2,258 research outputs found
[Stammbuch Peter Huber] / Peter Huber
[STAMMBUCH PETER HUBER] / PETER HUBER
[Stammbuch Peter Huber] / Peter Huber ( - )
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Beschreibung (Ir)
Register über die hierinn befindliche Nahmen. (Iv-IIr)
Eibiswald, Georg Ehrenreich von; Blatt 1 (1r)
Gäller zu Schwamberg, Johann Friedrich; Blatt 2 (1v-2r)
Glojach, Johann Carl von; Blatt 2,1 (2ar)
Hochberg, Christoph Ferdinand von; Blatt 2,2 (2av-2br)
Sebisch, Melchior; Blatt 3 (3r)
Schad, Daniel; Blatt 8 (7v-8r)
Dieterich, Conrad; Blatt 16 (15v-16r)
Metrophanes; Blatt 17 (16v-17r)
Bitsch, Caspar; Blatt 20 (19v-20r)
Locamer, Georg David; Blatt 21 (20v-21r)
Königstein, Sigmund Stubick von; Blatt 24 (23v-24r)
Florus, Marcus; Blatt 29 (28v-29r)
Furt, Ferdinand; Blatt 32 (31v-32r)
Schmidt, Johann; Blatt 33 (32v-33r)
Fröreisen, Isaac; Blatt 34 (33v-34r)
Dorsche, Johann Georg; Blatt 35 (34v-35r)
Agerius, Nicolaus; Blatt 46 (45v-46r)
Hebenstreit, Johann Baptist; Blatt 51 (50v-51r)
Heins, Johann; Blatt 55 (54v-55r)
Bernegger, Matthias; Blatt 56 (55v-56r)
Huber, Peter; Blatt 58 (57v-58r)
Bischoff, Ludwig; Blatt 59 (58v-59r)
Kerner, Balthasar; Blatt 60 (59v-60r)
Opitz, Martin; Blatt 61 (60v-61r)
Friedland, Paul; Blatt 67 (66v-67r)
Gerner, Abraham; Blatt 73 (72v-73r)
Ebel, Johann Philipp; Blatt 79 (78v-79r)
Mangold, Johann Conrad; Blatt 80 (79v-80r)
Freinsheim, Johann; Blatt 80 (80v-81r)
Herrenschmid, Andreas; Blatt 82 (81v-82r)
Merk, Johann Konrad; Blatt 83 (82v-83r)
Dilger, Nathanael; Blatt 84 (83v-84r)
Huber, Johann; Blatt 86 (86r)
Blass, Balthasar; Blatt 91 (90v-91r)
Zschaesy, Melchior; Blatt 100 (99v-100r)
Bardili, Karl; Blatt 100,1 (99v-100r)
Wolf von Sponheim, Hans; Blatt 101 (100v-101r)
Ehinger von Balzheim, Hans Friedrich; Blatt 101,2 (101v-102r)
Notter, Johann Georg; Blatt 103 (102v-103r)
Zittelin, Johann Michael; Blatt 105 (104v-105r)
Rihel, Josias; Blatt 106 (105v-106r)
Unbekannt; Blatt 107 (106v-107r)
Otto, Marcus; Blatt 108 (107v-108r)
Mörlin, Johann; Blatt 108,1 (108v-109r)
Heilbrunner, Anton; Blatt 108,2 (108v-109r)
Schmidt, Ulrich; Blatt 109 (108v-109r)
Baldinger, Albrecht von; Blatt 109,1 (109v-110r)
Baldinger, Sigmund; Blatt 109,2 (109v-110r)
Schleicher, Sigismund; Blatt 110 (109v-110r)
Pöckh, Johann Ludwig; Blatt 110 (110v-111r)
Otto, Sebastian; Blatt 111 (110v-111r)
Erhard, Melchior; Blatt 111 (111v-112r)
Roth, Leo Eberhard; Blatt 112 (111v-112r)
Baldinger, Johann Heinrich; Blatt 112,2 (112v-113r)
Acker, Nicolaus; Blatt 113 (112v-113r)
Acker, Georg; Blatt 113 (113v-114r)
Zorn, Georg Friedrich; Blatt 114 (113v-114r)
Authäus, Johann Hermann; Blatt 114,2 (114v-115r)
Tanneberg, Melchior; Blatt 115 (114v-115r)
Nostitz, Georg Wolfram von; Blatt 115,2 (115v-116r)
Freinsheimer, Johann Caspar; Blatt 116 (115v-116r)
