Categorizing Abortions By Safety Category: A Bayesian Hierarchical Modeling Approach

Kang, Zhenning

09 July 2018

Since 1990s, World Health Organization defines abortion as safe if it was done with a recommended method that was appropriate to the pregnancy duration and if the person providing the abortion was trained. In this study, we used a three-tiered categorization on abortion safety. Abortion is less safe if the pregnancy was terminated either by untrained individuals or under dangerous methods, and least safe if neither of the two criteria was met. We included all available empirical data on abortion methods, providers, and settings, and factors affecting safety as covariates to estimate the global, regional, and sub regional distributions of abortion by safety categories for the period 2010-2014. We applied a Bayesian hierarchical model with two regression submodels to estimate abortion safety. One submodel estimated safe proportions and the other one divided unsafe into less safe and least safe proportions. Country intercepts were included in both submodels and estimated using hierarchical models. Data sources were assigned varying levels of uncertainty or treated as minima or maxima to reflect quality of reporting. We constructed 90% highest density intervals as credible intervals to reflect uncertainty in final outcomes. We carried out model selection using information criteria. We examined model validation and carried out various checks to verify the sensitivity of reporting to prior distributions used and outlying countries. We found that the model was reasonably well calibrated and subregional estimates were not sensitive to outlying observations or prior choice. Of the 55· 7 million abortions that occurred worldwide each year between 2010–14, we estimated that 30·6 million (54·9%, 90% uncertainty interval 49·9–59·4) were safe, 17·1 million (30·7%, 25·5–35·6) were less safe, and 8·0 million (14·4%, 11·5–18·1) were least safe. The proportion of unsafe abortions was significantly higher in developing countries than developed countries, and significantly higher in countries with highly restrictive abortion laws than in those with less restrictive laws. In-depth assessments of data quality and factors affecting abortion safety in outlying countries may result in further model improvements.

abortion

safety

Bayesian

hierarchical

Post-fire Tree Establishment Patterns at the Subalpine Forest-Alpine Tundra Ecotone: A Case Study in Mount Rainier National Park

Stueve, Kirk M.

2009 August 1900

Climatic changes have induced striking altitudinal and latitudinal vegetation shifts throughout history. These shifts will almost certainly recur in the future; threatening other flora and fauna, and influencing climate feedback loops. Changes in the spatial distribution of vegetation are most conspicuous at physiognomically distinct ecotones, particularly between the subalpine forest and alpine tundra. Traditionally, ecological research has linked abiotic variables with the position of this ecotone (e.g., cold temperatures inhibit tree survival at high elevations). Thus, the prevailing assumption states that this ecotone is in equilibrium or quasi-equilibrium with the surrounding physical environment and that any dynamic shifts express direct linkages with the physical environment. This dissertation employs a landscape ecology approach to examine the abiotic and biotic ecological mechanisms most important in controlling tree establishment at this ecotone. The study site is on the western slopes of Mount Rainier, which was severely burned by a slash fire in 1930. Therefore, a crucial underlying assumption is that the ecological mechanisms controlling tree establishment are similar at disturbed and undisturbed sites. I exploited the use of 1970 CORONA satellite imagery and 2003 aerial photography to map 33 years of changes in arboreal vegetation. I created detailed maps of abiotic variables from a LIDAR-based DEM and biotic variables from classified remotely sensed data. I linked tree establishment patterns with abiotic and biotic variables in a GIS, and analyzed the correlations with standard logistic regression and logistic regression in the hierarchical partitioning framework at multiple spatial resolutions. A biotic factor (proximity to previously existing trees) was found to exert a strong influence on tree establishment patterns; equaling and in most cases exceeding the significance of the abiotic factors. The abiotic setting was more important at restricted spatial extents near the extreme upper limits of the ecotone and when analyzing coarse resolution data, but even in these cases proximity to existing trees remained significant. The strong overall influence of proximity to existing trees on patterns of tree establishment is unequivocal. If the underlying assumption of this dissertation is true, it challenges the long-held ecological assumption that vegetation in mountainous terrain is in equilibrium with and most strongly influenced by the surrounding physical environment.

alpine treeline

tree establishment

hierarchical partitioning

hierarchical patch dynamics

Extensions of quantal problems

Acar, Emel

January 2000

No description available.

