Dynamic control technology of ultrasound applied using Shannon's juggling theorem.

Ultrasonic plating treatment technology using fine bubbles and megahertz ultrasonic waves.

The Ultrasonic System Research Institute has been developing ultrasonic plating treatment technology utilizing fine bubbles and megahertz ultrasound in collaboration with Japan Barrel Industry Co., Ltd. since 2015. Note: As of August 2024, it is continuously evolving based on good results into various application technologies. 1) Cleaning, processing, welding, plating... surface treatment... 2) Chemical reactions, liquid homogenization, stirring... 3) Inspection, evaluation... 4) Optimization control of ultrasound and fine bubbles tailored to specific purposes. Currently, in collaboration with Japan Barrel Industry Co., Ltd., we are developing application technologies utilizing ultrasound and fine bubbles for iron plating treatment (iron powder, amorphous, megahertz ultrasound...). If you are interested, please contact us via email. Ultrasonic propagation characteristics: 1) Detection of vibration modes (changes in autocorrelation) 2) Detection of nonlinear phenomena (changes in bispectrum) 3) Detection of response characteristics (analysis of impulse response characteristics) 4) Detection of interactions (analysis of power contribution rates)

• Non-destructive testing
• Other measuring instruments
• others

- Application of nanolevel stirring, emulsification, dispersion, and grinding technology to control nonlinear ultrasonic phenomena (acoustic flow) -

- Technology for controlling nonlinear ultrasonic phenomena for nano-level stirring, emulsification, dispersion, and grinding - Ultrasonic Treatment 1: "Nanonization of Powders" Ultrasonic Treatment 2: "Homogenization of Liquids and Improvement of Fluidity" The Ultrasonic System Research Institute has developed a technology for "homogenizing liquids and improving fluidity using ultrasonic technology," utilizing the "technology for controlling nonlinear ultrasonic phenomena (acoustic flow)." This technology controls ultrasonic (cavitation and acoustic flow) by utilizing (evaluating) the ultrasonic propagation characteristics (analysis results) of indirect containers, ultrasonic tanks, and other items through surface inspection. Furthermore, it realizes effective ultrasonic (cavitation and acoustic flow) propagation states tailored to the structure, material, and acoustic characteristics of specific target objects, in accordance with the interactions between glass containers, ultrasonic waves, and target objects, through the control of ultrasonic oscillation. In particular, the dynamic characteristics of harmonics achieved through acoustic flow control enable responses at the nano level. Ultrasonic Propagation Characteristics: 1) Vibration Modes (Self-Correlation) 2) Nonlinear Phenomena (Bicoherence) 3) Response Characteristics (Impulse Response) 4) Interactions (Power Contribution Rate)

• pump
• Water Treatment
• others

Technology for controlling nonlinear phenomena of ultrasound.

The Ultrasonic System Research Institute has developed a technology for controlling "nonlinear phenomena of ultrasound (acoustic flow)" using indirect containers. This technology utilizes (evaluates) the ultrasonic propagation characteristics (analysis results) of indirect containers, ultrasonic water tanks, and other items to control ultrasound (cavitation and acoustic flow). Furthermore, it realizes effective ultrasonic (cavitation and acoustic flow) propagation states tailored to the structure, material, and acoustic characteristics of specific target objects, by controlling the oscillation of ultrasound in accordance with the interactions between glass containers, ultrasound, and target objects. In particular, the dynamic characteristics of harmonics through acoustic flow control enable responses at the nanoscale. This has been applied and developed from examples of dispersing metal powders to nanosize. By employing control technologies for standing waves and cavitation in relation to ultrasound, as well as propagation control technologies for indirect containers, we can appropriately control cavitation and acoustic flow. Through original measurement and analysis techniques for ultrasonic propagation states, we have confirmed the evaluation of acoustic flow and numerous know-how.

• Analysis and prediction system
• Scientific Calculation and Simulation Software
• others

- Technology for controlling nonlinear ultrasonic phenomena, enabling nano-level stirring, emulsification, dispersion, and grinding techniques.

