Unlocking the Next Wave: How Kilohertz-Range Ultrasonic Non-Destructive Testing Systems Will Transform Industrial Inspection in 2025 and Beyond. Discover the Technologies, Trends, and Market Forces Shaping the Future of Precision Testing.

• Executive Summary: 2025 Market Outlook and Key Takeaways
• Technology Overview: Kilohertz-Range Ultrasonic NDT Fundamentals
• Current Market Size, Segmentation, and 2025 Growth Projections
• Key Industry Players and Strategic Initiatives (e.g., olympus-ims.com, ge.com, sonatest.com)
• Emerging Applications: Aerospace, Automotive, Energy, and Infrastructure
• Innovation Pipeline: Advances in Transducer Design and Signal Processing
• Regulatory Standards and Industry Guidelines (e.g., asnt.org, astm.org)
• Competitive Landscape and Strategic Partnerships
• Market Drivers, Challenges, and Risk Factors
• Future Outlook: 2025–2030 Forecasts, Growth Rate (CAGR 7–9%), and Disruptive Opportunities
• Sources & References

Executive Summary: 2025 Market Outlook and Key Takeaways

The market for kilohertz-range ultrasonic non-destructive testing (NDT) systems is poised for steady growth in 2025, driven by increasing demand for advanced inspection solutions across critical industries such as aerospace, automotive, energy, and infrastructure. These systems, operating typically in the 20 kHz to 1 MHz frequency range, are valued for their ability to detect subsurface flaws, measure material thickness, and ensure structural integrity without causing damage to the tested components.

Key industry players, including Olympus Corporation, GE Vernova (formerly GE Inspection Technologies), and Sonatest, continue to innovate in transducer design, digital signal processing, and portable device integration. In 2025, these companies are expected to focus on enhancing system sensitivity, user interface simplicity, and data connectivity, aligning with broader trends in industrial digitalization and predictive maintenance.

The adoption of kilohertz-range ultrasonic NDT is being accelerated by stricter regulatory standards and the aging of global infrastructure, particularly in sectors such as oil & gas and transportation. For example, pipeline operators and rail networks are increasingly required to implement regular, high-precision inspections to prevent catastrophic failures. This regulatory environment is fostering demand for both handheld and automated ultrasonic systems, with a notable shift toward solutions that can be integrated into robotic and drone-based platforms for remote or hazardous environments.

In 2025, the market is also witnessing a growing emphasis on data analytics and cloud-based reporting, with manufacturers such as Olympus Corporation and GE Vernova investing in software platforms that enable real-time defect characterization and fleet-wide asset monitoring. This digital transformation is expected to enhance the value proposition of ultrasonic NDT by reducing inspection times, improving traceability, and supporting predictive maintenance strategies.

Looking ahead to the next few years, the kilohertz-range ultrasonic NDT sector is projected to benefit from continued R&D in piezoelectric materials, miniaturization of electronics, and the integration of artificial intelligence for automated defect recognition. Strategic partnerships between equipment manufacturers and end-users are likely to accelerate the deployment of customized solutions tailored to specific industry needs.

• Steady market growth anticipated through 2025, driven by regulatory compliance and infrastructure renewal.
• Key players such as Olympus Corporation, GE Vernova, and Sonatest are leading innovation in system capabilities and digital integration.
• Adoption of cloud-based analytics and AI-driven defect detection is set to transform inspection workflows.
• Emerging applications in robotics and remote inspection platforms are expanding the addressable market.

Technology Overview: Kilohertz-Range Ultrasonic NDT Fundamentals

Kilohertz-range ultrasonic non-destructive testing (NDT) systems utilize sound waves in the frequency range of approximately 20 kHz to 1 MHz to inspect, characterize, and evaluate materials and structures without causing damage. These systems are fundamental in industries such as aerospace, automotive, energy, and manufacturing, where the integrity of components is critical. The kilohertz range, as opposed to the more common megahertz-range ultrasonic NDT, is particularly suited for the inspection of thick, attenuative, or highly scattering materials, such as concrete, composites, and certain metals, where higher frequencies would suffer from excessive signal loss.

The core technology involves generating ultrasonic pulses using piezoelectric transducers, which are then transmitted into the test object. The reflected or transmitted signals are captured and analyzed to detect internal flaws, measure thickness, or assess material properties. Lower-frequency (kilohertz-range) systems offer deeper penetration and are less sensitive to small defects, making them ideal for bulk inspections and for materials with coarse grain structures. Recent advances in digital signal processing, phased array techniques, and portable instrumentation have significantly enhanced the resolution, reliability, and usability of these systems.

