scispace - formally typeset
Search or ask a question

How can noise pollution be controlled? 


Best insight from top research papers

Noise pollution can be controlled through various methods. One approach is the use of IoT-based systems that employ low-cost sensors to capture and store real-time data for better decision-making processes . These systems enable monitoring and analysis of noise levels, allowing for effective control measures to be implemented. Another method involves the development of noise control devices and products based on accurate identification of noise sources and their positions . By accurately distinguishing the sound source position, the appropriate noise reduction product can be designed and implemented. Additionally, taking appropriate actions against major sound-polluting devices in specific areas can help control and reduce noise pollution . It is also important to consider the effects of noise on human health and implement control measures accordingly . Overall, a combination of monitoring, analysis, identification of noise sources, and implementation of control measures is necessary to effectively control noise pollution.

Answers from top 5 papers

More filters
Papers (5)Insight
Book ChapterDOI
Dilip Kumar, Deepak Kumar 
01 Jan 2018
4 Citations
The paper discusses various control measures for the abatement of noise pollution, including the hierarchy of control for reducing hearing loss to personnel.
Open accessDOI
Dipalben B. Patel, Hitesh Solanki 
02 Apr 2021
6 Citations
The paper discusses the need to control and prevent noise pollution, but it does not provide specific methods or techniques for controlling noise pollution.
Patent
Li Li, Fan Xiaopeng 
25 Jun 2019
1 Citations
The paper provides a noise control method and device that involves collecting a noise sample, processing it, determining the interference degree, identifying the noise pollution source, and designing a noise reduction product based on the sound source position.
The paper discusses a smart sound system controller that can help control noise pollution by monitoring and controlling sound-emitting devices in specific areas using IoT technology.
The paper discusses the use of Internet of Things (IoT) solutions for controlling noise pollution. It proposes a system of four layers for monitoring and analyzing noise levels.

Related Questions

How to mitigate noise pollution in a building?5 answersTo mitigate noise pollution in a building, various methods can be employed. One approach is the use of greening systems, such as modular green roof systems, which have been shown to be effective in reducing noise pollution in residential buildings. Another method is the implementation of active noise control (ANC) technology, which actively mitigates noise at the source or in the transmission path. ANC has been successfully demonstrated in construction machines, noise barriers, and even on windows in naturally-ventilated buildings. Optimizing construction site layout planning in the pre-construction stage can also help reduce noise pollution for on-site workers. This can be achieved by considering the location of facilities and designing layouts that balance noise reduction, safety improvement, and cost control. Additionally, the use of noise detection and treatment devices on construction sites can continuously monitor and reduce noise levels, minimizing the impact on surrounding residents. Finally, the use of green wall systems, particularly hydroponic systems, has been found to be effective in reducing noise impact in urban environments.
How can we control methane emissions?5 answersMethane emissions can be controlled through various measures. The oil and gas industry can take direct actions to reduce emissions from flaring, venting, and leakage of methane, while also generating revenue from the wasted natural resource. Rice cultivation, which is a significant source of methane emissions, can be controlled through agronomic practices. Cutting human-caused methane emissions by 45% this decade can help slow global warming and have multiple benefits, including improved air quality, food security, and job creation. To mitigate natural methane emissions, strategies, methods, and solutions need to be developed, including categorization of emission types and mitigation approaches. In the EU, measures such as the collection and combustion of landfill gas, recovery and use of methane from animal waste, and reduction in livestock numbers can help reduce methane emissions.
How can we control the corruption in the government?4 answersTo control corruption in the government, it is necessary to increase the expected costs of engaging in corrupt conduct. This can be achieved by implementing sanctions such as the loss of office, forfeiture of illegally acquired wealth, and even imprisonment for public officials involved in corruption. In order to effectively control corruption, an institutional framework with multiple, reinforcing, and overlapping institutions of accountability is required. These institutions should include horizontal accountability mechanisms such as the law, anti-corruption bodies, public audits, and the judicial system, as well as vertical accountability mechanisms like an independent electoral commission, independent mass media, and non-governmental organizations. Additionally, external accountability through extensive international scrutiny and support is crucial. By establishing these mechanisms, countries can move towards a situation where corruption is morally intolerable and behaviorally rare.
Can globalization can be controlled?8 answers
How do you control music in noise Colorfit Pro 3 assist?4 answers
How to control particle size?7 answers