Ultrasonic Treatment 1: "Nanopowdering" Ultrasonic Treatment 2: "Liquid Homogenization and Flowability Improvement" The Ultrasonic System Research Institute has developed a "technology for liquid homogenization and flowability improvement using ultrasonic control of nonlinear phenomena (acoustic flow)." This technology utilizes (evaluates) the ultrasonic propagation characteristics (analysis results) of indirect containers, ultrasonic tanks, and other items through surface inspection to control ultrasonic (cavitation and acoustic flow). Furthermore, it achieves effective ultrasonic (cavitation and acoustic flow) propagation states tailored to the structure, material, and acoustic properties of specific target objects, by controlling the ultrasonic oscillation in accordance with the interactions between glass containers, ultrasonic waves, and target objects. In particular, the dynamic characteristics of harmonics through acoustic flow control enable responses at the nanoscale. It has been applied and developed from the example of dispersing metal powders to nanosize.

• pump
• Water supply facilities
• others

A technology has been developed to control the nonlinear phenomena of ultrasonic vibrations propagating to the target object based on classification techniques of ultrasonic waves and oscillation control.

We provide consulting services for the development of ultrasonic systems utilizing the following device. <<Deaeration Fine Bubble (Microbubble) Generation Liquid Circulation Device>> 1) By narrowing the suction side of the pump, cavitation is generated. 2) Cavitation causes bubbles of dissolved gases to form. The above describes the state of the deaeration liquid circulation device. 3) When the concentration of dissolved gases decreases, the bubble size of dissolved gases due to cavitation becomes smaller. 4) Through appropriate liquid circulation, fine bubbles (microbubbles) of less than 20μ are generated. The above describes the state of the deaeration microbubble generation liquid circulation device. 5) When ultrasonic waves are applied to the above-mentioned deaeration fine bubble (microbubble) generation liquid circulation device, the ultrasonic waves disperse and crush the fine bubbles (microbubbles), and when measuring the fine bubbles (microbubbles), the distribution of ultra-fine bubbles becomes greater than that of fine bubbles. The above state indicates that ultrasonic waves can be stably controlled.

• Non-destructive testing
• Other analytical equipment
• others

Development of an original ultrasonic system utilizing surface elastic wave control technology based on sound pressure measurement analysis.

The Ultrasonic System Research Institute has developed applied technologies that utilize surface acoustic waves through ultrasonic control. By combining ultrasound and surface acoustic waves, we achieve dynamic control of ultrasonic propagation. The key point is the ability to efficiently control nonlinear phenomena caused by surface acoustic waves. As specific technologies, we have developed system technologies that control nonlinear phenomena (bi-spectral) resulting from the interaction of ultrasound with water tanks and tools, tailored to specific purposes (cleaning, stirring, stress relief, inspection, etc.). As a result of utilizing measurement and analysis techniques for ultrasonic propagation states, we have confirmed the realization of harmonic control and the ability to adjust nonlinear phenomena. Our know-how lies in confirming and responding to the acoustic characteristics of the system (measurement, analysis, evaluation).

• Secondary steel products
• Other analytical equipment
• others

Dynamic Liquid Circulation System of Ultrasonic Cleaners - Acoustic Flow Control

(Development of a control system based on measurement and analysis of ultrasonic cleaning machines) The Ultrasonic System Research Institute has developed a technology that applies techniques for measuring and analyzing the state of ultrasonic cleaning machines propagating in liquid, to set and control the state of ultrasonic cleaning machines according to the effects of tank structure, strength, manufacturing conditions, and liquid circulation state. This technology analyzes and evaluates the dynamic characteristics of complex ultrasonic vibrations (Note 1) in relation to various factors, allowing for the setting of cavitation and acceleration effects according to specific purposes through the configuration of circulation pump settings (Note 2). Note 1: This utilizes the original technology of the Ultrasonic System Research Institute, which employs "ultrasonic oscillation control" technology considering "timbre." Note 2: The know-how involves settings related to the relationships at the boundaries of the cleaning machine, cleaning liquid, and air. It can also be applied to cleaning tanks that do not have an overflow structure. Regarding the self-organization of micro-flows, control of acoustic flow has become possible through degassing, aeration, ultrasound, and elastic waves on the tank surface.

• pump
• Other analytical equipment
• others

Consulting services for processing technology utilizing megahertz ultrasonic oscillation control - Utilizing nonlinear phenomena of ultrasound.

