Noise impact - a liveable or unbearable disturbance - A case study in noise impact during the construction phase of Citybanan and Norra länken. / Bullerpåverkan - uthärdlig eller outhärdlig störning. En fallstudie om bullerpåverkan under konstruktionsfasen av Citybanan och Norra länken.

Strömberg, Caisa

January 2011

Noise is today defined as an unwanted sound that invades the lives of many people in their homes and at work. During a construction phase a large amount of noise is generated that often leads to community complaints. The construction business has to face this issue today when larger infrastructure projects are performed in highly dense areas. Therefore the aim of this Master’s Thesis is to investigate the effect construction noise has on humans and the perceived annoyance in the concerned studied areas, which Bilfinger Berger is contractor for. The impact was studied on both the third party around a construction site on Södermalm, Stockholm and on Bilfinger Berger’s employees on the site. The work concerns three areas, which are situated in the inner city of Stockholm and represent contracts of the infrastructure pro-jects Citybanan and Norra länken. The extensive noise emission during an infrastructure project is affecting the surrounding environment both due to the high noise level that is generated from a number of machines and work activities. Also due to the extensive time frame a project of this kind has. Therefore it is a complex problem to handle and essential for both contractor and client to handle properly. By using appropriate mitigation measures through both the planning stage, the construction phase and clear information towards all parties the impact can be reduced. Through a literature study among the existing science and observations of which mitigation measures are used today to reduce the noise level on sites, a base of theoretical knowledge could be built up for this study. The real noise impact among the affected parties was performed through a survey, which gave results that could be evaluated and discussed. The results from the surveys show that the third party around the workplace is definitely affected by the noise generated from the production. It is also possible to assume that the most affected are persons, which spend a lot of the daytime at home, and therefore feels the noise very disturbing and has to adapt their life after the project’s progress. Through the survey among the employees at Bilfinger Berger a certain acceptance exist towards the noise even if they feel disturbed by the noise. The conclusion drawn from this is that the human attitude to noise impact becomes more positive if they have the knowledge about why and how it arises even if the noise has the same impact on everyone. Therefore the noise issue has to be raised in future projects, even during the tender phase when noise is always easier to control in an earlier stage.

Noise impact

Mitigation measures

Third party

Noise exposure

Other Civil Engineering

Annan samhällsbyggnadsteknik

Characteristics of the Audiometric 4,000 Hz Notch (744,553 Veterans) and the 3,000, 4,000, and 6,000 Hz Notches (539,932 Veterans)

Wilson, Richard H., McArdle, Rachel

25 March 2013

The purpose of this study was to examine the prevalence and characteristics of audiograms that are notched (1) at 4,000 Hz and (2) at 3,000, 4,000, and/or 6,000 Hz. Bilateral audiograms from 1,000,001 veterans were obtained from Department of Veterans Affairs archives; after "cleaning" algorithms were applied, 744,553 participants (mean age = 63.5 yr) were included in the 4,000 Hz notch analysis (group 1) and 539,932 participants (mean age = 62.2 yr) were included in the 3,000, 4,000, and/or 6,000 Hz notch analysis (group 2). A notch was defined when the threshold at the notch frequency (3,000, 4,000, or 6,000 Hz) minus the 2,000 Hz threshold and the threshold at the notch frequency minus the 8,000 Hz threshold both were greater than or equal to 10 dB. In group 1, 77.1% did not have a notch at 4,000 Hz. In group 2, 65.3% did not have a notch at 3,000, 4,000, or 6,000 Hz; 12.4% had bilateral notches, 11.7% had left ear notches, and 10.7% had right ear notches. The notches were about twice as deep on the low-frequency side of the notch than on the high-frequency side. The mean left ear and right ear notch depths were about the same (23 dB), with mode notch depths in the 15.0 to 17.5 dB range.

audiogram

bilateral

hearing loss

high-frequency

multisite

noise exposure

noise notch

notched audiogram

unilateral

veterans

Characteristics of the Audiometric 4,000 Hz Notch (744,553 Veterans) and the 3,000, 4,000, and 6,000 Hz Notches (539,932 Veterans)