See what other people are reading

What are the advantages of using centrifugal pumps in food processing?
4 answers
Centrifugal pumps offer several advantages in food processing applications, making them a preferred choice for this industry. One of the primary benefits is their ability to provide stable and continuous transportation of fluid food, thanks to their simple structure compared to positive displacement pumps. This stability is crucial for maintaining the quality and consistency of food products during processing. Additionally, centrifugal pumps are capable of handling a wide range of liquid viscosities, which is essential in food processing where the viscosity of products can vary significantly. The performance of these pumps can be adjusted to accommodate different fluid viscosities by altering the pump shaft speed, ensuring efficient operation across various applications. The design of centrifugal pumps also contributes to their efficiency and energy-saving potential. The impeller, a key component, is optimized through numerical and experimental analysis to enhance the pump's hydrodynamic performance, thereby reducing energy consumption. This optimization is critical in an industry where energy efficiency directly impacts operational costs and environmental sustainability. Moreover, centrifugal pumps are designed to meet the high hygiene standards required in food processing. Their construction allows for easy cleaning and maintenance, ensuring that the processed food remains uncontaminated and safe for consumption. The ability to directly flange the pump to the motor for a more compact design further simplifies installation and maintenance while reducing the risk of contamination. In terms of technical performance, centrifugal pumps can be precisely modeled and analyzed to predict their behavior under various operating conditions. This predictive capability allows for the fine-tuning of pump operations, ensuring optimal performance and minimal wastage during the food processing cycle. Lastly, the versatility of centrifugal pumps, supported by research aimed at optimizing their design and efficiency, underscores their suitability for a broad spectrum of applications within the food processing industry, from handling low-viscosity liquids to transporting particle-laden flows. In summary, centrifugal pumps are advantageous in food processing due to their stable and continuous operation, adaptability to various viscosities, energy efficiency, compliance with hygiene standards, and their capacity for precise modeling and optimization.
Is using rank-correlation a good practis?
4 answers
Utilizing rank correlation, such as Spearman's rank correlation coefficient, proves to be a beneficial practice in various fields. Rank correlations offer distribution-free and consistent tests of independence between random variables. For instance, in stress management, a model based on rank correlation significantly enhances activity recommendations, leading to effective stress reduction. Moreover, in radio communications, rank correlation aids in identifying useful signals amidst interference, ensuring robustness of communication systems. Additionally, the development of a linearized maximum rank correlation estimator for the single index model showcases the versatility and efficiency of rank-based methods in statistical estimation. Overall, incorporating rank correlation techniques can enhance data analysis, model performance, and statistical efficiency across various domains.
Is using rank-correlation a good practice?
5 answers
Rank correlation is a valuable tool in various fields, offering benefits such as distribution-free tests of independence and robustness against non-linear relationships. It is particularly useful in scenarios where linear relationships are not assumed, as it can outperform Pearson's correlation in such cases. Rank correlations have been applied in radio communications to detect and differentiate signals amidst interference, showcasing their significance in practical applications. Additionally, rank correlations play a crucial role in financial analysis, especially in portfolio management, where understanding correlations among assets is essential for effective risk diversification. Overall, utilizing rank correlations is a sound practice due to their versatility, robustness against non-linear relationships, and applicability in diverse fields such as statistics, communications, and finance.
What is the research gaps related with improving the accuracy of marine radar in detecting ocean wave?
5 answers
Research gaps related to improving the accuracy of marine radar in detecting ocean waves include issues such as look-angle dependence, noise interference, and gaps in data collection. The accuracy of radar measurements is affected by systematic errors due to look-angle dependence and random errors caused by noise in radar data. Additionally, marine radar echoes can be mixed with clutter, making it challenging to detect weak targets accurately. Moreover, gaps in high-frequency (HF) radar data due to environmental interferences and data acquisition failures pose a significant concern for continuous and reliable ocean current observations. Understanding the noise environment and noise floor of HF radar sites is crucial for improving wave height measurements and addressing discrepancies between buoy and radar data. Addressing these gaps is essential for enhancing the precision and reliability of marine radar systems in ocean wave detection.
What are the positive impact of Advanced air traffic management systems in terms of Environmental Benefits for Airline companies?
5 answers
Advanced air traffic management systems offer significant environmental benefits for airline companies. These systems, such as the green air traffic flow management model, optimize operations by considering fuel costs and carbon dioxide emissions alongside traditional ATFM costs. They enable the integration of sustainable aviation fuel (SAF), reducing emissions and fuel consumption, thus aligning with global environmental goals. Additionally, the development of new air traffic management systems aims to save fuel, reduce flight time, and lower carbon emissions, contributing to environmental sustainability. Furthermore, the proposed technology for managing Advanced Air Mobility traffic through distributed airspace allocation and conflict resolution on a blockchain ecosystem enhances efficiency, reduces the risk of system outages, and promotes fairness in airspace utilization, all of which have positive environmental implications for airline operations.