The Ultrasonic System Research Institute provides consulting services for ultrasonic processing technology using its original product: ultrasonic systems (sound pressure measurement analysis, oscillation control). In response to the current state of ultrasonic processing, we propose and implement ultrasonic enhancement and improvement methods based on sound pressure measurement and analysis. Specifically, we will discuss ultrasonic enhancements through the measurement and confirmation of processing machines using our original product: Ultrasonic Tester NA (recommended type), which allows for easy measurement and analysis of ultrasonic waves. In line with the ultrasonic enhancements, we propose the use of our original product: Ultrasonic Oscillation System (1 MHz, 20 MHz), which enables easy oscillation control of ultrasonic waves.

• Non-destructive testing
• Other measuring instruments
• others

Analysis of sound pressure measurement data (autocorrelation, power spectrum, bispectrum, power contribution rate, impulse response, etc.) evaluation and technology.

The Ultrasonic System Research Institute has developed a technology to optimize ultrasonic propagation systems that enable control of resonance and nonlinear phenomena based on various analysis results of ultrasonic propagation states using an original ultrasonic system (sound pressure measurement analysis and oscillation control). In contrast to existing control technologies, this technology utilizes new measurement and evaluation parameters (note) related to the entire propagation path of ultrasonic vibrations, including various propagation tools, to achieve dynamic propagation states of ultrasound tailored to specific applications (cleaning, stirring, processing, etc.). This is a method and technology that can be applied immediately, and we offer it as consulting services (with increasing achievements in ultrasonic processing, precision cleaning at the nano level, stirring, etc.). Note: The original technology product (ultrasonic sound pressure measurement analysis system) measures, analyzes, and evaluates dynamic changes in the propagation state of water tanks, transducers, target objects, and tools. (Parameters: power spectrum, autocorrelation, bispectrum, power contribution rate, impulse response characteristics, etc.)

• Non-destructive testing
• Scientific Calculation and Simulation Software
• others

Control technology for acoustic flow (nonlinear phenomena) based on sound pressure measurement analysis.

The Ultrasonic System Research Institute has developed a system that applies technology to measure and analyze the state of ultrasonic waves propagating in the liquid within an ultrasonic tank, setting and controlling the propagation state of ultrasonic waves according to the effects of the tank's structure, strength, manufacturing conditions, and the state of liquid circulation. The liquid circulation within the ultrasonic tank is captured as a system, and the primary purpose of many ultrasonic (tank) applications is to predict or control the sound pressure changes of the liquid inside the tank. However, numerous issues have been pointed out in many implementations due to discrepancies between theory and practice. In response to such cases: 1) The removal of obstacles involves the use of statistical data analysis methods, which is the technology for measuring and analyzing ultrasonic propagation states. 2) Based on the results of data analysis related to the subject, the characteristics of the subject are confirmed, which is the technology for detecting the acoustic properties related to the surface elastic waves of the object. 3) Progressing to control realization through characteristic confirmation involves technology for controlling nonlinear phenomena. By employing the above methods, the utilization state of ultrasonic waves has been improved for efficient use, and there are numerous examples of original systems that have realized the intended use of ultrasonic waves.

• Vibration and Sound Level Meter
• Scientific Calculation and Simulation Software
• others

Surface treatment technology using a megahertz ultrasonic oscillation control probe -- Improvement treatment of metal fatigue strength (relaxation and uniformization of surface residual stress) --

The Ultrasonic System Research Institute has developed methods for measuring, analyzing, and evaluating surface residual stress by applying the following technologies: 1) Manufacturing technology for ultrasonic probes 2) Evaluation technology for ultrasonic propagation conditions 3) Surface inspection technology using ultrasound Based on numerous achievements, we believe that various applications are possible as ultrasonic utilization technology, and we are making related technologies publicly available. Specific examples: Surface treatment know-how: Standard settings Output: 13-15V Rectangular wave: Duty 47.1% Sweep range: 500kHz - 13MHz, 2 seconds Settings for low-intensity targets (or long processing times): Output: 1-3V Rectangular wave: Duty 47.1% Sweep range: 300kHz - 3MHz, 1 second (or 100kHz - 5MHz, 1 second) Note: The oscillation conditions can vary significantly due to the ultrasonic propagation characteristics of the target object and the oscillation characteristics of the function generator. Ultrasonic propagation characteristics: 1) Detection of vibration modes (changes in self-correlation) 2) Detection of nonlinear phenomena (changes in bispectrum) 3) Detection of response characteristics (analysis of impulse response) 4) Detection of interactions (analysis of power contribution rates)

