Chalmers Open Digital Repository
Välkommen till Chalmers öppna digitala arkiv!
Här hittar du:
- Studentarbeten utgivna på lärosätet, såväl kandidatarbeten som examensarbeten på grund- och masternivå
- Digitala specialsamlingar, som t ex Chalmers modellkammare
- Utvalda projektrapporter
Forskningspublikationer, rapporter och avhandlingar hittar du i research.chalmers.se
Enheter i Chalmers ODR
Välj en enhet för att se alla samlingar.
Senast inlagda
Theory and measurement of low-frequency structure-borne sound in concrete buildings
(2024) Cheng, Jiali
Low-frequency structure-borne sound is a critical issue because this type of noise
travels long distances with little attenuation. This has become a growing concern
with the advancement of audio technology and loudspeakers. It is especially problematic
in spaces like home theatres and concert halls, where it can cause discomfort
and long-term health effects for residents, even those located at a distance. Therefore,
predicting effective sound insulation in the early building design process is
essential. This thesis investigates the behaviour of low-frequency vibrations in a
concrete floor within an office building, focusing on the relationship between the
propagation speed of bending waves, the loss factor, and the attenuation of vibrations
over distance. It is built on the work of Østvik1, who described the correlation
between structural reverberation and distance-dependent damping of vibrations of
a concrete slab within a building.
A theoretical model of vibration decay, based on the propagation speed and the
loss factor of the structure, was proposed and validated through vibration measurements.
These measurements were conducted at multiple excitation points on
both the floor and the wall, with results confirming that the propagation speed of
bending waves follows the expected square-root dependence on frequency. A lower
propagation speed was observed when the floor was excited on the wall, compared
to direct excitations on the floor. The level decay predicted by the model generally
followed a logarithmic pattern, with geometric spreading being dominant. More significant
decay was observed at higher frequencies than at lower ones. Furthermore,
the structural reverberation time was found to decrease with increasing frequency,
indicating that the vibrations last longer at low frequencies. The total loss factor
also decreased with increasing frequency, suggesting that energy loss per oscillation
is greater at low frequencies. These findings provide valuable insights into lowfrequency
vibration propagation. Further research with additional excitation and
measurement positions is needed to validate the proposed relationship and better
understand the variations observed in this study.
Flanking sound transmission over CLT-joints
(2024) Andersson, Eric
Cross-laminated timber (CLT) is a sustainable and efficient building
material that has gained popularity due to its high stiffness, low density,
and reduced environmental impact. However, predicting low-frequency
sound and vibration transmission across CLT joints remains a significant
challenge. This thesis focuses on improving the modeling of flanking
sound transmission over different CLT joint configurations, using finite
element modeling (FEM) validated through experimental measurements.
The study involves measurements of vibration reduction index (Kij) for
undamped and isolated joint setups. The FEM simulations closely
matched experimental trends for non isolated setups, though some
discrepancies arose due to possible differences in coupling conditions and
measurement resolution. In isolated setups, FEM predictions highlighted
limitations in accurately simulating the effect of vibration-isolation
brackets, particularly in representing their behavior when fastened to the
CLT panels.
The results emphasize the need for refined FEM approaches to better
model the dynamic behavior of joints and connections in CLT structures.
Future work should focus on enhancing joint coupling simulations,
modeling of vibration-isolation brackets and optimizing experimental
setups to achieve free boundary conditions. Thereby advancing the
acoustic performance prediction for CLT constructions.
Gradient descent based adaptive IIR filtering with direct and lattice form filter structures; applied to estimation of a headphone compensation filter and binaural head related transfer functions
(2025) Lendon, Alexander
In acoustic Digital Signal Processing (DSP), Finite Impulse Response (FIR) filters
are commonly used due to their stability and ease of design. However, Infinite
Impulse Response (IIR) filters offer better frequency resolution at lower filter
orders, making them ideal for hardware-constrained applications like portable
AR/VR headsets. With advances in computational methods, optimising IIR filters
has become straightforward, making it important to compare their performance
against traditional FIR filters.
This thesis investigates adaptive IIR filtering algorithms using Gradient Descent
(GD) methods, applied to both direct form and lattice form filter structures. Lattice
form filter structures provide the benefit of an in-built stability test which can
guarantee that the produced IIR filter remains stable at each step. This is essential
for reliable IIR filter design and allows for further modifications to the optimisation
routine.