What are the positive impact of Advanced air traffic management systems in terms of Reduced Workload for Pilots?
4 answers
Advanced air traffic management systems have shown positive impacts on reducing workload for pilots. Implementing technologies like Automatic Speech Recognition and Understanding (ASRU) can significantly decrease workload for air traffic controllers (ATCos) by improving situational awareness and reducing errors in radar label maintenance. Additionally, the development of dynamic sectorization and airspace configuration, along with dynamic approach and landing procedures, can reduce operator load by 30-40% and enable aircraft to follow better trajectories, ultimately decreasing noise pollution, emissions, and landing distances. These advancements in air traffic management not only enhance safety but also contribute to environmental sustainability by saving fuel, reducing carbon emissions, and operating costs.
What are the positive impact of Advanced air traffic management systems in terms of Environmental Benefits for Aircraft manufacturers?
4 answers
Advanced air traffic management systems offer significant environmental benefits for aircraft manufacturers. These systems focus on dynamic sectorization, airspace configuration, and highly dynamic approach and landing procedures to reduce fuel consumption, flight time, carbon emissions, and noise pollution. Additionally, the integration of these systems with new aerospace frameworks promotes safety, sustainability, and efficiency in air traffic operations. Furthermore, the adoption of distributed airspace allocation management and conflict resolution through blockchain technology enhances system resilience, reduces the risk of outages, and promotes fairness among airspace users. By implementing these advanced systems, aircraft manufacturers can achieve reduced environmental impact, lower operating costs, and improved overall efficiency in air transportation.
What are the positive impact of Advanced air traffic management systems in terms of Environmental Benefits for Airports?
5 answers
Advanced air traffic management systems offer significant environmental benefits for airports. By implementing dynamic sectorization and airspace configuration, airports can reduce ground noise, emissions, and avoid severe weather encounters, leading to decreased environmental impact. Additionally, the deployment of Automatic Dependent Surveillance–Broadcast (ADS–B) enhances flight efficiency, reduces environmental impact, increases airport throughput, and improves operational predictability and flexibility, ultimately reducing waiting times and delays. Furthermore, the introduction of a secure distributed approach for managing air traffic complexity through blockchain technology not only enhances safety but also reduces the risk of system outages due to Single-Points-of-Failure (SPoFs), making the system more resilient to failures in ground communication infrastructure, thus contributing to environmental sustainability.
What factors contribute to data leakage in time series observations for meteorological conditions?
4 answers
Data leakage in time series observations for meteorological conditions can occur due to various factors. One significant factor is the presence of outliers and inconsistencies in the observed time series, which can be influenced by meteorological factors like snow coverage. Additionally, the use of pulse compression techniques in meteorological radars can lead to artifacts like range sidelobes, causing information to spread across multiple range gates and potentially contaminating data. Moreover, the characteristics of time series data, such as high noise levels and non-stationarity, can contribute to data leakage issues in prediction methods, potentially leading to using testing set information in the training process. Addressing these factors is crucial to ensure accurate and reliable predictions in meteorological time series analysis.
What are the negative impact of Supersonic and hypersonic aircraft in terms of Noise pollution for Airport authorities?
5 answers
Supersonic and hypersonic aircraft pose significant challenges in terms of noise pollution for airport authorities. These aircraft generate intense noise levels that can lead to community annoyance, disrupt sleep patterns, affect children's learning abilities, and even increase the risk of cardiovascular diseases for individuals living near airports. Additionally, the sonic booms produced by supersonic flights can cause short-term annoyance and loudness issues for inhabitants in overflown areas. Noise abatement procedures have been proposed to mitigate the impact of supersonic aircraft noise during takeoff, aiming to reduce noise levels along lateral sidelines. Therefore, airport authorities need to consider implementing noise mitigative strategies and coping mechanisms to address the negative impacts of supersonic and hypersonic aircraft noise on the well-being of individuals residing near airports.
What are the negative impact of Supersonic and hypersonic aircraft in terms of Noise pollution for Environmental groups?
4 answers
Supersonic and hypersonic aircraft pose significant challenges in terms of noise pollution for environmental groups. Aircraft noise is a critical environmental concern, affecting community annoyance, sleep disruption, children's learning, and even cardiovascular health. The development of new supersonic transports involves analyzing their performance, noise levels, and exhaust emissions, which can impact the environment and communities near airports. Efforts to mitigate aircraft noise pollution are crucial for managing environmental interactions and align with reducing aviation emissions, as noise pollution can restrict airport operations and expansion by influencing land zoning and flight patterns. These factors highlight the importance of considering and addressing the negative impacts of supersonic and hypersonic aircraft on noise pollution from an environmental perspective.