Key manufacturers and technology providers in this sector include Olympus Corporation, which offers a range of ultrasonic NDT equipment, including low-frequency transducers for challenging applications. GE Vernova (formerly GE Inspection Technologies) is another major player, providing ultrasonic flaw detectors and phased array systems capable of operating in the kilohertz range. Sonatest specializes in portable ultrasonic NDT devices, with models designed for low-frequency applications such as concrete and composite inspection. Krautkrämer, now part of Baker Hughes, is recognized for its robust ultrasonic testing solutions, including systems tailored for thick-section and attenuative materials.

In 2025, the trend is toward greater integration of digital technologies, such as real-time data analytics, wireless connectivity, and cloud-based reporting, which are making kilohertz-range ultrasonic NDT systems more accessible and efficient. The adoption of advanced phased array and full matrix capture (FMC) techniques is expected to further improve defect characterization and imaging capabilities. Looking ahead, the next few years will likely see continued miniaturization of equipment, enhanced automation (including robotic deployment), and broader application in infrastructure health monitoring, driven by increasing regulatory and safety demands across industries.

Current Market Size, Segmentation, and 2025 Growth Projections

The market for kilohertz-range ultrasonic non-destructive testing (NDT) systems is experiencing robust growth in 2025, driven by increasing demand for reliable inspection solutions across industries such as aerospace, automotive, energy, and manufacturing. These systems, operating typically in the 20 kHz to 1 MHz frequency range, are valued for their ability to detect internal flaws, measure thickness, and assess material properties without causing damage to the tested components.

Current estimates place the global market size for ultrasonic NDT equipment—including kilohertz-range systems—at several billion USD, with a compound annual growth rate (CAGR) projected in the high single digits through the next few years. This growth is underpinned by stringent safety regulations, aging infrastructure, and the ongoing shift toward automation and digitalization in industrial inspection processes.

Market segmentation is primarily based on technology (conventional ultrasonic testing, phased array, and advanced modalities), end-user industry, and geography. Conventional kilohertz-range ultrasonic systems remain widely used for thickness gauging and flaw detection in metals, composites, and welds. The aerospace sector, for example, relies heavily on these systems for routine inspection of aircraft structures, while the oil & gas industry uses them for pipeline and pressure vessel monitoring. The automotive sector is also a significant adopter, particularly for quality assurance in manufacturing and assembly lines.

Regionally, North America and Europe continue to lead in adoption, supported by established industrial bases and regulatory frameworks. However, Asia-Pacific is emerging as the fastest-growing market, fueled by rapid industrialization, infrastructure development, and expanding manufacturing activities in countries such as China, India, and South Korea.

Key industry players include Olympus Corporation, a global leader in ultrasonic NDT equipment, offering a broad portfolio of kilohertz-range systems for diverse applications. GE Vernova (formerly GE Inspection Technologies) is another major supplier, known for its advanced ultrasonic flaw detectors and thickness gauges. Sonatest Ltd and Krautkrämer (a brand under Baker Hughes) are also prominent, with strong presences in Europe and North America. These companies are investing in R&D to enhance system sensitivity, portability, and integration with digital platforms.

Looking ahead, the market is expected to benefit from continued advancements in sensor technology, data analytics, and automation. The integration of kilohertz-range ultrasonic NDT systems with industrial IoT and cloud-based data management is anticipated to further drive adoption, particularly in predictive maintenance and asset integrity management. As industries prioritize safety, efficiency, and cost-effectiveness, the outlook for kilohertz-range ultrasonic NDT systems remains highly positive through 2025 and beyond.

Key Industry Players and Strategic Initiatives (e.g., olympus-ims.com, ge.com, sonatest.com)

The kilohertz-range ultrasonic non-destructive testing (NDT) systems market in 2025 is characterized by the presence of several established global players, each leveraging advanced technologies and strategic initiatives to maintain and expand their market positions. These companies are focusing on innovation, digital integration, and global partnerships to address the evolving needs of industries such as aerospace, automotive, energy, and manufacturing.

