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Paterna, Spain
11-50 Employees
2017
Anti-Drone is a customizable integrated system that can include different kinds of equipment and solutions depending on the customer's needs and requirements…. When choosing an anti-drone system it’s important to remember that after UAV detection it’s necessary to have some extra time for reaction. Special integration software provides simultaneous use and smooth operation of different Counter-UAV solutions within one integrated system while data processing and visualization software helps to access the level of threat and take adequate response actions. We read all feedback carefully, but we are unable to respond to each submission individually. We make things to make our life easier, safer, we develop tools that help in our daily life, production, business, but sooner or later we should protect ourselves from machines we are created. This benefit launched the mass flying in urban areas, where is a potential risk in case of crash. Prime consulting and technologies held a demonstration of anti-drone systems in Poland. More than ten interested organizations conducted theoretical and practical classes on anti-drone systems.
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Acoustic sensors
... DroneShield sensors for UAV acoustic ...
Eskdale, United Kingdom
11-50 Employees
2006
Designed in-house and using advanced manufacturing techniques, we develop outstanding systems, without compromise. We aim to provide the subsea community with innovative, high-quality acoustic products at an affordable price. Driven by innovation, Blueprint Subsea's leading range of compact, robust, intuitive and affordable underwater acoustic products have been meeting the rigorous demands of the global subsea, offshore and defence markets since 2006.We specialise in imaging sonars, acoustic positioning beacons and diver navigation systems. Designed in-house and using advanced manufacturing techniques, we develop outstanding systems without compromise.
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Advanced underwater acoustic sensors without compromise
... Advanced underwater acoustic sensors without ...
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IT-20 Underwater Acoustic Sensor Network transducer
... IT-20 Underwater Acoustic Sensor Network transducer – HZ ...
11-50 Employees
2011
Microflown AVISA develops and markets highly innovative capabilities for the global defense and security markets. Exploiting the benefits of its proprietary CASTLE acoustic subarray hardware platform, Microflown AVISA offers an ever growing range of sheer firmware defined capabilities to detect and localize all sorts of audible threats.To some extent, these capabilities are based upon a single sensor post. The CASTLE comprises of four hard wired, spatially distributed Acoustic Multi Mission Sensors (AMMSs), enriched by an Acoustic Master (AMR) and a weather station. The Microflown is the world’s first and only dedicated acoustic particle velocity sensor, the complementary physical quantity to sound pressure. The Microflown provides acoustic directionality over the entire acoustic bandwidth, equaling and exceeding by far the functionality of a pair or triplet of microphones/ sound pressure transducers. Microflown AVISA develops and markets highly innovative and complete battlefield acoustic solutions, providing 3D situational awareness by detecting, localizing and classifying the full range of audible battlefield threats, such as small arms fires, rockets, artillery and mortars and engine driven platforms (heavy ground vehicles, helicopters and UAV's).
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Microflown AVISA acoustic vector sensor technology - Microflown AVISA
... Microflown AVISA acoustic vector sensor technology - Microflown ...
Houston, United States
11-50 Employees
2016
Flow is the base unit measurement for many industrial processes. When installed onto a wellhead and calibrated, our sensor can deliver bulk fluid production rates with up to 98% accuracy. This gives production engineering teams unrivaled data on which to operate their wells at maximum efficiency.
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Carbic
... Blanket your wells, pipes, and facilities with low cost sensors. Carbic’s wireless acoustic sensors can track all of your operations from wellhead to refinery. ...
11-50 Employees
2017
Our mission is to provide high quality and reliable IIoT online unattended condition monitoring solutions for predictive maintenance of valuable industrial assets in the world. Our products have been not only sold domestically in China, but also sold to customers around the world such as the United States, the United Kingdom, Japan, Singapore, Brazil, and Mexico and more. We are a united and growing team working together to provide better products and services to customers. We are excited to be able to work with you and help you solve your problems and achieve your goals. Our mission is to provide high quality and reliable online unattended condition monitoring solutions for predictive maintenance of valuable industrial assets in the world. We have been committed to acoustic emission testing equipment and monitoring systems for more than 20 years. In addition, we also develop and manufacture vibration testing system, handheld ultrasonic gauges, other testing and inspection systems, and condition monitoring systems. We were established in 2000 and have offices in Guangzhou (headquarter) and Beijing (branch).
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Acoustic Emission Sensors
... Acoustic Emission Sensors ...
Arnhem, Netherlands
11-50 Employees
1998
Microflown Technologies was founded in 1998 by Hans Elias de Bree and Alex Koers, building on de Bree's invention of the particle velocity sensor in 1994. The Microflown sensor is a one-of-a-kind acoustic sensor, and the first to directly measure particle velocity as a physical quantity. Currently, Microflown focuses on delivering high-quality acoustic measurement solutions that help to make the world a quieter and more pleasant place. Microflown was founded as an innovative start-up project at the technical University of Twente, situated in the Dutch technology hub. The innovation of Microflown extends beyond the sensor itself, as the company has partnered with leading experts in acoustics to develop new measurement techniques. Today, Microflown offers a wide range of solutions that provide comprehensive acoustic measurement and analysis for a variety of applications. Microflown sensor technology powers our measurement solutions, which are the result of extensive R&D by a dedicated team of engineers. Since 1998, Microflown has pioneered the field of acoustics, driven by the world's first particle velocity sensor.