519.5

Quantum; Data; Hierarchical; Regression

A path-specific approach to SEIR modeling

Porter, Aaron Thomas

01 May 2012

Despite being developed in the late 1920s, compartmental epidemic modeling is still a rich and fruitful area of research. The original compartmental epidemic models were SIR (Susceptible, Infectious, Removed) models, which assume permanent immunity after recovery. SIR models, along with the more recent SEIR (Susceptible, Exposed, Infectious, Removed) models are still the gold standard in modeling pathogens that confer permanent immunity. This dissertation expands the SEIR structure to include a new class of spatial SEIR models. The exponential assumption of these models states that the latent and infectious times of the pathogen are exponentially distributed. Work that relaxes this assumption and still allows for mixing to occur at the population level is limited, thereby making strong assumptions about these times. We relax this assumption in a flexible way, by considering a hybrid approach that contains characteristics of both population level and individual level approaches. Next, we expand the Conditional Autoregressive (CAR) class of spatial models. This is to account for the Mumps data set we have procured, which contains mismatched lattice structures that cannot be handled by traditional CAR models. The use of CAR models is desirable here, as these models are known to produce spatial smoothing on lattices, and are a natural way to draw strength spatially in estimating spatial effects. Finally, we develop a pair of spatial SEIR models utilizing our CAR structure. The first utilizes the exponential assumption, which is very robust. The second develops a highly flexible spatial SEIR model by embedding the CAR structure into the SEIR structure. This allows for a realistic analysis of epidemic data occurring on a lattice. These models are applied to the Iowa Mumps epidemic of 2006. There are three questions of interest. First, what improvement do the methods proposed here provide over the current models in the literature? Second, did spring break, which occurred approximately 40 days into the epidemic, have an effect on the overall number of new infections? Thirdly, did the public's awareness of the epidemic change the rate at which mixing occurred over time? The spatial models in this dissertation are adequately constructed to answer these questions, and the results are provided.

Bayesian

CAR

Hierarchical

SEIR

Biostatistics

Responding to Joint Attention: Growth and Prediction to Subsequent Social Competence in Children Prenatally Exposed to Cocaine

Kolnik, Shira

01 January 2008

Responding to Joint Attention (RJA) involves an infant's ability to follow a gaze or point by a partner. Prenatal cocaine exposure (PCE), which places a child in danger of numerous risks, has been accepted as having subtle effects on developmental outcomes such as social competence and associated socio-emotional outcomes. The current study looked at a sample of 166 children prenatally exposed to cocaine who were attending an early intervention program. The study established group and individual trajectories of responding to joint attention from 12, 15, and 18 months of age. Hierarchical modeling identified two groups, a delay group and an average group, while individual trajectories identified a linear pattern of growth of RJA. Both individual and group trajectories indicated that children with higher RJA from 12 to 18 months demonstrated better social competence at three years of age and first grade. The delay and average group showed significant differences on later social competence measures, but not problem behaviors, such that RJA, a positive behavior, may connect more closely with later positive behaviors than with behavior problems. RJA may therefore be useful in a preventative intervention targeted at enhancing positive social behaviors and as an important and simple screening tool for possible delay early in a child's life, helping to deliver early intervention services in a targeted and effective manner.

A formula for low achievement: using multi-level models to understand the impact of individual level effects and school level effects on mathematics achievement

Parks, Kathrin Ann

30 September 2004

The following study utilizes data from the High School and Beyond Study in order to predict mathematics achievement using both student characteristics and school level characteristics. Utilizing Hierarchical Linear Modeling, this study extends the body of literature by exploring how race, socio-economic status, and gender, as well as the percentage of minority students in a school, whether or not the school is Catholic, the proportion of students in the academic track, and the mean socioeconomic status of the school all affect mathematics achievement. Through this methodology, it was possible to see the direct effects of both student level and school level variables on achievement, as well as the cross-level interaction of all of these variables. Findings suggest that there are discrepancies in how different types of students achieve, as well as how those students achieve in varying contexts. Many of the variables were statistically significant in their effect on mathematics achievement. Implications for this research are discussed and considerations for future research are presented.