One of the most prominent companies in this sector is Olympus IMS, a division of Olympus Corporation. Olympus IMS is recognized for its comprehensive portfolio of ultrasonic NDT equipment, including portable flaw detectors and phased array systems operating in the kilohertz frequency range. In 2025, Olympus continues to invest in R&D to enhance the sensitivity and data processing capabilities of its devices, with a particular focus on integrating artificial intelligence (AI) for automated defect recognition and cloud-based data management. The company’s global service network and training programs further strengthen its market leadership.

Another key player is GE, through its GE Inspection Technologies division (now part of Baker Hughes). GE’s ultrasonic NDT solutions are widely used for critical infrastructure inspection, offering both conventional and advanced phased array systems. In recent years, GE has emphasized digital transformation, embedding Industrial Internet of Things (IIoT) connectivity and advanced analytics into its ultrasonic platforms. This enables real-time data sharing and predictive maintenance, aligning with the broader industry shift toward smart manufacturing and asset integrity management.

UK-based Sonatest is another significant contributor, known for its robust and user-friendly ultrasonic flaw detectors and thickness gauges. Sonatest’s strategic initiatives in 2025 include expanding its product line with enhanced portable devices tailored for field applications and developing software solutions for improved data visualization and reporting. The company also collaborates with academic and industrial partners to advance ultrasonic testing methodologies, particularly in the kilohertz range for challenging materials and geometries.

Other notable industry participants include Krautkramer (now part of Waygate Technologies, a Baker Hughes business), which continues to innovate in high-performance ultrasonic transducers and automated inspection systems, and Eddyfi Technologies, which is expanding its ultrasonic NDT offerings through acquisitions and technology integration.

Looking ahead, the competitive landscape is expected to intensify as companies invest in digitalization, automation, and global service capabilities. Strategic partnerships, mergers, and acquisitions are likely to shape the market, with a focus on delivering more intelligent, connected, and user-centric kilohertz-range ultrasonic NDT solutions to meet the demands of safety-critical industries.

Emerging Applications: Aerospace, Automotive, Energy, and Infrastructure

Kilohertz-range ultrasonic non-destructive testing (NDT) systems are experiencing rapid adoption and innovation across critical sectors such as aerospace, automotive, energy, and infrastructure. These systems, operating typically in the 20 kHz to several hundred kHz range, are valued for their ability to detect subsurface flaws, measure material thickness, and assess structural integrity without causing damage. As of 2025, several trends and developments are shaping their application landscape.

In the aerospace sector, the demand for lightweight composite materials and stringent safety requirements are driving the integration of advanced ultrasonic NDT. Aircraft manufacturers and maintenance providers are increasingly deploying phased array and immersion ultrasonic systems for the inspection of complex geometries and bonded structures. Companies such as Olympus Corporation and GE Aerospace (through its NDT division) are at the forefront, offering portable and automated solutions tailored for in-service inspections and manufacturing quality control. The push towards digitalization and predictive maintenance is further accelerating the adoption of real-time, high-resolution ultrasonic data analytics in aerospace.

In the automotive industry, kilohertz-range ultrasonic NDT is increasingly utilized for spot weld inspection, detection of adhesive bond quality, and evaluation of advanced high-strength steels and aluminum alloys. The shift towards electric vehicles (EVs) and lightweighting strategies has heightened the need for reliable, rapid, and non-invasive inspection methods. Major automotive suppliers and OEMs are collaborating with NDT technology providers such as Sonatest and Zetec to integrate ultrasonic systems into automated production lines, supporting higher throughput and traceability.

The energy sector—including oil & gas, nuclear, and renewables—relies on ultrasonic NDT for pipeline inspection, weld integrity assessment, and corrosion monitoring. The transition to hydrogen and renewable energy infrastructure is creating new challenges for material inspection, particularly for high-pressure vessels and composite pipelines. Companies like Baker Hughes (through its Panametrics brand) are expanding their ultrasonic NDT offerings to address these emerging needs, with a focus on rugged, field-deployable systems and advanced signal processing.

In infrastructure, ultrasonic NDT is critical for the assessment of bridges, tunnels, and concrete structures. The increasing age of global infrastructure and the need for life extension programs are driving investment in portable and robotic ultrasonic inspection systems. Organizations such as MISTRAS Group are deploying integrated NDT solutions that combine kilohertz-range ultrasonics with data management platforms for asset health monitoring.

Looking ahead, the next few years are expected to see further miniaturization, increased automation, and the integration of artificial intelligence in kilohertz-range ultrasonic NDT systems. These advances will enable more frequent, reliable, and cost-effective inspections across aerospace, automotive, energy, and infrastructure, supporting safety, sustainability, and operational efficiency.

