Developed "Dynamic System of Ultrasonics: Liquid Circulation Control Technology."

Technology for evaluating the dynamic characteristics of ultrasonic probes.

The Ultrasonic System Research Institute has developed manufacturing and evaluation technology for ultrasonic probes that can control ultrasonic propagation states from 500 Hz to 900 MHz, based on the classification of ultrasonic propagation characteristics (acoustic characteristics). We can manufacture and develop original ultrasonic oscillation control probes tailored to specific purposes. This technology is available for consulting. If you are interested, please contact us via email. Propagation characteristics of ultrasonic probes: 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 (interaction between oscillation voltage and received voltage: analysis of power contribution rate) Note: "R" is a free statistical processing language and environment. - autocor: autocorrelation analysis function - bispec: bispectrum analysis function - mulmar: impulse response analysis function - mulnos: power contribution rate analysis function

• Non-destructive testing
• Vibration and Sound Level Meter
• Scientific Calculation and Simulation Software

Optimization technology based on measurement and analysis of ultrasonic propagation of the target.

<Dynamic Control System for Ultrasound> The propagation state of ultrasound is captured as a system, and analysis and control are performed. Many purposes for utilizing ultrasound involve predicting or controlling the nonlinear phenomena of ultrasound propagating through target objects or liquids. However, in many implementations, numerous issues have been pointed out due to the differences between the theory of cavitation and actual results. In response to such cases: 1) To eliminate obstacles, for ultrasound that changes over time, statistical data processing of sound pressure data is conducted, known as <Measurement and Analysis Technology for Ultrasound Propagation State>. 2) Based on the results of data analysis related to the target, the acoustic characteristics of the target are confirmed through <Technology for Detecting Acoustic Characteristics Related to Surface Elastic Waves of Target Objects and Acoustic Flow of Target Liquids>. 3) By confirming the characteristics, progress is made towards achieving dynamic control of ultrasound through <Technology for Controlling Nonlinear Phenomena with Sweep Oscillation Control for Multiple Ultrasounds>. Through these methods, the utilization state of ultrasound has been improved for efficient use, and there are numerous examples of original ultrasound control systems that achieve the intended use of ultrasound.

• pump
• Analysis and prediction system
• others

Dynamic control technology for ultrasonic cleaning machines.

The Ultrasonic System Research Institute has developed ultrasonic cleaning technology utilizing the "Constructal Law" related to flow and shape. <References> 1) On Vibration From the Royal Institution's 133rd lecture "Vibration" I intend to describe almost all of the important fields of mechanical engineering here. [Author] Richard B. Bishop [Translator] Hidetaro Nakayama, Kodansha (1981, B-471) 2) Flow and Shape The evolution of all shapes is governed by the "Constructal Law," which aims to improve flow! [Authors] Adrian Bejan, J. Peder Zane [Translator] Hiroyuki Shibata, [Commentator] Shigeo Kimura, Kinokuniya (2013) 3) How Cybernetics Was Born [Author] Norbert Wiener [Translator] Yasuo Shizume, Misuzu Shobo (1956) Using the above as references and hints, we have organized the technology for measuring and utilizing "nonlinear effects" in ultrasonic propagation phenomena according to the "Constructal Law," which aims to improve flow, culminating in ultrasonic cleaning technology.

• pump
• Drainage and ventilation equipment
• 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

Ultrasonic system combining "Ultrasonic Tester NA (10 MHz)" and "Ultrasonic Oscillator (20 MHz)"

An ultrasonic system that allows for easy measurement analysis and oscillation control. The Ultrasonic System Research Institute is publicly conducting experiments using a system that combines the "Ultrasonic Tester NA (recommended type)," which allows for easy measurement analysis of ultrasonic waves, and the "Ultrasonic Oscillation System (20 MHz)," which enables easy oscillation control of ultrasonic waves. Ultrasonic Probe: Overview Specifications - Measurement Range: 0.01 Hz to 200 MHz - Oscillation Range: 0.5 kHz to 25 MHz - Propagation Range: 0.5 kHz to over 900 MHz (confirmed and evaluated through analysis) - Materials: Stainless steel, LCP resin, silicone, Teflon, glass, etc. - Oscillation Equipment Example: Function Generator Note: 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) Note: "R" Free Statistical Processing Language and Environment - autocor: Autocorrelation Analysis Function - bispec: Bispectrum Analysis Function - mulmar: Impulse Response Analysis Function - mulnos: Power Contribution Rate Analysis Function

• Water Treatment
• Other analytical equipment
• others

- Control technology for ultrasonic probe oscillation using a function generator -

The Ultrasonic System Research Institute has developed a technology to control the nonlinear phenomena of ultrasound by optimizing various interactions through the oscillation control of two types of ultrasonic probes from two oscillation channels of a function generator. Note: Nonlinear (resonance) phenomenon The resonance phenomenon that occurs due to the generation of harmonics resulting from original oscillation control, leading to a high amplitude of ultrasonic vibrations. By optimizing the ultrasonic propagation characteristics of various materials according to their intended purpose, efficient ultrasonic oscillation control becomes possible. Through the measurement and analysis of sound pressure data from ultrasonic testers, this system technology allows for the control of dynamic changes in surface elastic waves according to their intended use. 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)

