 62, no. 4 (September 22, 2020): 416–35. http://dx.doi.org/10.1163/15685365-12341666.

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Abstract The understanding of space and time and their relationship in the Epistle to the Hebrews is an essential key to the interpretation of this NT Scripture. In contrast to the too often one-sided interpretations of Hebrews throughout its history of research, Hebrews’ understanding of reality is characterized by an interplay of horizontal and vertical dimensions wherein, through God’s act of speaking in the Son, times and spaces overlap and form a paradoxical reality for the believers who seek their heavenly home.
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44

Lee, Byung-Ju. "Interpretation on the Space by Breaking the Grid System." Journal of Digital Design 7, no. 1 (January 2007): 107–18. http://dx.doi.org/10.17280/jdd.2007.7.1.011.

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45

Fedorovsky, O. D. "On the interpretation of space images of natural landscapes." Kosmìčna nauka ì tehnologìâ 5, no. 5-6 (September 30, 1999): 9–15. http://dx.doi.org/10.15407/knit1999.05.009.

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46

QI, Yan-xia, Hui-li SHEN, Zhao-hui CHEN, and Bin GU. "Event-B interpretation for space aircraft description language model." Journal of Computer Applications 32, no. 12 (May 29, 2013): 3525–28. http://dx.doi.org/10.3724/sp.j.1087.2012.03525.

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47

Saxena, A., P. C. Srivastava, J. G. Hirsch, V. K. B. Kota, and M. J. Ermamatov. "35,37,39S isotopes in sd–pf space: Shell-model interpretation." Nuclear Physics A 961 (May 2017): 68–77. http://dx.doi.org/10.1016/j.nuclphysa.2017.02.008.

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48

Kennedy, Christopher A. "Interpretation of Monte Carlo Simulations Using Parameter Space Plots." Risk Analysis 24, no. 2 (April 2004): 437–42. http://dx.doi.org/10.1111/j.0272-4332.2004.00445.x.

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49

Gaboardi, Marco, and Romain Péchoux. "On bounding space usage of streams using interpretation analysis." Science of Computer Programming 111 (November 2015): 395–425. http://dx.doi.org/10.1016/j.scico.2015.05.004.

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50

Ho, Kelvin. "SKATEBOARDING: An Interpretation of Space in the Olympic City." Architectural Theory Review 4, no. 2 (November 1999): 98–102. http://dx.doi.org/10.1080/13264829909478374.

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