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Several governmental organizations all over the world aim for algorithmic accountability of artificial intelligence systems. However, there are few specific proposals on how exactly to achieve it. This article provides an extensive overview of possible transparency and inspectability mechanisms that contribute to accountability for the technical components of an algorithmic decision-making system. Following the different phases of a generic software development process, we identify and discuss several such mechanisms. For each of them, we give an estimate of the cost with respect to time and money that might be associated with that measure.
Editorial
(2020)
In many applications, visual analytics (VA) has developed into a standard tool to ease data access and knowledge generation. VA describes a holistic cycle transforming data into hypothesis and visualization to generate insights that enhance the data. Unfortunately, many data sources used in the VA process are affected by uncertainty. In addition, the VA cycle itself can introduce uncertainty to the knowledge generation process but does not provide a mechanism to handle these sources of uncertainty. In this manuscript, we aim to provide an extended VA cycle that is capable of handling uncertainty by quantification, propagation, and visualization, defined as uncertainty-aware visual analytics (UAVA). Here, a recap of uncertainty definition and description is used as a starting point to insert novel components in the visual analytics cycle. These components assist in capturing uncertainty throughout the VA cycle. Further, different data types, hypothesis generation approaches, and uncertainty-aware visualization approaches are discussed that fit in the defined UAVA cycle. In addition, application scenarios that can be handled by such a cycle, examples, and a list of open challenges in the area of UAVA are provided.
Dataflow process networks (DPNs) are intrinsically data-driven, i.e., node actions are not synchronized among each other and may fire whenever sufficient input operands arrived at a node. While the general model of computation (MoC) of DPNs does not impose further restrictions, many different subclasses of DPNs representing different dataflow MoCs have been considered over time. These classes mainly differ in the kinds of behaviors of the processes. A DPN may be heterogeneous in that different processes in the network belong to different classes of DPNs. A heterogeneous DPN can therefore be effectively used to model and to implement different components of a system with different kinds of processes and, therefore, different dataflow MoCs. This paper presents a model-based design based on different dataflow MoCs including their heterogeneous combinations. In particular, it covers the automatic software synthesis of systems from DPN models. The main objective is to validate, evaluate and compare the artifacts exhibited by different dataflow MoCs at the implementation level of systems under the supervision of a common design tool. Moreover, this work also offers an efficient synthesis method that targets and exploits heterogeneity in DPNs by generating implementations based on the kinds of behaviors of the processes. The proposed synthesis method provides a tool chain including different specialized code generators for specific dataflow MoCs, and a runtime system that finally maps models using a combination of different dataflow MoCs on cross-vendor target hardware.
This paper presents an iterative finite element (FE)–based method to calculate the gravity-free shape of nonrigid parts from
an optical measurement performed on a non-over-constrained fixture. Measuring these kinds of parts in a stress-free state
is almost impossible because deflections caused by their weight occur. To solve this problem, a simulation model of the
measurement is created using available methods of reverse engineering. Then, an iterative algorithm calculates the gravityfree
shape. The approach does not require a CAD model of the measured part, implying the whole part can be fully scanned.
The application of this method mainly addresses thin, unstable sheet metal parts, like those commonly used in the automotive
or aerospace industry. To show the performance of the proposed method, validations with simulation and experimental
data are presented. The shown results meet the predefined quality goal to predict shapes within a tolerance of ±0.05 mm
measured in surface normal direction.
We propose a universal method for the evaluation of generalized standard materials that greatly simplifies the material law implementation process. By means of automatic differentiation and a numerical integration scheme, AutoMat reduces the implementation effort to two potential functions. By moving AutoMat to the GPU, we close the performance gap to conventional evaluation routines and demonstrate in detail that the expression level reverse mode of automatic differentiation as well as its extension to second order derivatives can be applied inside CUDA kernels. We underline the effectiveness and the applicability of AutoMat by integrating it into the FFT-based homogenization scheme of Moulinec and Suquet and discuss the benefits of using AutoMat with respect to runtime and solution accuracy for an elasto-viscoplastic example.