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Acoustic Sensors & Testing Solutions
... Microflown: Acoustic Sensors & Testing Solutions - ...
Russia
11-50 Employees
1992
We develop, manufacture and supply the measuring equipment all over the world. We supply our products worldwide via most reliable shipping companies. TECHNO-AC is a group of companies of full cycle established in 1992. Our specialists demonstrate our new devices as well as the equipment that are already applied successfully by thousand of companies in more than 40 countries from America to Australia.
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Portable acoustic sensor ADM-227 with magnetic connection feature
... Portable acoustic sensor ADM-227 with magnetic connection feature TECHNO-AC - ...
London, United Kingdom
11-50 Employees
This research provides better science, helping governments make regulatory decisions and industry develop effective mitigation strategies. Deliverables of the JIP can be found here. Wind is a constant contributor to ocean ambient noise and can vary from 30-85 dB re 1 μPa over the frequency range of 100 Hz-10 kHz. Thunder is a loud source that occurs in air, but can be heard underwater. Global product cargo transported by sea has risen 2.5 times between 2000 and 2013. Commercial shipping is the largest man-made contribution to ambient sound in the ocean. Working together with multi-national groups, experts and NGOs, this JIP is the most extensive industry research programme in this field, which has already committed US$ 31 million to research. Very little is known about what these large whales can hear, and our research has contributed new knowledge to large whale hearing.
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Density Estimation For Cetaceans From Acoustic Fixed Sensors (DECAF)
... Density Estimation for Cetaceans from Passive Acoustic Fixed Sensors (DECAF) allows the oil and gas industry to know the population density and distribution of marine ...
Hertsmere, United Kingdom
101-250 Employees
2007
Silixa’s distributed sensing-based solutions enable the world’s digital transformation. We are a diverse team of 32 different nationalities and our identities, backgrounds and talents allow us to go faster and farther. Silixa has won a number of awards for its excellence and innovation. Luna Innovations acquired Silixa on December 21, 2023. Meet the team leading Silixa: individuals that share a commitment to integrity and trust. Built by subject matter experts, Silixa’s engineered solutions serve the unique demands of multiple sectors. Recognised as an award-winning innovator, Silixa has developed a reputation for revolutionising multiple industries. We offer dense array data sets of the highest fidelity.
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Distributed Acoustic Sensing for Oil & Gas with Silixa's iDAS Acoustic Sensor Technology | Silixa Ltd.
... ™ - Silixa's intelligent Distributed Acoustic Sensor (iDAS™) is an optoelectronic system which records the true acoustic signal continuously along the path of sensing fibre tens of kilometres long. ...
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Some interesting numbers and facts about the results you have just received for Acoustic Sensor
Country with most fitting companies | United Kingdom |
Amount of fitting manufacturers | 80 |
Amount of suitable service providers | 43 |
Average amount of employees | 11-50 |
Oldest suiting company | 1992 |
Youngest suiting company | 2017 |
An acoustic sensor is a device designed to detect sound waves or vibrations within a specific environment and convert them into electrical signals for analysis. Operating on the principles of acoustics, these sensors are pivotal in various fields, leveraging the propagation of sound through mediums like air, water, or solids to monitor, detect, or measure events. In the realm of environmental monitoring, acoustic sensors play a crucial role in detecting changes in wildlife populations or underwater ecosystems by capturing sounds that indicate the presence or activities of organisms. In industrial applications, they are instrumental in predictive maintenance, using sound and vibration patterns to preemptively identify machinery faults before they lead to failure. Similarly, in security systems, acoustic sensors are employed to detect breaking glass or unauthorized entry, providing real-time alerts. The versatility and sensitivity of these sensors make them invaluable across sectors, including healthcare, where they contribute to non-invasive diagnostics and monitoring by detecting specific body sounds for clinical assessment. By transforming acoustic energy into data, these sensors offer insights that drive innovation, enhance safety, and contribute to environmental conservation, marking a significant impact on their respective fields through the advancement of acoustic technology and its applications.
1. Enhanced Sensitivity
Acoustic sensors are renowned for their exceptional sensitivity. They can detect a wide range of frequencies, including those beyond human hearing. This makes them incredibly effective for applications requiring the detection of subtle sound waves or vibrations that alternative sensors might miss.
2. Low Power Consumption
One significant advantage of acoustic sensors is their low power requirements. They are capable of operating effectively on minimal power, making them ideal for remote monitoring applications where power sources are limited or for devices that need to conserve energy.