Innovation Pipeline: Advances in Transducer Design and Signal Processing

The innovation pipeline for kilohertz-range ultrasonic non-destructive testing (NDT) systems is rapidly evolving, with significant advances in both transducer design and signal processing expected to shape the sector through 2025 and the following years. These developments are driven by the increasing demand for higher sensitivity, improved resolution, and more robust performance in challenging industrial environments such as aerospace, energy, and infrastructure.

Transducer technology is at the forefront of this innovation. Leading manufacturers are focusing on the development of broadband, low-frequency (kHz-range) transducers that can penetrate thick or highly attenuative materials, such as composites and concrete, which are common in modern infrastructure and energy assets. Companies like Olympus Corporation and GE (through its Inspection Technologies division) are investing in piezoelectric and capacitive micromachined ultrasonic transducer (CMUT) technologies, aiming to enhance both sensitivity and durability. These new transducers are being designed to operate efficiently at lower frequencies (typically 20–500 kHz), enabling deeper penetration and improved flaw detection in large or complex structures.

Signal processing is another area witnessing rapid progress. The integration of advanced digital signal processing (DSP) algorithms, including machine learning and artificial intelligence, is enabling more accurate interpretation of ultrasonic signals, even in noisy or heterogeneous materials. Companies such as Sonatest and Zetec are incorporating real-time data analytics and automated defect recognition into their NDT platforms, reducing operator dependency and increasing inspection reliability. These systems are also leveraging cloud connectivity for remote diagnostics and data sharing, a trend expected to accelerate as industrial digitalization continues.

Another notable trend is the miniaturization and ruggedization of ultrasonic probes and electronics, allowing for easier deployment in confined or harsh environments. Modular and wireless systems are gaining traction, with companies like Olympus Corporation and GE introducing portable, battery-powered units that maintain high performance in the kilohertz range.

Looking ahead, the outlook for kilohertz-range ultrasonic NDT systems is marked by continued convergence of hardware and software innovation. The next few years are likely to see further integration of AI-driven analytics, enhanced transducer materials for broader bandwidth and higher power handling, and expanded use of digital twins for predictive maintenance. As regulatory standards evolve and asset owners demand more reliable, data-rich inspections, the sector is poised for robust growth and technological advancement.

Regulatory Standards and Industry Guidelines (e.g., asnt.org, astm.org)

The regulatory landscape for kilohertz-range ultrasonic non-destructive testing (NDT) systems is shaped by a combination of international standards, industry guidelines, and evolving best practices. As of 2025, the sector is experiencing heightened scrutiny and harmonization efforts, driven by the increasing adoption of advanced ultrasonic NDT technologies in critical industries such as aerospace, energy, and infrastructure.

Key standards organizations, including the ASTM International and the American Society for Nondestructive Testing (ASNT), continue to play pivotal roles in defining the requirements for ultrasonic NDT equipment and procedures. ASTM’s E317 and E114 standards, for example, specify the calibration and performance criteria for ultrasonic testing instruments and transducers, with recent revisions emphasizing traceability, digital data handling, and compatibility with lower-frequency (kilohertz-range) systems. These updates reflect the growing use of kilohertz-range ultrasonics for applications such as thick-section inspection and coarse-grained material evaluation, where lower frequencies offer improved penetration and signal-to-noise ratios.

ASNT, through its Recommended Practice No. SNT-TC-1A and the CP-189 standard, continues to set the benchmark for personnel qualification and certification in ultrasonic NDT. In 2025, there is a notable trend toward integrating competency requirements specific to kilohertz-range systems, recognizing the unique challenges and skillsets associated with interpreting lower-frequency ultrasonic data. This is particularly relevant as industries seek to address aging infrastructure and extend asset lifecycles, necessitating reliable detection of subsurface flaws in large or attenuative components.

On the international front, the International Organization for Standardization (ISO) maintains ISO 16810 and related standards, which provide a framework for ultrasonic testing terminology, principles, and equipment performance. Recent ISO working group activities have focused on harmonizing definitions and acceptance criteria for kilohertz-range applications, aiming to facilitate cross-border equipment certification and data comparability.

