Fact-checked by Grok 2 weeks ago

Prognostics

Prognostics is an engineering discipline that involves predicting the remaining useful life (RUL) of a , subsystem, or component until it no longer performs its intended function, often through the estimation of failure times based on current health conditions, future loads, and environmental factors. This process is a core element of prognostics and health management (PHM), which integrates , algorithms, and models to enable and minimize unplanned downtime. Emerging in the 1990s alongside advancements in health monitoring technologies, prognostics gained prominence through efforts by organizations such as , the U.S. Department of Defense (), and industry leaders to enhance vehicle health management in applications. It builds on diagnostics— which identify and isolate existing faults—by forecasting future degradation, thereby supporting proactive decision-making for reliability and mission assurance. Key benefits include reduced maintenance costs, maximized operational availability, and prevention of secondary damage from failures, as demonstrated in DoD's Condition Based Maintenance Plus (CBM+) initiatives where PHM enables reduction of downtime to three days in maintenance actions through predictive scheduling. Prognostics methods are broadly categorized into data-driven, physics-based, and hybrid approaches. Data-driven techniques, such as neural networks and particle filtering, rely on statistical analysis of historical and real-time sensor data to model trends without requiring detailed physical knowledge. Physics-based methods use mathematical models of underlying mechanisms, like cumulative damage propagation, to simulate future states under varying conditions. Hybrid methods combine these for improved accuracy, particularly in uncertain environments with noisy data. Challenges in implementation include managing uncertainties via probability distributions, validating algorithms against limited data, and defining performance metrics like prediction accuracy and convergence time. Applications span multiple domains, including for predicting component failures, electronics for life estimation, and for crack propagation in materials. In practice, prognostics supports scheduled maintenance based on condition rather than fixed intervals, optimizing and enhancing in high-stakes systems like military vehicles and . Ongoing research emphasizes integration with advanced sensors and to address real-world complexities, with recent advancements as of 2025 including hybrid AI methods and digital twins for enhanced accuracy, ensuring prognostics evolves as a vital tool for practices.

Overview

Definition and Principles

Prognostics is an focused on predicting the future health state and remaining useful life (RUL) of a or component based on its , observed degradation trends, and operational context. The term originates from word progignōskein, meaning "to know in advance," reflecting its emphasis on foresight to anticipate failures rather than merely responding to them. In practice, prognostics estimates the time to failure (TTF) or RUL, along with associated uncertainties and risks, to enable proactive in and operations. At its core, prognostics operates on the principle of forward-looking prediction, contrasting with traditional reactive maintenance strategies that address issues only after they occur. This approach integrates seamlessly within broader Prognostics and Health Management (PHM) frameworks, where it supports condition-based maintenance by combining , , and to optimize system availability, safety, and lifecycle costs. Key stages in prognostics include to identify deviations from normal behavior, to quantify progressive deterioration, and RUL prediction to forecast when the system will reach an unacceptable performance threshold. These principles prioritize early intervention, leveraging to transition from corrective to predictive paradigms in fields like and . Prognostics distinctly differs from diagnostics, which focuses on detecting and isolating current faults or failures in a . While diagnostics provides a snapshot of existing issues through , prognostics extends this by projecting future degradation trajectories and failure probabilities, often incorporating probabilistic models to account for variability in operating conditions. This forward-oriented focus enables prognostics to inform long-term planning, such as scheduling maintenance before failures disrupt operations. The basic workflow of prognostics begins with data acquisition, where sensors collect raw signals on system parameters like , , or load. This is followed by feature extraction to identify relevant indicators of from the data, reducing noise and dimensionality for analysis. A prognostic model—whether data-driven or physics-based—is then applied to process these features and generate outputs, such as a point estimate of RUL, a probability distribution, or confidence intervals, which guide health management decisions. This structured process ensures predictions are actionable and tied to verifiable degradation evidence.

