2012 [AS13b, Wal12a]. 2013 [Alv13, Bar13, Cam13, Car13, CCS13, Cut13, Edi14, Swe13]. 2014 [CDS13, DN14, ND14, Rod14, Tym14a]. 2015 [DeL14a, DeL14b, She15b]. 2016 [AT16a, CCV16, CCV17, MR15, SDCT16a, SDCT16c, She16a]. 2017 [DG17, EC17, Fit18b, MJ18, TCSM17, TCM17]. 2018 [BG18b, DD17, Dec19b, Gol18, JI18, MKMP18, MMK18, PQH17, She18]. 2019 [Cut19, FI19, HPQ19, MP19a, MPRM19, MP19b, MS19, Rod18, She19a]. 2020 [DH19].

/pdf/a-complete-bibliography-of-publications-in-sigcse-bulletin-1aolnsl5m4.pdf

A Complete Bibliography of Publications in SIGCSE Bulletin: 2000{2009

Experimental study of tyre/road contact forces in rolling conditions for noise prediction

Feedforward control of flexural waves propagating in a rectangular panel

Feedback control of wave propagation in a rectangular panel, Part 1: Theoretical investigation of fundamental characteristics

Feedforward active vibration control techniques aim at canceling vibrations occurring in a system by means of introducing intentional forces that generate destructively interfering vibrations. These forces are typically controlled using an adaptive filtering algorithm that tracks the system state in real time and seeks to minimize overall vibration. One important often-overlooked issue in such systems is related with the vibrations introduced by the adaptive control algorithm itself either during its transient learning phase or due to its nonideal characteristic. These vibrations may become very significant in several mechanical structures due to resonance phenomena. In this context, this work is dedicated to the development of an effective scheme for feedforward active vibration control that is capable of dealing with undesirable vibrations introduced by the adaptive controller. A particular version of the filtered-x normalized least-mean-squares algorithm tailored to the proposed scheme is also developed. Results obtained from numerical simulation as well as from an experimental device are presented, aiming to demonstrate the effectiveness of the proposed scheme. 

A Novel Adaptive Scheme to Improve the Performance of Feedforward Active Vibration Control Systems

Active scattering control of flexural waves at beam junctions: The influence of beam properties on power flow and control effort

Feedforward control of bending waves in frequency domain at structural junctions using an impedance formulation

On the design of structural junctions for the purpose of hybrid passive-active vibration control

For all research that involves understanding of the contact between tyre and road surface, knowledge
of the tyres dynamical material properties is of importance. A method for identification of
the complex moduli, i.e. dynamic stiffness and damping, of rubber tread materials is presented.
The method is based on a velocity profile match between FE-models and measurements. The
measurements are conducted on beam-like samples with a laser Doppler vibrometer, giving only
insignificant errors due to measurement interference. The specified material parameters are updated
in the FE-model in order to minimise the sum of the squared errors between measured and
modelled velocity data. This optimisation problem is solved with a gradient descent algorithm,
where a one-dimensional wave model provides initial values. This identification method may
be used at higher frequencies for highly damped materials, and do not show the limitations of
methods only evaluating the material at resonance frequencies. The method gives a consistent
identification in a wide frequency range.

Identification of complex moduli for rubber compounds by minimisation of the error between measured and FE-modelled velocity profiles

The complementary advantages of active and passive vibration control have motivated research concerning hybrid configurations. Previous studies have mainly focused on active constrained layers (ACL). However, investigations pointing towards suboptimal performance of ACL have made it interesting to investigate other solutions. This thesis presents a theoretical approach to hybrid passive-active vibration control. The fundamental principle of the configuration investigated in this thesis is to use active control to force all wave power into a passive constrained layer (PCL). The approach is based on matching the impedance jump at the junction of an untreated beam and a beam treated with PCL. The theoretical results show that the active impedance load absorbs the major part of the incident wave power off-resonance, while it injects power at resonances. The incident wave power in addition to the power injected by the active impedance load is, at resonances, absorbed in the PCL.

An impedance approach to passive-active vibration control

Handle everyday research tasks with reliable, citation-backed results

Your personal Research Agent to handle research tasks with citation-backed results

Popular Tasks used by Researchers

How can I help with your research?

Meet SciSpace

Get more enhanced response by uploading the PDFs you want me to reference.

No relevant PDFs in your library

SciSpace is the AI research assistant for academics. Run systematic literature reviews on 280M+ papers, and write papers with cited sources. Trusted by 1M+ students, PhDs & researchers.

SciSpace | AI for Research

Analyze PDFs

Code & Manuscripts

Funding & Grants

Literature & Patents

Medical & Clinical Data

Systematic Review

Visualize & Present

Web & Data

Build a Google Scholar-like website for your research.

Build a website

Create charts and images for your research

Create a Chart

Write a paper for submission to a journal

Draft a manuscript

Patent Search

Design eye-catching scientific posters in minutes.

Scientific Poster Generation

Systematic Literature Review

One task is running at the moment. Your messages will be shown right after.

Drag and drop or click here to browse

Loved by <highlight>1 million+</highlight> researchers

Extract a list of specific topics and their sources from unstructured text

Topics

Compare and analyze relevant papers that matches with your search

Papers

Get insights from PDFs and bookmarked papers from your library

My library

Recent searches

Try searching for:

Catch AI-generated content in scholarly and non-scholarly content

{ai} Detector

Ai Writer

Get PDF Summaries, highlighted text explanations 

Chat with PDF

Effortlessly create in-text citations and bibliographies in APA and 2,500 other formats

Citation generator

Get explanations, summaries, and answers on academic papers

Ease up your research workflow with {scispace}'s cohort of exciting AI tools

Elevate your academic writing skills and convey your ideas the way you want

Paraphraser

Explore our range of reading and writing tools

Your file is being prepared and should be ready in a few minutes. If it's a large file, it might take a bit longer. You can close this window, and we'll email you the file when it's done.

You have reached a maximum limit of <strong>{limit}</strong> columns in the table. Remove at least <strong>1</strong> column to add or create another one.

Jonas Svensson

Author Tools

Chat about Author