Mathematics Achievement

Hierarchical Linear Models

A Confidence-based Hierarchical Word Clustering for Document Classification

Yin, Kai-Tai

09 August 2007

We propose a novel feature reduction approach to group words hierarchically into clusters which can then be used as new features for document classification. Initially, each word constitutes a cluster. We calculate the mutual confidence between any two different words. The pair of clusters containing the two words with the highest mutual confidence are combined into a new cluster. This process of merging is iterated until all the mutual confidences between the un-processed pair of words are smaller than a predefined threshold or only one cluster exists. In this way, a hierarchy of word clusters is obtained. The user can decide the clusters, from a certain level, to be used as new features for document classification. Experimental results have shown that our method can perform better than other methods.

Classification

Word Clustering

Confidence

Hierarchical

物理環境の階層構造を考慮した魚類生息場評価法の開発

知花, 武佳, CHIBANA, Takeyoshi, 辻本, 哲郎, TSUJIMOTO, Tetsuro, 玉井, 信行, TAMAI, Nobuyuki

02 1900

No description available.

PHABSIM

Fish Habitat

Hierarchical Structure

Hierarchical control of the Atlas experiment.

Barriuso Poy, Alejandro

14 May 2007

Hierarchical Control of the ATLAS experimentÀlex Barriuso PoyEls sistemes de control emprats en nous experiments de física d'altes energies són cada dia més complexos a conseqüència de la mida, volum d'informació i complexitat inherent a la instrumentació del detectors. En concret, aquest fet resulta visible en el cas de l'experiment ATLAS (A Toroidal LHC ApparatuS) situat dins del nou accelerador de partícules LHC (Large Hadron Collider) al CERN. ATLAS és el detector de partícules més gran mai construït fruit d'una col·laboració internacional on participen més de 150 instituts i laboratoris d'arreu del món. L'experiment estudia col·lisions protó-protó i, seguint l'estructura clàssica d'un detector de partícules, es composa d'una sèrie de sub-detectors especialitzats i d'un sistema d'imants superconductors que confereixen camp magnètic a l'experiment.Concernent l'operació de ATLAS, existeixen dos sistemes integradors principals. Per una banda, el sistema DAQ (Data AdQuisition) realitza l'adquisició de dades per els conseqüents estudis de física. Per altra banda, el DCS (Detector Control System) s'encarrega d' assegurar la coherent operació de tot l'experiment. Tot i ser dos sistemes independents, ambdós es complementen. Mentre un gestiona les dades utilitzades per als consegüents estudis de física, l'altre gestiona tota la infrastructura relacionada amb l'estat operacional del detector assegurant així la correcta extracció de informació.El DCS, principal argument d'aquesta tesi, supervisa tot el hardware dins al complex de l'experiment incloent tots els serveis dels sub-detectors (ex. alta i baixa tensió, refrigeració, etc.) i la infrastructura general de l'experiment (ex. condicions ambientals). El DCS també és la interfície amb els sistemes externs a l'experiment com per exemple els serveis tècnics CERN (ex. ventilació o electricitat) o, encara més crucial, amb l'accelerador LHC o el DAQ de ATLAS. En total, al voltant de 200.000 canals d'informació seran supervisats en tot moment per el DCS.Un dels principals problemes existents en anteriors experiments era la manca d'estandardització en moltes àrees. Per exemple, degut a l'escenari tècnic de l'època, els sistemes de control a l'era LEP (1989-2000) utilitzaven diferents llenguatges de programació, diferents protocols de comunicació i hardware 'fet a mida'. Com a conseqüència, el desenvolupament i manteniment del DCS era en molts casos una tasca difícil. Amb la intenció de solventar els problemes del passat, el projecte JCOP va ser creat al CERN a finals de 1997. Els diferents sub-detectors de ATLAS (així com dels 3 altres principals experiments del LHC) estan composats de múltiples equips de persones treballant en paral·lel. L'objectiu principal del JCOP és treballar en comú per reduir duplicitat i, al mateix temps, facilitar la integració i futur manteniment dels experiments. D'aquesta manera, components sovint utilitzats per al control de plantes industrials com PLCs, 'fieldbuses', el protocol OPC o SCADA han estat instaurats i són utilitzats amb èxit als experiments. Al mateix temps, el JCOP combina els productes comercials existents amb elements hardware i software específicament creats per al seu ús dins el món del control d'experiments de física d'altes energies. Aquest és el cas del software anomenat FSM (Finite State Machine).El modelatge i integració dels molts dispositius distribuïts que coexisteixen al DCS es realitza utilitzant la FSM. D'aquesta manera, el control s'estableix mitjançant entitats software distribuïdes, autònomes i cooperatives que són organitzades jeràrquicament i