For the studies, the Modified GD direct form and the Simplified Partial Gradient
Descent (SPGD) lattice form algorithms were used to model a headphone
compensation filter and binaural Head-Related Transfer Function (HRTF),
comparing the resulting IIR filters to equivalent FIR filters. Parameter studies
on step-size coefficient and filter order were conducted to assess accuracy in both
frequency and time domain.
The study found that both IIR filter forms reduced order length to 20% of the
HRTF filter order and 40% of the compensation filter order, both within a 1 dB
accuracy threshold in the magnitude response. This results in reduction in numerical
operations of 60% for the HRTF filter and 20% for the headphone compensation
filter.
This work demonstrates the that significant order reduction is possible using lattice
form, gradient decent based adaptive filters. The exact reduction depends on the
target filter and requires similar simulations and analysis to those used here.
Enhancing project management and inspection efficiency through advanced data integration in construction projects
(2024) Ali, Isaac; Shahul Hameed, Ashiq Ahmed
The construction industry is increasingly adopting advanced digital tools to enhance
project management practices, improve data accuracy, and streamline communication.
This master’s thesis investigates the integration of StreamBIM, a Building Information
Modeling (BIM) software, with Power BI, a powerful data visualization and analytics
tool, to enhance project management within the construction industry. The study
focuses on a real-world project exploring the benefits and challenges associated with
this technological integration. Through a detailed case study approach, including semistructured
interviews and thorough document analysis, the research identifies
significant improvements in data management, inspection protocols, and overall project
efficiency. The integration allows for advanced data filtering, customized visual
representations, and the creation of interactive dashboards, which enhance the ability
to monitor progress, identify issues, and make informed decisions. Key findings
demonstrate that this integration not only improves the accuracy and timeliness of data
but also facilitates better communication and collaboration among project stakeholders.
The results highlight the transformative impact of integrating StreamBIM with Power
BI, showing marked enhancements in the preparation and planning stages of
inspections, standardization and automation of reporting processes, and overall quality
control. The study concludes with recommendations for further improving digital tools
in construction management, emphasizing the need for comprehensive training
programs and the adoption of a model-based construction approach to fully leverage
the capabilities of BIM and data visualization technologies. This research contributes
to the body of knowledge on BIM integration, offering practical insights and solutions
for industry professionals aiming to achieve more efficient and effective project
management outcomes.
Total BIM in Swedish installation contracting; a comparative study of model-based and traditional ventilation contracting
(2024) Ahmadi, Reza
Time waste and budget overruns are common issues in most construction projects. Digital
tools like Building Information Modeling (BIM) have been developed to address these
problems. While BIM has improved the design process, its adoption on construction sites
remains limited, where paper drawings are still dominant. Total BIM is a new concept that is
becoming popular in Scandinavia and aims to use BIM models even in the production phase.
This approach eliminates the need for paper drawings and has the potential to improve both
project efficiency and accuracy. Therefore, this study aims to compare model-based versus
traditional working methods in the production phase of a real-world installation project and
analyze workers' reactions to the new concept.
To conduct this comparison, the traditional workflows of an installation company were
studied, and one of their ongoing ventilation projects, Blå Stjärnan, was selected as the
reference project. A 3D model of the project was compiled using StreamBIM, and the
company’s installers formed the study group. The comparison focused on three key areas:
time spent on quantity takeoff, differences in cost estimation, and the workers’ experience
with the installation process. The study also identifies several lessons and challenges related
to the implementation of Total BIM.
The results showed that model-based quantity takeoff improved efficiency by 40 times
compared to traditional drawing-based methods. Additionally, traditional methods tended to
underestimate project costs by 8% due to human errors. Workers on-site reported significant
improvements in planning, efficiency, and accuracy when using the 3D model, and noted that
communication through the model would have been beneficial if requirements were set.
However, despite its potential, the industry remains hesitant to fully adopt Total BIM due to
established workflows and the legal binding nature of paper drawings. Increased knowledge
within the construction industry and successful real-world implementations could encourage
clients to oblige the use of BIM models in production.