Stainer, Johann; Blatt 116,2 (116v-117r)
Ulrich, Paul; Blatt 117 (116v-117r)
Widemann, Georg Sebastian; Blatt 117,2 (117v-118r)
Bach, Georg; Blatt 118 (117v-118r)
Straub, Caspar; Blatt 118,2 (118v-119r)
Wild, Johann Rudolph; Blatt 119 (118v-119r)
Gebhart, Johann; Blatt 119,2 (119v-120r)
Klein, Joachim; Blatt 120 (119v-120r)
Roth, Johann Jacob; Blatt 120 (120v-121r)
Roth, Johann Conrad; Blatt 121 (120v-121r)
Hofmeister, Conrad; Blatt 121 (121v-122r)
Schad, Daniel; Blatt 122 (121v-122r)
Reichhatt, Bartholomäus; Blatt 122,2 (122v-123r)
Wickh, David; Blatt 123 (122v-123r)
Hipler, Johann; Blatt 123 (123v-124r)
Weinmann, Johann Simon; Blatt 124 (123v-124r)
Weiskircher, Georg Heinrich; Blatt 126 (125v-126r)
Spleiß, Johannes; Blatt 127 (126v-127r)
Ortner, Johann; Blatt 128 (128r)
Sattler, Johann Bartholomäus; Blatt 130 (129v-130r)
Heider, Jacob; Blatt 130,2 (130v-131r)
Dannhauer, Johann Conrad; Blatt 130,3 (130v-131r)
Mergius, Johannes Martin; Blatt 131 (130v-131r)
Funck, Johann; Blatt 131,2 (131v-132r)
Zeiller, Martin; Blatt 132 (131v-132r)
König, Sebastian; Blatt 132,2 (132v-133r)
Frey, Johann; Blatt 132,3 (132v-133r)
Bückel, Johann Conrad; Blatt 133,1 (132v-133r)
Brehm, Nikolaus Jakob; Blatt 133,2 (132v-133r)
Haas, Johann Michael; Blatt 133 (133v-134r)
Krafft, Georg; Blatt 134 (133v-134r)
Wolfram, Friedrich; Blatt 135 (134v-135r)
Herbst, Sebastian; Blatt 136 (135v-136r)
Widmann, Johann; Blatt 136,2 (136v-137r)
Bardeller, Matthaeus; Blatt 137 (136v-137r)
Zoller, Johann Georg; Blatt 138 (137v-138r)
Bachmann, Johann Jacob; Blatt 139 (138v-139r)
Burkhard, Georg; Blatt 139,2 (139v-140r)
Bayer, Johann Melchior; Blatt 140 (139v-140r)
Gerschlauer, Georg; Blatt 140 (140v-141r)
Mayer, Johann; Blatt 141 (140v-141r)
Wollaib, Marcus; Blatt 141,2 (141v-142r)
Öchslin, Johann Georg; Blatt 142 (141v-142r)
Stang, Israel; Blatt 142,2 (142v-143r)
Glirr, Gotthard; Blatt 143 (142v-143r)
Yelin, Jacob; Blatt 143,2 (143v-144r)
Stettner, Paul; Blatt 144 (143v-144r)
Becher, Joachim; Blatt 144 (144v-145r)
Ast, Michael; Blatt 145 (144v-145r)
Nachtigall, Johann Georg; Blatt 145-146 (145v-146r)
Kiechel, Matthias; Blatt 146 (146v-147r)
Honold, Jakob; Blatt 147 (146v-147r)
Faber, Martin; Blatt 147,2 (147v-148r)
Bartholomaei, Johann Martin; Blatt 148 (147v-148r)
Keller, Christoph Sigismund; Blatt 148,2 (148v-149r)
Waiß, Johann Jacob; Blatt 149 (148v-149r)
Waiß, Peter; Blatt 149 (149v-150r)
Tilger, Konrad; Blatt 150 (149v-150r)
Deller, Conrad; Blatt 150,2 (150v-151r)
Mayer, Emanuel; Blatt 151 (150v-151r)
Stöltzlin, Bonifacius; Blatt 151 (151v-152r)
Müller, Christoph; Blatt 152 (151v-152r)
Georgius, Johann Bernhard; Blatt 152 (152v-153r)
Müller, David; Blatt 153 (152v-153r)
Saurweitt, Johann Conrad; Blatt 153,2 (153v-154r)
Graff, Mathäus; Blatt 154 (153v-154r)