segueixen una lògica de màquines finites d'estats. L'eina FSM combina dues tecnologies principals: SMI++ (State Manager Interface toolkit) i un producte SCADA comercial. SMI++ (escrit en C++) ja ha estat utilitzat amb èxit en dos experiments de física d'altes energies anteriors a ATLAS proveint la següent funcionalitat: un llenguatge orientat a objectes, una lògica de màquina finita d'estats, un sistema expert basat en regles, i un protocol de comunicació independent de la plataforma utilitzada. Aquesta funcionalitat s'aplica doncs a tots els nivells d'operació/abstracció de l'experiment (ex. des d'una vàlvula d'un sistema de refrigeració fins a tot ATLAS). Així i, basant-se en regles establertes i acurades inter-connexions que organitzen els objectes jeràrquicament, s'assoleix l'automatització global de l'experiment.Aquesta tesi presenta la integració del ATLAS DCS dins una jerarquia de control seguint la segmentació natural de l'experiment en sub-detectors i sub-sistemes. La integració final dels molts sistemes que formen el DCS a ATLAS inclou tasques com: l'organització del software de control, la identificació de models dels processos, l'automatització de processos, la detecció d'errors, la sincronització amb DAQ, i la interfície amb l'usuari.Tot i que l'experiència adquirida al passat amb la utilització de SMI++ és bon punt de partença per al disseny de la jerarquia de control de ATLAS, nous requisits han aparegut degut a la complexitat i mida de l'experiment. Així, l'escalabilitat de l'eina ha estat estudiada per afrontar el fet de què la jerarquia de control final a ATLAS serà centenars de cops més gran que cap dels dos antecedents existents. Una solució comú per a tots els sistemes que formen el DCS ha estat creada amb el principal objectiu d'assolir una certa homogeneïtat entre les diferents parts. Així, una arquitectura basada en 3 nivells funcionals organitza els sistemes pertanyents als 12 sub-detectors de l'experiment. Seguint aquesta arquitectura, les diferents funcions i parts del DCS han estat modelades amb una 'granularitat' similar entre sub-detectors, la qual cosa, ens ha portat a l'obtenció de jerarquies de control isomorfes.La detecció, monitorització i diagnòstic d'errors és una part essencial per l'operació i coordinació de tasques de qualsevol experiment de física d'altes energies o planta industrial. La presència d'errors al sistema distorsiona l'operació i pot invalidar els càlculs realitzats per a la recerca de física. Per aquest motiu, una estratègia estàndard i una interfície estàndard amb l'usuari han estat definides donant èmfasi a la ràpida detecció, monitorització i diagnòstic dels errors basant-se en un mecanisme dinàmic de tractament d'errors. Aquests nou mecanisme es basa en la creació de dos camins de comunicació (o jerarquies paral·leles) que, al mateix temps que tracten els errors, donen una descripció més clara de les condicions d'operació de l'experiment. Així, un dels camins de comunicació està poblat per objectes dedicats a la detecció i anàlisi dels errors, mentre a l'altre, els objectes comanden l'operació de l'experiment. Aquests dos camins paral·lels cooperen i contenen la lògica que descriu l'automatització de processos al DCS. Així, els diferents objectes segueixen unes màquines finites de estats preestablertes per ATLAS que faciliten la comprensió i futur desenvolupament del DCS. A més, el fet de què l'estratègia proposada agrupi i resumi els errors d'una forma jeràrquica, facilita notablement l'anàlisi d'aquests errors en un sistema de la mida d'ATLAS. L'estratègia proposada, modular i distribuïda, ha estat validada mitjançant nombrosos tests. El resultat ha estat una substancial millora en la funcionalitat mantenint, al mateix temps, unacorrecta gestió dels recursos existents. Aquesta estratègia ha estat implementada amb èxit i constitueix l'estàndard emprat a ATLAS per a la creació de la jerarquia de control.Durant l'operació de l'experiment, el DCS s'ha de sincronitzar amb els sistema DAQ a càrrec del procés de presa de dades per als conseqüents estudis de física. L'automatització de processos d'ambdós sistemes, DAQ i DCS, segueixen una lògica similar basada en una jerarquia de màquines finites d'estats (similituds i diferències han estat identificades i presentades). Tot i això, la interacció entre els dos principals sistemes integradors de ATLAS ha estat fins el moment limitada, però aproximant-se a l'inici d'operacions, esdevé cada dia més important. Així, un mecanisme de sincronització que estableix connexions entre els diferents segments dels sistema DAQ i la jerarquia de control del DCS ha estat desenvolupat. La solució adoptada insereix automàticament objectes SMI++ dins la jerarquia de control del DCS. Aquests objectes permeten a les aplicacions del DAQ comandar diferents seccions del DCS d'una forma independent i transparent. Al mateix temps, el mecanisme no permet prendre