2,299 research outputs found
A model for choice infrastructure: looking beyond choice architecture in Behavioral Public Policy
Interventions that tackle ‘last mile’ behaviors in the form of improved choice architecture are fundamental to Behavioral Public Policy (BPP), yet far less attention is typically paid to the nature and design of underlying system conditions and infrastructures that support these interventions. However, inattention to broader conditions that impact participant engagement and intervention functionality, such as barriers to access that deter participa- tion or perverse structural disincentives that reward undesirable behaviors, may not only limit the effectiveness of behavioral solutions but also miss opportunities to deliberately design underlying ‘plumbing’ – the choice infrastructure – in a way that improves overall system efficacy and equity. Using the illustrative case of civic policy in food licensure, this article describes how using a ‘SPACE’ model to address Standards, Process mechanics and policies, Accountability, Culture within systems, and Evaluative and iterative feedback can support the development of improved choice infrastructure, contributing to BPP problem- solving efforts by helping practitioners create system conditions that are more conducive to the success of behavioral solutions
Computational and wind tunnel studies of shelterbelts for reduction of wind flow and wind-induced loads on low-rise buildings
Numerical and experimental tests were done to determine the optimum design parameters of a shelterbelt for wind damage mitigation to structures behind the shelterbelt. The Wang and Takle shelterbelt numerical model was used to study the shelterbelt\u27s cross-sectional shape, height, spacing/line tightness, density/density distribution, line width, number of lines, and wind speed parameters. The numerical model was also used to study the effectiveness of more realistically shaped shelterbelt tree lines, rather than using the traditional blocks to represent each line of trees in the shelterbelt. Finally, experiments were conducted in a wind tunnel to test the effects of wind-induced load reduction with the implementation of a shelterbelt screen, studying forces rather than flow fields
Exploring a Behavioral Model of "Positive Friction" in Human-AI Interaction
Designing seamless, frictionless user experiences has long been a dominant
trend in both applied behavioral science and artificial intelligence (AI), in
which the goal of making desirable actions easy and efficient informs efforts
to minimize friction in user experiences. However, in some settings, friction
can be genuinely beneficial, such as the insertion of deliberate delays to
increase reflection, preventing individuals from resorting to automatic or
biased behaviors, and enhancing opportunities for unexpected discoveries. More
recently, the popularization and availability of AI on a widespread scale has
only increased the need to examine how friction can help or hinder users of AI;
it also suggests a need to consider how positive friction can benefit AI
practitioners, both during development processes (e.g., working with diverse
teams) and to inform how AI is designed into offerings. This paper first
proposes a "positive friction" model that can help characterize how friction is
currently beneficial in user and developer experiences with AI, diagnose the
potential need for friction where it may not yet exist in these contexts, and
inform how positive friction can be used to generate solutions, especially as
advances in AI continue to be progress and new opportunities emerge. It then
explores this model in the context of AI users and developers by proposing the
value of taking a hybrid "AI+human" lens, and concludes by suggesting questions
for further exploration.Comment: This preprint has not undergone peer review or any post-submission
corrections. The Version of Record of this contribution will be published in
Springer Nature Computer Science book series in Volume HCI International 202
Behavioral planning: Improving behavioral design with “roughly right” foresight
Many challenges emerging from the current COVID-19 pandemic are behavioral in nature, which has prompted the field of behavioral design to propose solutions for issues as wide-ranging as hand-washing, wearing masks, and the adoption of new norms for staying and working from home. On the whole, however, these behavioral interventions have been somewhat underwhelming, exposing an inherent brittleness that comes from three common “errors of projection” in current behavioral design methodology: projected stability, which insufficiently plans for the fact that interventions often function within inherently unstable systems; projected persistence, which neglects to account for changes in those system conditions over time; and projected value, which assumes that definitions of success are universally shared across contexts. Borrowing from strategic design and futures thinking, a new proposed strategic foresight model—behavioral planning—can help practitioners better address these system-level, anticipatory, and contextual weaknesses by more systematically identifying potential forces that may impact behavioral interventions before they have been implemented. Behavioral planning will help designers more effectively elicit signals indicating the emergence of forces that may deform behavioral interventions in emergent COVID-19 contexts, and promote “roughly right” directional solutions at earlier stages in solution development to better address system shifts
Combining X-ray CT and 3D printing technology to produce microcosms with replicable, complex pore geometries
Measurements in soils have been traditionally used to demonstrate that soil architecture is one of the key drivers of soil processes. Major advances in the use of X-ray Computed Tomography (CT) afford significant insight into the pore geometry of soils, but until recently no experimental techniques were available to reproduce this complexity in microcosms. This article describes a 3D additive manufacturing technology that can print physical structures with pore geometries reflecting those of soils. The process enables printing of replicated structures, and the printing materials are suitable to study fungal growth. This technology is argued to open up a wealth of opportunities for soil biological studies
Combination of techniques to quantify the distribution of bacteria in their soil microhabitats at different spatial scales
To address a number of issues of great societal concern at the moment, like the sequestration of carbon, information is direly needed about interactions between soil architecture and microbial dynamics. Unfortunately, soils are extremely complex, heterogeneous systems comprising highly variable and dynamic micro-habitats that have significant impacts on the growth and activity of inhabiting microbiota. Data remain scarce on the influence of soil physical parameters characterizing the pore space on the distribution and diversity of bacteria. In this context, the objective of the research described in this article was to develop a method where X-ray microtomography, to characterize the soil architecture, is combined with fluorescence microscopy to visualize and quantify bacterial distributions in resin-impregnated soil sections. The influence of pore geometry (at a resolution of 13.4 μm) on the distribution of Pseudomonas fluorescens was analysed at macro- (5.2 mm × 5.2 mm), meso- (1 mm × 1 mm) and microscales (0.2 mm × 0.2 mm) based on an experimental setup simulating different soil architectures. The cell density of P. fluorescens was 5.59 x 107(SE 2.6 x 106) cells g−1 soil in 1–2 mm and 5.84 x 107(SE 2.4 x 106) cells g−1 in 2–4 mm size aggregates soil. Solid-pore interfaces influenced bacterial distribution at micro- and macroscale, whereas the effect of soil porosity on bacterial distribution varied according to three observation scales in different soil architectures. The influence of soil porosity on the distribution of bacteria in different soil architectures was observed mainly at the macroscale, relative to micro- and mesoscales. Experimental data suggest that the effect of pore geometry on the distribution of bacteria varied with the spatial scale, thus highlighting the need to consider an “appropriate spatial scale” to understand the factors that regulate the distribution of microbial communities in soils. The results obtained to date also indicate that the proposed method is a significant step towards a full mechanistic understanding of microbial dynamics in structured soils
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