Becker, Gottfried; Blatt 154 (154v-155r)
Friderici, Paul; Blatt 155 (154v-155r)
Asch, Johann Christoph; Blatt 155,2 (155v-156r)
Friderici, Johann Philipp; Blatt 156 (155v-156r)
Khern, Michael; Blatt 156,2 (156v-157r)
Gräter, Wilhelm; Blatt 157,1 (156v-157r)
Springmann, Matthaeus; Blatt 157,2 (156v-157r)
Heckel, Johann Georg; Blatt 157,2 (157v-158r)
Acker, Karl; Blatt 158 (157v-158r)
Degeler, David; Blatt 158 (158v-159r
Writers Talk Featuring Sonya Huber
Sonya Huber, 2004 graduate of OSU's MFA Creative Writing Program, currently an assistant professor at Georgia Southern University. Author of "The Backwards Research Guide for Writers," "Opa Nobody," and most recently "Cover Me: A Health Insurance Memoir."The media can be accessed here: http://streaming.osu.edu/knowledgebank/cstw12/WT_WCRS_11-08-10_SonyaHuber.mp3Ohio State University. Center for the Study and Teaching of Writin
Quaestionum historicarum de editione V.T. Graeca, LXXII. interpretibus Hierosolymitanis vulgò tributa, tetras secunda
quam ... praeside ... Ioh. Henrico Hottingero ... publicae disquisitioni subiectam propugnare conabitur Ioh. Iacobus Aberlinus ... ad diem Ianuarii, M DC XLVII ...Dedikation an Joh. Jacob Irminger, Oswald Keller, Joh. Jacob Ulrich, Joh. Rudolf Stucki, Joh. Caspar Suter, Joh. Wirtz, Caspar Wyss und Christoph Tubenmann auf Bl. A1v. Gedichte von Christian Huber, Joh. Caspar Huber, Marcus Tubenmann und Johannes Müller auf Bl. C1-2.Text teilw. hebr.Diss. Hohe Schule Zürich, 164
Interior-point methods for PDE-constrained optimization
In applied sciences PDEs model an extensive variety of phenomena. Typically the final goal of simulations is a system which is optimal in a certain sense. For instance optimal control problems identify a control to steer a system towards a desired state. Inverse problems seek PDE parameters which are most consistent with measurements. In these optimization problems PDEs appear as equality constraints. PDE-constrained optimization problems are large-scale and often nonconvex. Their numerical solution leads to large ill-conditioned linear systems. In many practical problems inequality constraints implement technical limitations or prior knowledge.
In this thesis interior-point (IP) methods are considered to solve nonconvex large-scale PDE-constrained optimization problems with inequality constraints. To cope with enormous fill-in of direct linear solvers, inexact search directions are allowed in an inexact interior-point (IIP) method. This thesis builds upon the IIP method proposed in [Curtis, Schenk, Wächter, SIAM Journal on Scientific Computing, 2010]. SMART tests cope with the lack of inertia information to control Hessian modification and also specify termination tests for the iterative linear solver.