Historical Development

The roots of prognostics trace back to post-World War II advancements in , where the demands of complex military electronics and systems necessitated systematic failure prediction and prevention to enhance operational dependability. This era saw the emergence of foundational concepts in statistical reliability analysis, laying the groundwork for prognostic techniques by emphasizing predictive assessments over reactive maintenance. Formalization of prognostics as a distinct occurred in the and , primarily through NASA's aerospace programs, which integrated health monitoring into launch vehicles and to predict failures and optimize mission reliability. NASA's Integrated Vehicle Health Management initiatives during this period expanded from basic diagnostics to prognostic capabilities, focusing on degradation modeling for critical components like engines and . In the 2000s, prognostics advanced significantly with the development of IEEE standards for Prognostics and Health (PHM), standardizing frameworks for data capture, fault progression analysis, and to support broader industrial applications. The 2010s marked rapid growth in , propelled by the proliferation of (IoT) sensors and analytics, which enabled scalable, prognostic systems across and sectors. Entering the , emphasis shifted toward integration for enhanced prognostics, as evidenced by reviews on system-level approaches and surveys on event-based methods that leverage for dynamic failure forecasting. From 2023 to 2025, developments have included the conceptualization of Prognostics and Health Large Models (PHM-LM), combining large-scale with PHM paradigms for improved predictive capabilities, alongside market expansion driven by advancements in , , and IoT integration. Key contributors include organizations such as , which pioneered aerospace PHM, and the IEEE PHM Society, established to foster global collaboration and standardization in the field. Influential research, like the 2016 that outlined core challenges in prognostic accuracy and , has shaped ongoing methodological refinements. The evolution of prognostics has been driven by a shift from physics-based model-driven methods to data-driven paradigms, facilitated by computational power and abundant sensor data that allow for empirical learning without exhaustive physical modeling. Additionally, Industry 4.0 technologies have accelerated adoption by embedding prognostics into ecosystems for proactive and reduced downtime.

Core Concepts

Remaining Useful Life Estimation

Remaining useful life (RUL) estimation is a core output in prognostics, representing the predicted time or number of operational cycles until a system or component reaches from its current . RUL is typically defined as the end of the useful life phase, where performance degradation crosses a predefined threshold, marking the point when the asset can no longer fulfill its intended function. This metric enables proactive in by quantifying future reliability horizons. The estimation process for RUL generally follows two broad approaches: direct and indirect methods. Direct methods extrapolate observed trends in sensor data or features straight to the threshold to compute RUL, bypassing intermediate modeling. In contrast, indirect methods first construct a model—often using indicators as inputs—then project its evolution to predict when occurs. A fundamental for RUL at time t is given by \text{RUL}(t) = T_{\text{failure}} - t_{\text{current}}, where T_{\text{failure}} is the predicted time of failure derived from the chosen estimation approach. Several factors influence RUL accuracy, including varying operating conditions (e.g., load and speed), usage profiles (e.g., mission cycles), and environmental stressors (e.g., temperature and vibration), which can accelerate or mitigate degradation rates. These elements necessitate adaptive models to account for real-world variability in prognostic predictions. RUL outputs can take multiple forms to convey prediction reliability: a scalar point estimate for simple applications, a capturing , or confidence bounds around the estimate. In more advanced representations, RUL may be expressed via a S(t) = P(\text{RUL} > t), which gives the probability that the asset survives beyond time t, or a hazard rate h(t), indicating the instantaneous risk conditional on survival up to t. These probabilistic forms, drawn from , enhance decision-making under in prognostics.

Health State Indicators

Health state indicators, also known as health indicators (HIs), are quantitative metrics that evaluate the current degradation level of a system or component by processing raw sensor data into interpretable representations of health status. These indicators transform measurements such as vibration amplitudes, temperature profiles, or wear accumulation into signals that reflect progressive deterioration, enabling early detection of faults in prognostics and health management applications. Commonly, HIs are normalized to a bounded scale of 0 to 1, with 1 denoting pristine health and 0 signifying failure, to facilitate consistent comparison across systems and integration into predictive models. Health state indicators are classified into distinct types based on their measurement basis and integration approach. directly quantify observable damage, such as crack propagation length in composite materials under loading. Functional health indicators capture relative to nominal , exemplified by the in of engines due to . Fused health indicators aggregate inputs from multiple sensors or modalities, such as combining and strain data, to yield a holistic that mitigates limitations of single-source metrics. Developing robust health state indicators requires systematic from sensor datasets, guided by established criteria to ensure reliability for degradation tracking. Key among these is monotonicity, which verifies that the indicator exhibits a consistent upward or downward trend as degradation advances, avoiding fluctuations that obscure fault progression. Trendability assesses the consistency of the indicator's degradation across multiple units or experimental runs, promoting generalizability in diverse operating conditions. These criteria, formalized in optimization frameworks using genetic algorithms, enable the identification of optimal features from high-dimensional data, prioritizing those with strong to end-of-life thresholds. In rotating machinery, the (RMS) of signals serves as a widely adopted state indicator for bearings, where escalating RMS values correlate with inner race defects and . This time-domain feature captures overall energy in the signal, providing a sensitive marker for early fault evolution. A standard for such indicators is given by: HI = 1 - \frac{\text{[degradation](/page/Degradation) feature}}{\max(\text{[degradation](/page/Degradation) feature})} This formulation scales the feature to the 0-1 range, aligning it with progression for use as input in remaining useful life .

