425 research outputs found
Acoustic Analysis of Enclosed Sound Space as well as Its Coupling with Flexible Boundary Structure
Combustion instability is often encountered in various power systems, a good understanding on the sound field in acoustic cavity as well as its coupling with boundary flexible structure will be of great help for the reliability design of such combustion system. An improved Fourier series method is presented for the acoustic/vibro-acoustic modelling of acoustic cavity as well as the panel-cavity coupling system. The structural-acoustic coupling system is described in a unified pattern using the energy principle. With the aim to construct the admissible functions sufficiently smooth for the enclosed sound space as well as the flexible boundary structure, the boundary-smoothed auxiliary functions are introduced to the standard multi-dimensional Fourier series. All the unknown coefficients and higher order variables are determined in conjunction with Rayleigh-Ritz procedure and differential operation term by term. Numerical examples are then presented to show the correctness and effectiveness of the current model. The model is verified through the comparison with those from analytic solution and other approaches. Based on the model established, the influence of boundary conditions on the acoustic and/or vibro-acoustic characteristics of the structural-acoustic coupling system is addressed and investigated
A Rare Root Canal Configuration of a Maxillary Second Molar with Fused C-shaped Buccal Root and Five Canals: A Case Report and Review of literature
Having a thorough knowledge of root canal configuration is essential for a successful endodontic treatment. Clinicians should always pay attention to the unusual canal configuration so as to avoid missing extra canals. This paper describes a non-surgical retreatment of a maxillary second molar with two missing root canals; diagnosed by cone-beam computed tomographic (CBCT) imaging. The tooth had three roots and five canals: a C-shaped buccal root fused by mesiobuccal (MB) and distobuccal (DB) roots with three canals (CBCT scanning showed that the second MB canal was closer to the palatal than the buccal side), a mesiopalatal root with one canal, and a distopalatal root with one canal. The purpose of this case report is to remind clinicians of the importance of anatomical variations, and thus, detection of extra canals.Keywords: Maxillary Second Molar; C-shaped Canal; Cone-Beam Computed Tomograph
Complexity-aware Large Scale Origin-Destination Network Generation via Diffusion Model
The Origin-Destination~(OD) networks provide an estimation of the flow of
people from every region to others in the city, which is an important research
topic in transportation, urban simulation, etc. Given structural regional urban
features, generating the OD network has become increasingly appealing to many
researchers from diverse domains. However, existing works are limited in
independent generation of each OD pair, i.e., flow of people from one region to
another, overlooking the relations within the overall network. In this paper,
we instead propose to generate the OD network, and design a graph denoising
diffusion method to learn the conditional joint probability distribution of the
nodes and edges within the OD network given city characteristics at region
level. To overcome the learning difficulty of the OD networks covering over
thousands of regions, we decompose the original one-shot generative modeling of
the diffusion model into two cascaded stages, corresponding to the generation
of network topology and the weights of edges, respectively. To further
reproduce important network properties contained in the city-wide OD network,
we design an elaborated graph denoising network structure including a node
property augmentation module and a graph transformer backbone. Empirical
experiments on data collected in three large US cities have verified that our
method can generate OD matrices for new cities with network statistics
remarkably similar with the ground truth, further achieving superior
outperformance over competitive baselines in terms of the generation realism.Comment: 11 pagers, 5 figure
Youla-Kucera parameterized adaptive tracking control for optical data storage systems
In the next generation optical data storage systems, the tolerance of the tracking error will become even smaller under various unknown working situations. However, the unknown external disturbances caused by vibrations make it difficult to maintain the desired tracking precision during normal disk operation. It is proposed in this paper to use an adaptive regulation approach to maintain the tracking error below its desired value despite these unknown disturbances. The design of the regulator is formulated by augmenting a base controller into a Youla-Kucera (Q) parameterized set of stabilizing controllers so that both the deterministic and the random disturbances can be deal with properly. The adaptive algorithm is developed to search the desired Q parameter which satisfies the Internal Model Principle and thus the exact regulation against the unknown deterministic disturbance can be achieved. The performance of the proposed control approach is evaluated with experimental results that illustrate the capability of the proposed adaptive regulator to attenuate the unknown disturbances and achieve the desired tracking precision
Towards Generative Modeling of Urban Flow through Knowledge-enhanced Denoising Diffusion
Although generative AI has been successful in many areas, its ability to
model geospatial data is still underexplored. Urban flow, a typical kind of
geospatial data, is critical for a wide range of urban applications. Existing
studies mostly focus on predictive modeling of urban flow that predicts the
future flow based on historical flow data, which may be unavailable in
data-sparse areas or newly planned regions. Some other studies aim to predict
OD flow among regions but they fail to model dynamic changes of urban flow over
time. In this work, we study a new problem of urban flow generation that
generates dynamic urban flow for regions without historical flow data. To
capture the effect of multiple factors on urban flow, such as region features
and urban environment, we employ diffusion model to generate urban flow for
regions under different conditions. We first construct an urban knowledge graph
(UKG) to model the urban environment and relationships between regions, based
on which we design a knowledge-enhanced spatio-temporal diffusion model
(KSTDiff) to generate urban flow for each region. Specifically, to accurately
generate urban flow for regions with different flow volumes, we design a novel
diffusion process guided by a volume estimator, which is learnable and
customized for each region. Moreover, we propose a knowledge-enhanced denoising
network to capture the spatio-temporal dependencies of urban flow as well as
the impact of urban environment in the denoising process. Extensive experiments
on four real-world datasets validate the superiority of our model over
state-of-the-art baselines in urban flow generation. Further in-depth studies
demonstrate the utility of generated urban flow data and the ability of our
model for long-term flow generation and urban flow prediction. Our code is
released at: https://github.com/tsinghua-fib-lab/KSTDiff-Urban-flow-generation
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