The original IIP method needs to solve two sparse large-scale linear systems in each optimization step. This is improved to only a single linear system solution in most optimization steps. Within this improved IIP framework, two iterative linear solvers are evaluated: A general purpose algebraic multilevel incomplete L D L^T preconditioned SQMR method is applied to PDE-constrained optimization problems for optimal server room cooling in three space dimensions and to compute an ambient temperature for optimal cooling. The results show robustness and efficiency of the IIP method when compared with the exact IP method.
These advantages are even more evident for a reduced-space preconditioned (RSP) GMRES solver which takes advantage of the linear system's structure. This RSP-IIP method is studied on the basis of distributed and boundary control problems originating from superconductivity and from two-dimensional and three-dimensional parameter estimation problems in groundwater modeling. The numerical results exhibit the improved efficiency especially for multiple PDE constraints.
An inverse medium problem for the Helmholtz equation with pointwise box constraints is solved by IP methods. The ill-posedness of the problem is explored numerically and different regularization strategies are compared. The impact of box constraints and the importance of Hessian modification on the optimization algorithm is demonstrated. A real world seismic imaging problem is solved successfully by the RSP-IIP method
Guest Editorial Special Section on Multisensor Fusion and Integration for Intelligent Systems
Robust Linear and Support Vector Regression
The robust Huber M-estimator, a differentiable cost function that is quadratic for small errors and linear otherwise, is
modeled exactly, in the original primal space of the problem, by an easily solvable simple convex quadratic program for both linear and
nonlinear support vector estimators. Previous models were significantly more complex or formulated in the dual space and most
involved specialized numerical algorithms for solving the robust Huber linear estimator [3], [6], [12], [13], [14], [23], [28]. Numerical test
comparisons with these algorithms indicate the computational effectiveness of the new quadratic programming model for both linear
and nonlinear support vector problems. Results are shown on problems with as many as 20,000 data points, with considerably faster
running times on larger problems
Mesabolivar amadoi Huber 2018, sp. n.
Mesabolivar amadoi sp. n. Figs 306–314 Diagnosis. Easily distinguished from most known congeners by armature of male chelicerae (Figs 310–311; two pairs of frontal apophyses), tip of procursus (Figs 308–309; distinctive shape of prolateral process), and shape of epigynum (Figs 312–313; anterior plate with large central whitish depression and pair of apophyses); from most similar known species (M. bonita) by apophyses on epigynum (absent in M. bonita) and by positions and sizes of male cheliceral apophyses (proximal apophyses smaller; distal apophyses in more proximal position). Etymology. Named for Jorge Amado (1912–2001), Brazilian writer, author of Gabriela, Cravo e Canela. Type material. BRAZIL: Bahia: ♂ holotype, 1♀ paratype, MNRJ (14319), 14♂ 10♀ paratypes, ZFMK (Ar 19147–48), Reserva Particular do Patrimônio Natural Serra Bonita (15°23.3’–23.4’S, 39°33.7’–34.0’W), ~ 750– 850 m a.s.l., 2–3.x.2011 (B.A. Huber, A. Pérez-González, M. Alves Dias). Other material examined. BRAZIL: Bahia: 1♂ 9♀ in pure ethanol, ZFMK (Br11-161), same data as types. Espírito Santo: 3♂ 16♀ 1 juv., ZFMK (Ar 19149–50), Reserva Biológica de Sooretama, ‘site 1’ (19°03.3’S, 40°08.8’W), ~ 90 m a.s.l., 27.ix.2011 (B.A. Huber, A. Pérez-González); 6♀ in pure ethanol, ZFMK (Br 11-126), same data. Description. Male (holotype) MEASUREMENTS. Total body length 3.3, carapace width 1.3. Distance PME-PME 130 µm, diameter PME 120 µm, distance PME-ALE 100 µm, distance AME-AME 30 µm, diameter AME 50 µm. Sternum