• Other measuring instruments
• Scientific Calculation and Simulation Software
• others

Do you have any concerns or requests regarding wired bed exit sensors? × Tangling or tripping over wired cables × Cable disconnection or damage × Worrying about forgetting to turn the switch back on after temporarily stopping the sensor. × Wanting to be notified of bed exits even from a location far from the nurse call outlet. Such concerns can be resolved simply by connecting our wireless nurse call linked set to the sensor! Our wireless nurse call linked set allows you to connect bed exit sensors like "Ugo-kun," "Foldable Thin Matta-kun," "Ayumi-chan," and "Just Place Pole-kun" to transmitters and receivers, reducing wiring around the bed area, alleviating concerns about tripping or falling due to cables, and contributing to a tidier work environment. Furthermore, it enables the use of bed exit sensors even from locations far from the nurse call outlet, allowing for more flexible equipment placement.

Japan is one of the top 10 countries in the world with frequent earthquakes. The 2020 White Paper on Land, Infrastructure, Transport and Tourism has also reported an increase in the probability of major earthquakes occurring. Regarding the Nankai Trough earthquake, the probability of an earthquake with a magnitude of 8 to 9 occurring within the next 30 years is estimated to be 70 to 80%. At Hotron, we recommend the introduction of seismic devices for earthquake countermeasures in buildings and equipment. The seismic device 'HK-2' is a product that automatically performs various controls that have been pre-set when it detects strong shaking equivalent to a seismic intensity of 5 lower or higher. For example, it can automatically execute actions such as: "Open automatic doors and gates to secure evacuation routes and access for emergency vehicles" "Transmit signals to the control room and stop facility equipment" "Unlock the keys to locked lockers" "Automatically play voice guidance" For more details, please download the materials or contact us.

The "HM-S6" is an embedded park sensor that detects vehicles through changes in magnetic flux and responds to various situations from passing to stationary vehicles. It can be used for the opening and closing of input doors at waste treatment plants, as well as for gates that vehicles pass through and outdoor parking applications. It can also be installed on rebar and steel plates. 【Features】 ■ Resistant to the effects of natural environments such as rain, snow, temperature changes, and geomagnetism ■ Protection rating IP68 reduces the risk of water ingress ■ Ten times the load capacity compared to conventional embedded park sensors (based on our comparison) ■ Can distinguish between vehicles even when they pass continuously ■ Can be installed on rebar and steel plates *For more details, please refer to the PDF document or feel free to contact us.

To customers considering the introduction of vehicle detection sensors for parking lot construction, design, or management: Are you facing any challenges with current issues or selecting the right sensors for parking management? Hotron offers free materials that explain how to utilize vehicle detection sensors and the benefits of their introduction! ▽ Here is the lineup of materials ◉ Vehicle Detection Sensor Basic Guide This guide focuses on the challenges and solutions in parking lot operations, introducing the overview of vehicle detection sensors. ◉ Key Points for Introducing Vehicle Detection Sensors This material discusses the benefits of introduction based on installation locations and specific challenges. ◉ Case Studies of Vehicle Detection Sensor Implementation This document presents the challenges before implementation and the results after introduction. For more details, please download from our website and check it out. https://www.hotron.co.jp/download/

SBS Marketing Co., Ltd., which provides consulting services related to marketing, sales promotion, and customer acquisition primarily in the BtoB (business-to-business) sector based on practical experience in support companies and business companies, has published a page titled "Project Budget Overruns, Delays, and Increased Resource Burden!? 'Scope Creep'" on November 11, 2025 (Tuesday). 'Scope creep' refers to the gradual expansion of a project's initial scope without following formal processes, leading to delays, budget overruns, and increased resource burdens. The page explains examples of occurrence, the negative impacts that can arise, as well as the causes and countermeasures. (Page Overview: Excerpts) ■ What is 'Scope Creep'? ■ Examples of 'Scope Creep' occurrence ■ Negative impacts caused by 'Scope Creep' ■ Causes of 'Scope Creep' ■ Countermeasures to prevent 'Scope Creep' (DL content only) ▼ For more details, please visit this page. https://sbsmarketing.co.jp/blog/scope-creep-2025-11/