Industry bodies such as the American Society of Mechanical Engineers (ASME) and the American Petroleum Institute (API) are also updating their codes to reference the latest ultrasonic NDT standards, particularly for pressure vessels, pipelines, and structural welds. These updates are expected to be adopted in new construction and in-service inspection programs over the next few years, further embedding kilohertz-range ultrasonic NDT as a mainstream practice.

Looking ahead, regulatory convergence and digitalization are anticipated to drive further evolution of standards. The integration of data analytics, remote monitoring, and automated reporting into ultrasonic NDT workflows is prompting standards bodies to address cybersecurity, data integrity, and interoperability. As kilohertz-range ultrasonic systems become more prevalent, ongoing collaboration between manufacturers, end-users, and standards organizations will be essential to ensure safety, reliability, and regulatory compliance across industries.

Competitive Landscape and Strategic Partnerships

The competitive landscape for kilohertz-range ultrasonic non-destructive testing (NDT) systems in 2025 is characterized by a mix of established global players and innovative niche specialists. The sector is witnessing increased activity in strategic partnerships, technology licensing, and collaborative R&D, as companies seek to address evolving industrial requirements for higher sensitivity, automation, and integration with digital platforms.

Major multinational corporations such as Olympus Corporation and GE (through its GE Inspection Technologies division) continue to dominate the market, leveraging their extensive product portfolios, global distribution networks, and strong brand recognition. These companies are investing in the development of advanced kilohertz-range ultrasonic systems with enhanced signal processing, real-time data analytics, and compatibility with Industry 4.0 frameworks. Olympus Corporation has notably expanded its partnerships with automation and robotics firms to deliver integrated inspection solutions for aerospace and energy sectors.

European firms such as Sonatest and Krautkrämer (now part of Baker Hughes) are also prominent, focusing on portable and modular ultrasonic NDT systems. These companies are increasingly collaborating with software developers to enhance the user interface and data management capabilities of their kilohertz-range devices. Baker Hughes has announced joint ventures with industrial automation providers to accelerate the deployment of ultrasonic NDT in pipeline and infrastructure monitoring.

In Asia, Olympus Corporation and Jireh Industries are expanding their presence, particularly in China and India, through local manufacturing partnerships and technology transfer agreements. These collaborations are aimed at meeting the growing demand for cost-effective, high-throughput inspection systems in automotive and construction industries.

Startups and university spin-offs are also contributing to the competitive dynamics by introducing novel transducer materials, miniaturized probes, and AI-driven defect recognition algorithms. Strategic alliances between these innovators and established OEMs are expected to accelerate commercialization and adoption of next-generation kilohertz-range ultrasonic NDT systems.

Looking ahead, the next few years are likely to see further consolidation, with mergers and acquisitions driven by the need for end-to-end digital inspection solutions and global service capabilities. The trend toward open-platform architectures and interoperability standards is fostering new forms of partnership, as companies seek to integrate kilohertz-range ultrasonic NDT with complementary technologies such as eddy current and thermography.

Market Drivers, Challenges, and Risk Factors

The market for kilohertz-range ultrasonic non-destructive testing (NDT) systems is being shaped by a convergence of technological, regulatory, and industrial factors as of 2025. These systems, operating typically in the 20 kHz to 1 MHz range, are critical for detecting flaws, measuring thickness, and ensuring structural integrity across sectors such as aerospace, automotive, energy, and manufacturing.

Market Drivers

• Stringent Safety and Quality Regulations: Regulatory bodies worldwide are enforcing stricter standards for infrastructure and component safety, particularly in aerospace and energy. This is driving demand for advanced NDT solutions, including kilohertz-range ultrasonic systems, which offer reliable subsurface defect detection. Companies like Evident (formerly Olympus IMS) and GE are at the forefront, supplying equipment that meets these evolving requirements.
• Industrial Automation and Digitalization: The integration of NDT systems into automated production lines and digital asset management platforms is accelerating. Kilohertz-range ultrasonic devices are increasingly being designed for compatibility with robotics and IoT frameworks, as seen in offerings from Sonatest and Zetec, enabling real-time data acquisition and predictive maintenance.
• Infrastructure Aging and Expansion: The need to inspect aging infrastructure—pipelines, bridges, and power plants—without service interruption is a significant driver. Ultrasonic NDT systems are favored for their portability and ability to provide rapid, accurate assessments, supporting asset life extension strategies.