3. Cost-Effectiveness
Compared to many alternative sensing technologies, acoustic sensors offer a more cost-effective solution. Their simplicity in design and the availability of materials needed for their construction contribute to lower manufacturing costs. This affordability does not compromise their efficiency, making them an attractive option for a wide range of applications.
4. Versatility
The versatility of acoustic sensors is unmatched. They can be used in various environments and for multiple purposes, from industrial monitoring and environmental noise measurement to healthcare applications. This adaptability allows for their integration into different systems and devices, expanding their utility across sectors.
While evaluating the different suppliers make sure to check the following criteria:
1. Frequency Range
Ensure the acoustic sensor covers the specific frequency range relevant to your application, as performance can vary significantly across different environments and requirements.
2. Sensitivity
Check the sensitivity levels of the sensor. A higher sensitivity can detect finer sounds, which might be crucial depending on the application's precision needs.
3. Size and Form Factor
Consider the physical dimensions and design of the sensor to ensure it fits within your device or system without causing disruptions or requiring major modifications.
4. Durability and Environmental Resistance
Evaluate the sensor's ability to withstand environmental conditions such as temperature, humidity, and potential mechanical impacts, ensuring longevity and reliability in the field.
5. Power Consumption
Assess the energy requirements of the sensor, especially if it will be used in battery-powered or energy-efficient systems. Lower power consumption can significantly extend the operation time.
6. Cost and Availability
Compare pricing and availability across suppliers. While cost-effectiveness is important, ensure it does not compromise the quality and performance of the sensor.
Acoustic sensors find pivotal applications in the realm of predictive maintenance within the manufacturing industry. By monitoring the sound emitted by machinery, these sensors can detect unusual noises indicative of wear or failure, facilitating timely repairs before costly breakdowns occur. This capability not only reduces downtime but also extends the lifespan of equipment, offering a significant advantage in operational efficiency and cost savings. In the energy sector, particularly within oil and gas exploration, acoustic sensors play a critical role in identifying the geological characteristics necessary for locating reserves. Employing these sensors, companies can analyze the acoustic properties of the earth's layers, enhancing the accuracy of exploration efforts. This precision leads to more effective drilling strategies and resource extraction, optimizing the industry's output and sustainability. The transportation industry benefits from acoustic sensors through their integration into structural health monitoring systems for bridges and tunnels. These sensors detect changes in the acoustic signature of materials, identifying potential weaknesses or damages in the infrastructure. Early detection allows for preventative maintenance, ensuring the safety and longevity of critical transport routes. In sum, acoustic sensors serve as indispensable tools across various industries, from enhancing predictive maintenance protocols and refining resource exploration to safeguarding transportation infrastructure. Their versatility and precision in detecting and analyzing sound make them a cornerstone technology in the modern industrial landscape.
Acoustic sensors, devices capable of detecting sound waves and vibrations in various environments, have achieved a high Technology Readiness Level (TRL), typically ranging between 7 and 9. This assessment is based on their extensive integration into numerous commercial and defense applications, demonstrating a matured state of development and validation. The progression to such high TRLs is largely attributed to significant advancements in material science and microfabrication technologies, which have enabled the production of highly sensitive and compact acoustic sensors. These sensors are now capable of operating in a broad spectrum of frequencies, including the ultrasonic range, which has expanded their applicability from traditional audio surveillance and noise monitoring to more sophisticated uses like structural health monitoring, underwater navigation, and medical diagnostics. The miniaturization of these sensors, alongside improvements in signal processing algorithms, has facilitated their integration into portable and wearable technologies, further evidencing their operational reliability and effectiveness in real-world conditions. The technical evolution, marked by enhanced sensitivity, selectivity, and durability, underlines why acoustic sensors have attained such advanced TRLs, reflecting their readiness for widespread deployment and their potential for continued innovation in sensor technology.
In the short-term, acoustic sensor technology is anticipated to see significant advancements in sensitivity and miniaturization. Researchers are focusing on enhancing the precision of acoustic sensors to detect a broader range of frequencies with higher fidelity. This improvement will enable applications in early fault detection in machinery and infrastructure monitoring, where the slightest noise variations can indicate potential failures. Mid-term developments are expected to integrate acoustic sensors with AI and machine learning algorithms to create smarter, more autonomous systems. These systems will not only detect and analyze sounds but will also interpret them to make decisions or recommendations. For example, in healthcare, this could lead to non-invasive diagnostics tools that analyze breath sounds for early signs of respiratory conditions. Integration with IoT devices for real-time data collection and analysis in industrial settings is another promising area. Looking long-term, the evolution of acoustic sensor technology could revolutionize human-machine interfaces and environmental monitoring. Futuristic applications include highly sophisticated surveillance systems capable of distinguishing specific types of sounds amidst high background noise and creating interactive, voice-responsive environments. Environmental applications might extend to global-scale monitoring networks that use acoustic sensors to track changes in biodiversity or detect natural disasters early, potentially saving lives and preserving ecosystems.