width/length: 0.95/ 0.55. Leg 1: 38.7 (11.0 + 0.5 + 10.8 + 14.6 + 1.8), tibia 2: 7.6, tibia 3: 4.9, tibia 4: 7.3; tibia 1 L/d: 94. Femora 1–4 width (at half length): 0.14, 0.15, 0.22, 0.15. COLOR (in ethanol). Prosoma and legs light brown, carapace with large dark median mark, clypeus not darker; tips of femora and tibiae lighter yellowish, legs without dark rings; abdomen greenish gray, dorsally and laterally densely covered with dark marks, ventrally with light brown area in front of gonopore. BODY. Habitus as in putative close relatives (M. bonita, M. pau; cf. Huber 2015: figs 12–13); ocular area raised; carapace with distinct median furrow; clypeus unmodified; sternum unmodified. CHELICERAE. With two pairs of frontal apophyses (Figs 310–311), both pointed in lateral view, distal pair rounded in frontal view. PALPS. As in Figs 306–307; apparently indistinguishable from M. bonita (direct comparison with M. bonita paratype); even details of procursus tip (Figs 308–309) apparently identical. LEGS. Without spines, without curved hairs, few vertical hairs; retrolateral trichobothrium on tibia 1 at 2%; prolateral trichobothrium present on tibia 1; tarsus 1 with>30 pseudosegments, distally fairly distinct. Male (variation). Tibia 1 in 15 other males: 9.4–11.2 (mean 10.2). Female. In general similar to male. Tibia 1 in 25 females: 5.9–8.5 (mean 7.0). Epigynum as in Figs 312–313; anterior plate with large central whitish depression bordered by posterior ridge and pair of apophyses near posterior margin; simple posterior plate. Internal genitalia as in Fig. 314, with pair of large pore-plates in tent-shaped lateral position, converging anteriorly. Natural history. The spiders were found in domed webs built in sheltered spaces close to the ground. Distribution. Known from two localities in Bahia and Espírito Santo states (Brazil) (Fig. 734).Published as part of Huber, Bernhard A., 2018, The South American spider genera Mesabolivar and Carapoia (Araneae, Pholcidae): new species and a framework for redrawing generic limits, pp. 1-178 in Zootaxa 4395 (1) on pages 76-79, DOI: 10.11646/zootaxa.4395.1.1, http://zenodo.org/record/120251
Mesabolivar claricae Huber 2018, sp. n.
Mesabolivar claricae sp. n. Figs 233–240, 251–252 Diagnosis. Distinguished from most known congeners by armature of male chelicerae (Figs 238–239; one pair of frontal apophyses near median line), shape of procursus (Figs 233–235; widely curved, distinctive distal structures, without prolateral apophysis), and shape of epigynum (Figs 236–237, 251; trapezoidal anterior plate with pair of apophyses and median pocket); from the very similar to M. cyaneomaculatus by shorter and wider procursus with different distal elements (compare Figs 227–229 and 233–235), and by smaller epigynum without anterior pair of low humps (compare Figs 230–232 and 236–237). Etymology. Named for Clarice Lispector (1920–1977), Brazilian writer, daughter of Russian-Jewish immigrants, author of Perto do coração selvagem. Type material. BRAZIL: Rio de Janeiro: ♂ holotype, 1♀ paratype, MNRJ (14315), 6♂ 19♀ paratypes, ZFMK (Ar 19082–83), Santa Maria Madalena, forest fragment (21°58.9’–59.1’S, 41°57.2’–57.6’W), 480–590 m a.s.l., 30.ix.–1.x.2010 (B.A. Huber, A. Pérez-González). Other material examined. BRAZIL: Rio de Janeiro: 4♀ in pure ethanol, ZFMK (Br 10-78), same data as types. 3♂ 4♀, ZFMK (Ar 19084), Cachoeiras de Macacu, Reserva Ecológica de Guapiaçú (22°24.4’–25.3’S, 42°44.2’–44.3’W), 140–280 m a.s.l., 23.ix.2009 (B.A. Huber, A. Giupponi); 1♂ in pure ethanol, ZFMK (Br 09- 101), same data but 23–24.ix.2009 (B.A. Huber); 2♂, ZFMK (Ar 19085), same data but 25.ix.2009 (B.A. Huber); 2♂ 2♀, ZFMK (Ar 19086), same locality at 22°24.3’S, 42°44.1’W, ~ 300–400 m a.s.l., 24.ix.2009 (B.A. Huber, A. Giupponi). Description. Male (holotype) MEASUREMENTS. Total body length 3.7, carapace width 1.35. Distance PME-PME 110 µm, diameter PME 150 µm, distance PME-ALE 100 µm, distance AME-AME 40 µm, diameter AME 45 µm. Sternum width/length: 