Challenges

• Technical Complexity and Skill Shortage: The operation and interpretation of kilohertz-range ultrasonic NDT systems require specialized expertise. The industry faces a shortage of qualified technicians, which can limit adoption rates and increase operational costs.
• Equipment Cost and ROI Concerns: High initial investment in advanced ultrasonic NDT equipment, especially for small and medium enterprises, remains a barrier. While companies like Evident and GE are working to offer scalable solutions, cost sensitivity persists in price-driven markets.
• Standardization and Interoperability: The lack of universal standards for data formats and system interoperability can hinder integration with broader digital inspection ecosystems, slowing widespread adoption.

Risk Factors and Outlook

• Economic Uncertainty: Fluctuations in capital expenditure, particularly in oil & gas and heavy industry, may impact procurement cycles for NDT equipment in the near term.
• Technological Disruption: Advances in alternative NDT modalities (e.g., phased array, electromagnetic) could shift market preferences, though kilohertz-range ultrasonic systems are expected to retain a core role due to their versatility and established track record.
• Cybersecurity and Data Privacy: As ultrasonic NDT systems become more connected, concerns over data security and compliance with privacy regulations are emerging, prompting manufacturers to invest in secure data management solutions.

Looking ahead, the market is poised for steady growth, underpinned by regulatory momentum, digital transformation, and ongoing infrastructure needs. Leading manufacturers such as Evident, GE, Sonatest, and Zetec are expected to drive innovation, with a focus on automation, user-friendly interfaces, and integration with broader asset management platforms.

Future Outlook: 2025–2030 Forecasts, Growth Rate (CAGR 7–9%), and Disruptive Opportunities

The outlook for kilohertz-range ultrasonic non-destructive testing (NDT) systems from 2025 to 2030 is marked by robust growth, technological innovation, and expanding application domains. Industry consensus projects a compound annual growth rate (CAGR) between 7% and 9% for ultrasonic NDT systems, driven by increasing demand for advanced inspection solutions in sectors such as aerospace, automotive, energy, and infrastructure. This growth is underpinned by the need for higher reliability, safety, and regulatory compliance in critical assets and components.

Key manufacturers such as Olympus Corporation, GE Vernova (formerly GE Inspection Technologies), and Sonatest are investing in R&D to enhance the sensitivity, portability, and data analytics capabilities of kilohertz-range ultrasonic systems. These companies are focusing on integrating artificial intelligence (AI) and machine learning algorithms to automate defect detection and classification, reducing operator dependency and improving inspection throughput. For example, Olympus Corporation has introduced phased array ultrasonic testing (PAUT) systems with advanced imaging and real-time data processing, which are expected to see wider adoption through 2030.

The energy sector, particularly wind and nuclear power, is anticipated to be a major driver of demand for kilohertz-range ultrasonic NDT. The aging infrastructure in Europe and North America, combined with new installations in Asia-Pacific, will require regular, high-precision inspection to ensure operational safety and longevity. Companies like GE Vernova are already collaborating with utilities and OEMs to deploy ultrasonic NDT for turbine blade and pipeline inspection.

Disruptive opportunities are emerging from the convergence of ultrasonic NDT with digital platforms and the Industrial Internet of Things (IIoT). Wireless, battery-powered ultrasonic sensors capable of continuous monitoring are being developed, enabling predictive maintenance and real-time asset health management. Sonatest and other innovators are piloting cloud-connected NDT devices that facilitate remote diagnostics and data sharing across global operations.

• By 2030, miniaturized, AI-enabled ultrasonic probes are expected to become standard in automated and robotic inspection systems, particularly for complex geometries and hard-to-reach areas.
• Emerging markets in Asia, Latin America, and the Middle East are projected to accelerate adoption, supported by infrastructure investments and stricter safety regulations.
• Collaborations between NDT equipment manufacturers and software developers will likely yield new service models, such as NDT-as-a-Service, further expanding market reach.

Overall, the kilohertz-range ultrasonic NDT sector is poised for significant transformation, with digitalization, automation, and global infrastructure needs shaping its trajectory through 2030.

Sources & References

• Olympus Corporation
• GE Vernova
• Sonatest
• Krautkrämer
• Olympus Corporation
• Eddyfi Technologies
• Zetec
• Baker Hughes
• MISTRAS Group
• ASTM International
• American Society for Nondestructive Testing (ASNT)
• International Organization for Standardization (ISO)
• American Society of Mechanical Engineers (ASME)
• American Petroleum Institute (API)
• Jireh Industries