When considering complex systems, identifying the most important actors is often of relevance. When the system is modeled
as a network, centrality measures are used which assign each node a value due to its position in the network. It is often
disregarded that they implicitly assume a network process flowing through a network, and also make assumptions of how
the network process flows through the network. A node is then central with respect to this network process (Borgatti in Soc
Netw 27(1):55–71, 2005, https ://doi.org/10.1016/j.socne t.2004.11.008). It has been shown that real-world processes often
do not fulfill these assumptions (Bockholt and Zweig, in Complex networks and their applications VIII, Springer, Cham,
2019, https ://doi.org/10.1007/978-3-030-36683 -4_7). In this work, we systematically investigate the impact of the measures’
assumptions by using four datasets of real-world processes. In order to do so, we introduce several variants of the betweenness
and closeness centrality which, for each assumption, use either the assumed process model or the behavior of the real-world
process. The results are twofold: on the one hand, for all measure variants and almost all datasets, we find that, in general,
the standard centrality measures are quite robust against deviations in their process model. On the other hand, we observe a
large variation of ranking positions of single nodes, even among the nodes ranked high by the standard measures. This has
implications for the interpretability of results of those centrality measures. Since a mismatch of the behaviour of the real
network process and the assumed process model does even affect the highly-ranked nodes, resulting rankings need to be
interpreted with care.
Since the h-index has been invented, it is the most frequently discussed bibliometric value and one of the most commonly used metrics to quantify a researcher’s scientific output. The more it is increasingly gaining popularity to use the metric as an indication of the quality of a job applicant or an employee the more important it is to assure its correctitude. Many platforms offer the h-index of a scientist as a service, sometimes without the explicit knowledge of the respective person. In this article we show that looking up the h-index for a researcher on the five most commonly used platforms, namely AMiner, Google Scholar, ResearchGate, Scopus and Web of Science, results in a variance that is in many cases as large as the average value. This is due to the varying definitions of what a scientific article is, the underlying data basis, and different qualities of the entity recognition problem. To perform our study, we crawled the h-index of the worlds top researchers according to two different rankings, all the Nobel Prize laureates except Literature and Peace, and the teaching staff of the computer science department of the TU Kaiserslautern Germany with whom we additionally computed their h-index manually. Thus we showed that the individual h-indices differ to an alarming extent between the platforms. We observed that researchers with an extraordinary high h-index and researchers with an index appropriate to the scientific career path and the respective scientific field are affected alike by these problems.
Kinetic models of human motion rely on boundary conditions which are defined by the interaction of the body with its environment. In the simplest case, this interaction is limited to the foot contact with the ground and is given by the so called ground reaction force (GRF). A major challenge in the reconstruction of GRF from kinematic data is the double support phase, referring to the state with multiple ground contacts. In this case, the GRF prediction is not well defined. In this work we present an approach to reconstruct and distribute vertical GRF (vGRF) to each foot separately, using only kinematic data. We propose the biomechanically inspired force shadow method (FSM) to obtain a unique solution for any contact phase, including double support, of an arbitrary motion. We create a kinematic based function, model an anatomical foot shape and mimic the effect of hip muscle activations. We compare our estimations with the measurements of a Zebris pressure plate and obtain correlations of 0.39≤r≤0.94 for double support motions and 0.83≤r≤0.87 for a walking motion. The presented data is based on inertial human motion capture, showing the applicability for scenarios outside the laboratory. The proposed approach has low computational complexity and allows for online vGRF estimation.
Background: The use of health apps to support the treatment of chronic pain is gaining importance. Most available pain management apps are still lacking in content quality and quantity as their developers neither involve health experts to ensure target group suitability nor use gamification to engage and motivate the user. To close this gap, we aimed to develop a gamified pain management app, Pain-Mentor.
Objective: To determine whether medical professionals would approve of Pain-Mentor’s concept and content, this study aimed to evaluate the quality of the app’s first prototype with experts from the field of chronic pain management and to discover necessary improvements.
Methods: A total of 11 health professionals with a background in chronic pain treatment and 2 mobile health experts participated in this study. Each expert first received a detailed presentation of the app. Afterward, they tested Pain-Mentor and then rated its quality using the mobile application rating scale (MARS) in a semistructured interview.
Results: The experts found the app to be of excellent general (mean 4.54, SD 0.55) and subjective quality (mean 4.57, SD 0.43). The app-specific section was rated as good (mean 4.38, SD 0.75). Overall, the experts approved of the app’s content, namely, pain and stress management techniques, behavior change techniques, and gamification. They believed that the use of gamification in Pain-Mentor positively influences the patients’ motivation and engagement and thus has the potential to promote the learning of pain management techniques. Moreover, applying the MARS in a semistructured interview provided in-depth insight into the ratings and concrete suggestions for improvement.
Conclusions: The experts rated Pain-Mentor to be of excellent quality. It can be concluded that experts perceived the use of gamification in this pain management app in a positive manner. This showed that combining pain management with gamification did not negatively affect the app’s integrity. This study was therefore a promising first step in the development of Pain-Mentor.