1.0/ 0.65. Leg 1: 57.6 (13.7 + 0.5 + 13.5 + 26.8 + 3.1), tibia 2: 8.7, tibia 3: 5.5, tibia 4: 8.3; tibia 1 L/d: 104. Femora 1– 4 width (at half length): 0.17, 0.23, 0.23, 0.17. COLOR (in ethanol). Carapace ochre-orange with large brown median mark including posterior part of ocular area, with pair of light marks laterally behind ocular area; sternum orange-brown; legs brown, tips of femora and tibiae lighter yellowish, without dark rings; abdomen greenish gray, dorsally and laterally densely covered with dark marks, ventrally with orange-brown area in front of gonopore, very indistinct plate in front of spinnerets. BODY. Habitus very similar to M. cyaneomaculatus (cf. Figs 148–149); ocular area raised; carapace with distinct median furrow; clypeus unmodified; sternum unmodified. CHELICERAE. With one pair of frontal apophyses close to median line (Figs 238–239). PALPS. In general very similar to M. cyaneomaculatus (cf. Huber 2000: figs 813, 816), proximal segments apparently identical in shape but slightly smaller (see Variation below); procursus distal part (after bend) clearly shorter and wider, with different distal elements (Figs 233–235); bulbal process in general very similar to M. cyaneomaculatus but clearly shorter (length about 0.4 vs. 0.6). LEGS. Without spines, without curved hairs, few vertical hairs; retrolateral trichobothrium on tibia 1 at 2%; prolateral trichobothrium present on tibia 1; tarsus 1 with>40 pseudosegments, distally fairly distinct. Male (variation). Tibia 1 in nine other males: 12.4–14.1 (mean 13.2). Palpal femur length 0.60–0.62 (vs. 0.67– 0.73 in M. cyaneomaculatus). Female. In general similar to male but all leg femora approximately same width. Tibia 1 in 14 females: 8.7– 10.3 (mean 9.5). Epigynum as in Figs 236–237, 251; anterior plate trapezoidal, with pair of short processes (slightly variable in size even within localities) and median pocket near posterior margin; simple posterior plate. Internal genitalia as in Figs 240, 252, with V-shaped (or U-shaped) sclerite and pair of large pore-plates in tentshaped lateral position, converging anteriorly. Distribution. Known from two localities in Rio de Janeiro state (Brazil) (Fig. 728).Published as part of Huber, Bernhard A., 2018, The South American spider genera Mesabolivar and Carapoia (Araneae, Pholcidae): new species and a framework for redrawing generic limits, pp. 1-178 in Zootaxa 4395 (1) on pages 62-63, DOI: 10.11646/zootaxa.4395.1.1, http://zenodo.org/record/120251
Quantum gates and multipartite entanglement resonances realized by nonuniform cavity motion
We demonstrate the presence of genuine multipartite entanglement between the modes of quantum fields in nonuniformly moving cavities. The transformations generated by the cavity motion can be considered as multipartite quantum gates. We present two setups for which multimode entanglement can be generated for bosons and fermions. As a highlight we show that the genuine bosonic multipartite correlations can be resonantly enhanced. Our results provide fundamental insights into the structure of Bogoliubov transformations and suggest strong links between quantum information, quantum fields in curved spacetimes and gravitational analogues by way of the equivalence principle.</p
Linear programming based time lag identification in event sequences
Many technical systems like manufacturing plants or software applications generate large event sequences. Knowing the temporal relationship between events is important for gaining insights into the status and behavior of the system. This paper proposes a novel approach for identifying the time lag between different event types. This identification task is formulated as a binary integer optimization problem that can be solved efficiently and close to optimality by means of a linear programming approximation. The performance of the proposed approach is demonstrated on synthetic and real-world event sequences
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