Prognostic Approaches

Data-Driven Methods

Data-driven methods in prognostics leverage statistical and techniques to predict remaining useful life (RUL) by identifying patterns in historical and , particularly for systems where underlying physical models are unavailable or difficult to develop. These approaches treat prognostics as a problem, using from measurements, usage profiles, and failure histories to forecast degradation trends without relying on explicit mechanistic representations. They are especially valuable in domains like and , where variability in operating conditions makes physics-based modeling challenging. Key techniques encompass regression models for time-series forecasting, machine learning algorithms for nonlinear pattern recognition, and similarity-based methods for case matching. Regression approaches, such as autoregressive integrated moving average (ARIMA), model degradation signals as stationary time series to extrapolate future health states; for instance, ARIMA has been applied to predict RUL for milling machine cutting tools by analyzing wear progression data. Machine learning methods include neural networks, which learn complex input-output mappings through layered architectures, and random forests, ensemble models that aggregate decision trees to handle noisy, high-dimensional data for RUL estimation in bearings. Similarity-based techniques, like k-nearest neighbors (kNN), estimate RUL by comparing the current system's degradation trajectory to historical similar cases, weighting predictions based on proximity in feature space. The process typically begins with to clean and normalize sensor signals, followed by to extract meaningful indicators such as (RMS) values or kurtosis from time- and frequency-domain analyses. Model training then involves fitting algorithms to labeled datasets of past failures, optimizing parameters like weights or hyperparameters via techniques such as back-propagation or . In failure modeling, distributions like the Weibull are often employed to parameterize time-to-failure probabilities, with the given by f(t) = \frac{\beta}{\eta} \left( \frac{t}{\eta} \right)^{\beta - 1} \exp \left( - \left( \frac{t}{\eta} \right)^\beta \right), where \beta is the influencing behavior and \eta is the representing characteristic life; parameters are estimated from data to predict RUL under varying conditions. These methods offer adaptability to real-world data variability, capturing nonlinearities and interactions that simpler models miss, which enhances prediction accuracy in dynamic environments. However, they depend heavily on the quality and quantity of training data, potentially underperforming with sparse or biased datasets, and their black-box nature complicates interpretability, making it difficult to trace predictions to specific causal factors.

Physics-Based Methods

Physics-based methods in prognostics rely on mathematical models derived from the underlying physical laws governing processes, , and criteria to enable accurate predictions of remaining useful life (RUL) over extended horizons. These approaches model the fundamental mechanisms of material and behavior, such as , , and , using principles from and , which allows for predictions that are grounded in the physics of rather than empirical patterns alone. By simulating how evolves under operational stresses, these methods provide interpretable insights into health, particularly in domains like and rotating machinery where physical understanding is paramount. Key techniques encompass analytical models and simulation-based approaches. Analytical models, such as those from , describe damage progression through explicit equations; for instance, Paris' law quantifies crack growth as \frac{da}{dN} = C (\Delta K)^m where \frac{da}{dN} is the crack growth rate per cycle, \Delta K is the range, and C and m are material-specific parameters. This law, originally derived for metallic materials, has been widely applied in prognostics for components like gears and bearings to predict crack propagation from initial flaws to critical sizes. Simulation-based techniques, including finite element analysis (FEA), numerically solve complex partial differential equations to estimate stress distributions and damage accumulation, often integrating principles for detailed spatiotemporal predictions in structures under cyclic loading. The process begins with developing the physical model based on domain-specific knowledge, followed by parameter estimation using available sensor data to calibrate constants like those in Paris' law, often via optimization or filtering techniques such as Kalman or particle filters. Degradation is then simulated forward in time, propagating damage states until a predefined —such as a length exceeding a —is met, yielding the RUL estimate. This simulation accounts for environmental and loading variations, ensuring the model's fidelity to real-world physics while highlighting potential modes early. These methods offer advantages in interpretability, as the models directly link predictions to physical phenomena, facilitating root-cause analysis and design improvements, and in beyond available data regimes due to their mechanistic foundation. However, they require substantial expertise to formulate accurate representations and often simplify multifaceted real-world complexities, such as nonlinear interactions or unmodeled paths, which can limit applicability without extensive validation.