Wilson, Richard H., McArdle, Rachel

25 March 2013

The purpose of this study was to examine the prevalence and characteristics of audiograms that are notched (1) at 4,000 Hz and (2) at 3,000, 4,000, and/or 6,000 Hz. Bilateral audiograms from 1,000,001 veterans were obtained from Department of Veterans Affairs archives; after "cleaning" algorithms were applied, 744,553 participants (mean age = 63.5 yr) were included in the 4,000 Hz notch analysis (group 1) and 539,932 participants (mean age = 62.2 yr) were included in the 3,000, 4,000, and/or 6,000 Hz notch analysis (group 2). A notch was defined when the threshold at the notch frequency (3,000, 4,000, or 6,000 Hz) minus the 2,000 Hz threshold and the threshold at the notch frequency minus the 8,000 Hz threshold both were greater than or equal to 10 dB. In group 1, 77.1% did not have a notch at 4,000 Hz. In group 2, 65.3% did not have a notch at 3,000, 4,000, or 6,000 Hz; 12.4% had bilateral notches, 11.7% had left ear notches, and 10.7% had right ear notches. The notches were about twice as deep on the low-frequency side of the notch than on the high-frequency side. The mean left ear and right ear notch depths were about the same (23 dB), with mode notch depths in the 15.0 to 17.5 dB range.

audiogram

bilateral

hearing loss

high-frequency

multisite

noise exposure

noise notch

notched audiogram

unilateral

veterans

Canine Noise Exposure and Brainstem Auditory Evoked Responses

Noetzel, Jennifer

23 August 2022

No description available.

Veterinary Services

brainstem auditory evoked response

occupational noise exposure

working dogs

PRIOR COMBINED SOLVENT AND NOISE EXPOSURE AND ITS IMPACT ON HEARING

THOMPSON, KIERSTEN LYN

30 June 2003

No description available.

Health Sciences, Audiology

combined exposure

exposure

hearing loss

solvents

noise exposure

AN EPIDEMIOLOGICAL ASSESSMENT OF OHIO FARMERS' HEARING SENSITIVITY

HARRIS, DAVE ANDREW

28 September 2005

No description available.

Hearing sensitivity

Ohio Farmers

Pesticide Exposure

Hearing Loss

Noise Exposure

Ototoxic

Audiotory Neuropathy

Investigation and Improvement of Occupational and Military Noise Exposure Guidelines: Evaluation of Existing and Modified Noise Exposure Metrics Using Historical Animal Data

Goley, George

03 August 2010

No description available.

Mechanical Engineering

NIHL

hearing loss

impulsive noise

noise exposure

occupational noise

military noise

Baseline Normative Brainstem Auditory Evoked Response in Special Operations Multi-Purpose Canines, Unclassified

Sonstrom, Kristine E.

11 September 2015

No description available.

Audiology

Brainstem Auditory Evoked Response

Auditory Brainstem Response

Auditory Middle Latency Response

Canine

Dog

Noise Exposure

Mapping Noise Pollution with Open-source GIS

Yeboah, Faustina Lina

January 2021

In a time when urban areas continue to expand, environmental noise pollution especially from road traffic remains a big challenge. This study was aimed at using open-source GIS tools to predict road traffic noise pollution using the mid-sized city of Gävle as a case study. The noise indicators measured were the equivalent day (Lday), evening (Levening), nighttime (Lnight), and the equivalent daily average (Lden). Traffic data (composition and flow of vehicles on selected roads), traffic source characteristics (road gradient, road surface type), and buildings (geometry) were integrated into Quantum GIS (QGIS) using the CNOSSOS-EU prediction method packaged in OpeNoise, a QGIS plug-in. The resultant noise levels at receiver points were interpolated using the Inverse Distance Weighting method to create noise maps for the city.  The results showed the maximum equivalent day, evening, nighttime predicted noise levels at 85 dB (A), 80 dB (A), 75 dB (A) respectively while the maximum for overall daily average noise level predicted was 85 dB (A). These limits far exceed population exposure threshold limits for the onset of annoyance (55 dB (A)) and sleep disturbance (40 dB (A)). This result is indicative of a poor sound acoustic environment. The pattern of noise level across the city was found to follow street connectivity and traffic intensity. The maximum noise levels were clustered around the highway. Within the city, areas with the highest noise levels were found close to main roads. Residential areas served by service roads were areas with the lowest noise levels. Predicted daytime noise levels (Lday) were compared with 60-second measurements of equivalent noise levels measured at 85 locations during the day in residential and mixed land use areas in the city. The mean of differences between predicted and observed noise levels was found at +1 dB for both residential and areas of mixed land use respectively. Correlation and regression analyses performed for observed and predicted values showed an initial weak positive association with a correlation coefficient of 0.21. However, when outliers were excluded, a correlation coefficient of 0.69 was observed indicating a strong association and linear relationship between the observed and predicted noise levels. Most outliers were underestimations recorded in residential areas at hidden facades. These were attributed to local effects at the measuring locations and assumptions made for building diffraction. The application of the CNOSSOS-EU method in this study did not consider attenuation from ground reflection and terrain effects. Despite these limitations, the results show that the CNOSSOS-EU has good predictive power. However, this study has only been exploratory in nature. It is recommended that further studies be performed with this model as well as in comparison with other models to find the one that best reflects the acoustic environment of the city. A wide application of the CNOSSOS-EU method across several cities will be integral in increasing our understanding of its strengths and weaknesses.