dades per física quan una part del detector funciona d'una forma incorrecta evitant així l'extracció d'informació corrupta mentre l'experiment torna a un estat segur. Un prototip que assoleix la sincronització dels dos sistemes ha estat implementat i validat, i ja està llest per a ésser utilitzat durant la integració dels sub-detectors.Finalment, la interfície situada a la sala de control entre el DCS i l'usuari ha estat implementada. D'aquesta manera, es completa la integració de les diferents parts del DCS. Els principals reptes solventats durant les fases de disseny i desenvolupament de la interfície han estat: permetre a l'operador controlar un procés de la mida de ATLAS, permetre la integració i manteniment dels molts diferents 'displays' d'operador que pertanyen als diferents sub-detectors i, donar la possibilitat a l'operador de navegar ràpidament entre les diferents parts del DCS. Aquestes qüestions han estat solventades combinant la funcionalitat del sistema SCADA amb la eina FSM. La jerarquia de control es utilitzada per la interfície per estructurar d'una forma intuïtiva els diferent 'displays' que formen el DCS. Llavors, tenint en compte que cada node de la jerarquia representa una porció susceptible de ser controlada independentment, hem assignat a cada node un 'display' que conté la informació del seu nivell d'abstracció dins la jerarquia. Tota la funcionalitat representada dins la jerarquia de control és accessible dins els 'displays' SCADA mitjançant dispositius gràfics especialment implementats. Utilitzant aquest dispositius gràfics, per una banda possibilitem que els diferents 'displays' s'assimilin en la seva forma, i així, facilitem la comprensió i utilització de la interfície per part del usuari. Per altra banda, els estats, transicions i accions que han estat definits per els objectes SMI++ són fàcilment visibles dins la interfície. D'aquesta manera, en cas de una possible evolució del DCS, el desenvolupament necessari per adequar la interfície es redueix notablement. A més, un mecanisme de navegació ha estat desenvolupat dins la interfície fent accessible a l'operador ràpidament qualsevol sistema dins la jerarquia. La jerarquia paral·lela dedicada al tractament d'errors també és utilitzada dins la interfície per filtrar errors i accedir als sistemes en problemes de una manera eficient. La interfície és suficientment modular i flexible, permet ésser utilitzada en nous escenaris d'operació, resol les necessitats de diferents tipus d'usuaris i facilita el manteniment durant la llarga vida de l'experiment que es preveu fins a 20 anys. La consola està sent utilitzada des de ja fa uns mesos i actualment totes les jerarquies dels sub-detectors estan sent integrades. / Hierarchical Control of the ATLAS experimentÀlex Barriuso PoyControl systems at High Energy Physics (HEP) experiments are becoming increasingly complex mainly due to the size, complexity and data volume associated to the front-end instrumentation. In particular, this becomes visible for the ATLAS experiment at the LHC accelerator at CERN. ATLAS will be the largest particle detector ever built, result of an international collaboration of more than 150 institutes. The experiment is composed of 9 different specialized sub-detectors that perform different tasks and have different requirements for operation. The system in charge of the safe and coherent operation of the whole experiment is called Detector Control System (DCS).This thesis presents the integration of the ATLAS DCS into a global control tree following the natural segmentation of the experiment into sub-detectors and smaller sub-systems. The integration of the many different systems composing the DCS includes issues such as: back-end organization, process model identification, fault detection, synchronization with external systems, automation of processes and supervisory control.Distributed control modeling is applied to the widely distributed devices that coexist in ATLAS. Thus, control is achieved by means of many distributed, autonomous and co-operative entities that are hierarchically organized and follow a finite-state machine logic.The key to integration of these systems lies in the so called Finite State Machine tool (FSM), which is based on two main enabling technologies: a SCADA product, and the State Manager Interface (SMI++) toolkit. The SMI++ toolkit has been already used with success in two previous HEP experiments providing functionality such as: an object-oriented language, a finite-state machine logic, an interface to develop expert systems, and a platform-independent communication protocol. This functionality is then used at all levels of the experiment operation process, ranging from the overall supervision down to device integration, enabling the overall sequencing and automation of the experiment.Although the experience gained in the past is an important input for the