• Non-destructive testing
• Vibration and Sound Level Meter
• IoT

Vibration measurement device using ultrasonic waves - Application of megahertz ultrasonic oscillation control technology -

The Ultrasonic System Research Institute has developed a completely new technology for controlling vibrations using original products (ultrasonic systems). Based on the analysis and evaluation of the nonlinear phenomena of ultrasound, we perform oscillation control of megahertz ultrasound, utilizing the sound pressure measurement analysis and oscillation control technology we have developed so far. From the accumulation of data measuring, analyzing, and evaluating the dynamic characteristics of ultrasound propagating on surfaces, we apply technology that can measure, analyze, and evaluate vibration states from low frequencies (0.1 Hz) to high frequencies (over 900 MHz). Measures based on new vibration measurement analysis have become possible regarding vibrations and noise from buildings and roads, equipment, devices, walls, piping, desks, handrails, the moment of vibration when metal melts during welding, instantaneous vibrations during machining, and the complex vibration states of entire manufacturing devices and systems. This is a new method and technology, and various application cases have developed from the results of previous implementations. In particular, it is possible to measure and respond to vibrations at very low frequencies and irregularly fluctuating vibrations.

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

Technology for manufacturing megahertz ultrasonic oscillation control probes - Consulting support for manufacturing know-how.

The Ultrasonic System Research Institute has developed a technology to manufacture ultrasonic probes that can control ultrasonic propagation states above 900 MHz, tailored to specific applications. Ultrasonic Probe: Overview Specifications - Measurement Range: 0.01 Hz to 200 MHz - Oscillation Range: 1.0 kHz to 25 MHz - Propagation Range: 0.5 kHz to over 900 MHz (confirmation of sound pressure data analysis) - Materials: Stainless steel, LCP resin, silicone, Teflon, glass, etc. - Oscillation Equipment: Example - Function Generator By understanding the acoustic properties of metals, resins, glass, etc., we achieve propagation states tailored to objectives regarding sound pressure levels, frequency, and dynamic characteristics through oscillation control. 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) 4) Detection of interactions (analysis of power contribution rates) Note: "R" is a free statistical processing language and environment. autcor: Autocorrelation analysis function bispec: Bispectrum analysis function mulmar: Impulse response analysis function mulnos: Power contribution rate analysis function

• Non-destructive testing
• Vibration and Sound Level Meter
• others

―― Is attendance management becoming a "burden" without you realizing it? A seminar to quickly learn about common issues and their solutions ―― We will be holding our attendance management web seminar in October, which takes place several times a year! The content is new, so whether you have participated in our webinars before or not, please feel free to join us. Date and Time: October 15 (Wednesday) 13:00- October 22 (Wednesday) 11:00- *Both days will cover the same content *Please check the link below for registration. In this seminar, we will recreate common situations in the workplace in a short drama format for easy understanding, and introduce specific solutions to each issue. This content is especially recommended for those who think, "I'm not struggling now, but I want to know information for the future." Common workplace "situations" can be a trigger for improvement. We will clearly present the challenges and countermeasures of attendance management. Recommended for: ❏ Those who take a long time to compile monthly attendance ❏ Those who tend to postpone compliance with legal revisions ❏ Those who currently have no major complaints but want to know hints for improvement ❏ Those who want to refer to initiatives and examples from other companies

On Monday, September 22, the Japan Meteorological Agency announced its three-month forecast for October to December. Due to the continued influence of conditions similar to the La Niña phenomenon until around December, the westerly winds are expected to flow more to the north than usual from October to early November, making it likely that warm air will cover the entire country. From late November to December, the westerly winds are expected to meander southward near Japan, and there may be periods when the winter pressure pattern strengthens. In December, the region is likely to be affected by cold air, and temperatures in western and eastern Japan are expected to be around or lower than the average for the season. For more details, please visit our website.

PTC Japan will support the CAR and DRIVER team, a car magazine founded in 1978, which will participate in the 36th "Media Challenge Roadster Endurance Race" held at Fuji Speedway on Saturday, October 4, 2025, continuing from last year.

PTC announced today the release of an AI assistant that supports Arena's Product Lifecycle Management (PLM) and Quality Management System (QMS). The Arena AI Assistant provides context-specific expertise and optimal operational methods in a conversational format in real-time for tasks related to Product Lifecycle Management (PLM) and Quality Management (QMS). This enables user teams to realize value in a shorter amount of time.

The seventh installment of the beginner-friendly 3D CAD Creo Parametric tutorial series focuses on features suitable for designs using frames, such as aluminum and sheet metal. It allows for easy realization of 3D solid structures.