Road traffic noise

CNOSSOS-EU

noise exposure

Lday

Levening

Lnight

Lden

Other Environmental Engineering

Annan naturresursteknik

Evaluation of an Auditory Localization Training System for Use in Portable Configurations: Variables, Metrics, and Protocol

Cave, Kara Meghan

22 January 2020

Hearing protection can mitigate the harmful effects of noise, but for Service Members these devices can also obscure auditory situation awareness cues. Tactical Communication and Protective Systems (TCAPS) can restore critical cues through electronic circuitry with varying effects on localization. Evidenced by past research, sound localization accuracy can improve with training. The investigator hypothesized that training with a broadband stimulus and reducing the number of presentations would result in training transfer. Additionally, training transfer would occur with implementation of more user-engaged training strategies. The purpose of the experiments described in this study was to develop an optimized auditory azimuth-training protocol for use in a field-validated portable training system sensitive to differences among different TCAPS. A series of indoor experiments aimed to shorten and optimize a pre-existing auditory localization training protocol. Sixty-four normal-hearing participants underwent localization training. The goal of training optimization included the following objectives: 1) evaluate the effects of reducing stimulus presentations; 2) evaluate the effects of training with a broadband stimulus (but testing on untrained military-relevant stimuli); and 3) evaluate performance differences according to training strategies. Twenty-four (12 trained and 12 untrained) normal-hearing listeners participated in the field-validation experiment. The experiment evaluated localization training transfer from the indoor portable system to live-fire blanks in field. While training conducted on the portable system was predicted to transfer to the field, differences emerged between an in-the-ear and over-the-ear TCAPS. Three of four untrained stimuli showed evidence of training transfer. Shortening the training protocol also resulted in training transfer, but manipulating training strategies did not. A comparison of changes in localization scores from the indoor pretest to the field posttest demonstrated significant differences among listening conditions. Training improved accuracy and response time for the open ear and one of two TCAPS. Posttest differences between the two TCAPS were not statistically significant. Despite training, localization with TCAPS never matched the open ear. The portable apparatus employed in this study offers a means to evaluate the effects of TCAPS on localization. Equipped with a known effect on localization, TCAPS users can render informed decisions on the benefits or risk associated with certain devices. / Doctor of Philosophy / Hearing protection can mitigate the harmful effects of noise, but for Service Members these devices can obscure auditory situation awareness cues. Certain powered hearing protection can restore critical cues through electronic circuitry with varying effects on localization. Evidenced by past research, sound localization accuracy can improve with training. The investigator hypothesized that training with a broadband stimulus and reducing the number of presentations would result in auditory learning. Additionally, implementing more user-engaged training strategies would demonstrate more auditory learning. The purpose of the experiments described in this study was to develop an optimized auditory azimuth-training protocol for use in a field-validated training system sensitive to differences among active hearing protection. A series of indoor experiments aimed to shorten and optimize a pre-existing auditory localization training protocol. Sixty-four normal-hearing participants underwent localization training. The goal of training optimization included the following objectives: 1) evaluate the effects of reducing stimulus presentations; 2) evaluate the effects of training with a broadband stimulus (but testing on untrained military-relevant stimuli); and 3) evaluate performance differences in localization performance according to training strategies. In the field-validation study, 12 trained and 12 untrained normal-hearing listeners participated. The experiment evaluated localization learning from the indoor portable training system to live-fire blanks in a field. Training conducted on the portable system was predicted to transfer to the field, but differences would emerge between an in-the-ear and an over-the-ear TCAPS. Three of four untrained stimuli showed evidence of localization learning. Shortening the protocol also resulted in localization learning, but manipulating training strategies did not. A comparison of changes in localization scores from the indoor pretest to the field posttest demonstrated significant differences among listening conditions. Training improved performance for the open ear and one of two active hearing protectors. Posttest differences between the two devices were not significant. Despite training, performance with hearing protection never equaled the open ear. The portable apparatus employed in this study offers a means to evaluate the effects of hearing protection on localization. Knowing the effects of hearing protection on localization apprises users of the benefits and/or risk associated with the use of certain devices.

Auditory Localization

Auditory Situation Awareness

Auditory Training

Hearing Protection

Noise Exposure