design of the detector's control hierarchy, further requirements arose due to the complexity and size of ATLAS. In total, around 200.000 channels will be supervised by the DCS and the final control tree will be hundreds of times bigger than any of the antecedents. Thus, in order to apply a hierarchical control model to the ATLAS DCS, a common approach has been proposed to ensure homogeneity between the large-scale distributed software ensembles of sub-detectors. A standard architecture and a human interface have been defined with emphasis on the early detection, monitoring and diagnosis of faults based on a dynamic fault-data mechanism. This mechanism relies on two parallel communication paths that manage the faults while providing a clear description of the detector conditions. The DCS information is split and handled by different types of SMI++ objects; whilst one path of objects manages the operational mode of the system, the other is dedicated to handle eventual faults. The proposed strategy has been validatedthrough many different tests with positive results in both functionality and performance. This strategy has been successfully implemented and constitutes the ATLAS standard to build the global control tree.During the operation of the experiment, the DCS, responsible for the detector operation, must be synchronized with the data acquisition system which is in charge of the physics data taking process. The interaction between both systems has so far been limited, but becomes increasingly important as the detector nears completion. A prototype implementation, ready to be used during the sub-detector integration, has achieved data reconciliation by mapping the different segments of the data acquisition system into the DCS control tree. The adopted solution allows the data acquisition control applications to command different DCS sections independently and prevents incorrect physics data taking caused by a failure in a detector part.Finally, the human-machine interface presents and controls the DCS data in the ATLAS control room. The main challenges faced during the design and development phases were: how to support the operator in controlling this large system, how to maintain integration across many displays, and how to provide an effective navigation. These issues have been solved by combining the functionalities provided by both, the SCADA product and the FSM tool. The control hierarchy provides an intuitive structure for the organization of many different displays that are needed for the visualization of the experiment conditions. Each node in the tree represents a workspace that contains the functional information associated with its abstraction level within the hierarchy. By means of an effective navigation, any workspace of the control tree is accessible by the operator or detector expert within a common human interface layout. The interface is modular and flexible enough to be accommodated to new operational scenarios, fulfil the necessities of the different kind of users and facilitate the maintenance during the long lifetime of the detector of up to 20 years. The interface is in use since several months, and the sub-detector's control hierarchies, together with their associated displays, are currently being integrated into the common human-machine interface.

Hierarchical

control of the atlas experiment

621.3

Backbone Ad Hoc Networks using Two-Tier Routing

Liao, Chun-kai

11 January 2005

In this paper, a mobile network is combined with backbone structure to form a hierarchical ad hoc network. Usually, a mobile ad hoc network is assumed to be homogeneous such that each mobile node uses the same radio capability. However, a homogenous ad hoc network suffers from poor scalability. In this thesis we establish a physical (not logical) hierarchical network to solve this problem in which backbone nodes are employed to transmit for long distance using larger radio power at high tier and cluster structure is used to efficiently utilize resources in a wide and dynamic network. We propose a cluster head determination scheme based on the degree variations of nodes. The nodes with minimum degree variation in the neighborhood are considered more stable and will be selected as the cluster heads. The cluster heads form the backbone nodes and other nodes are the cluster members. The information of cluster members and the nodes in neighboring clusters are recorded in a table of cluster head. According to the information, we have the knowledge of whether the destination node is close to the source node and can determine how to route the transmission. Routing is divided into low tier and high tier routing to relieve the workload of backbone network. The simulation results demonstrate that the proposed hierarchical routing in two tiers (HRTT) improves some problems occurred in the flat network.

Ad Hoc Networks

Backbone

Hierarchical