Hybrid Methods

Hybrid methods in prognostics integrate data-driven and physics-based approaches to capitalize on the interpretability and generalizability of physical models alongside the adaptability of data patterns, thereby enhancing overall prediction reliability. These fusion strategies address limitations such as the of purely empirical methods and the model inaccuracies of isolated physics simulations under varying conditions. By combining the two paradigms, techniques achieve improved accuracy, robustness to incomplete , and broader applicability across diverse systems like batteries and bearings. Pre-estimate fusion involves integrating and physical models prior to RUL , often by using observed to refine model parameters or generate synthetic sets. For instance, sensor can inform the tuning of degradation parameters in physics-of-failure models, enabling more accurate simulations when real failure is scarce. This approach is particularly useful in early-stage prognostics where historical datasets are limited, as it leverages physical laws to extrapolate beyond available observations. Post-estimate fusion, in contrast, merges the outputs from separate data-driven and physics-based prognostic models after individual RUL estimates are generated. A common technique here is the application of Kalman filtering to blend these estimates, where the filter recursively updates predictions based on measurement noise and model uncertainties from both sources. This method ensures that the final RUL incorporates complementary information, such as trend patterns from data-driven models and mechanistic insights from physics-based ones. Among techniques, Bayesian networks facilitate probabilistic by modeling dependencies between features, physical states, and probabilities, allowing for across components. These networks update beliefs iteratively as new arrives, making them suitable for prognostics in dynamic environments. A representative strategy employs weighted averaging of RUL estimates, where contributions from each method are scaled by their confidence levels derived from variance or validation errors. The RUL is computed as: \text{RUL}_{\text{hybrid}} = w_1 \cdot \text{RUL}_{\text{data}} + w_2 \cdot \text{RUL}_{\text{physics}} with w_1 + w_2 = 1 and weights adjusted based on method-specific reliability metrics. This simple yet effective approach has been demonstrated in electronic product prognostics, yielding more stable predictions than standalone methods. The primary benefits of hybrid methods include reduced in RUL estimates compared to pure approaches, as mitigates biases inherent in data scarcity or model assumptions. In PHM literature, such techniques have shown promise in applications like degradation, where post-fusion of empirical kernel models with exponential physics fits improved RUL prediction accuracy over individual methods in experimental datasets. Similarly, for rolling element bearings, hybrid fusions have enhanced robustness under variable loads, as evidenced in NASA prognostics benchmarks. These advancements underscore the role of hybrids in bridging theoretical models with operational data for more dependable health management.

Evaluation and Uncertainty

Performance Metrics

Performance metrics in prognostics evaluate the accuracy and reliability of predictions, particularly for remaining useful life (RUL) estimates and prediction horizons, enabling comparison of prognostic algorithms across diverse applications. These metrics quantify how closely predicted outcomes align with actual failure times, while accounting for the temporal aspects of degradation processes. Common evaluations distinguish between point estimates, which provide a single RUL value, and interval predictions, which offer bounds around the estimate. Such assessments are essential for validating prognostic models in fields like and , where precise supports decisions. A widely used metric for point estimates is the error (RMSE), which measures the average magnitude of errors in RUL predictions without considering their direction. It is calculated as: \text{RMSE} = \sqrt{\frac{\sum_{i=1}^{n} (RUL_{\text{pred},i} - RUL_{\text{actual},i})^2}{n}} where RUL_{\text{pred},i} is the predicted RUL, RUL_{\text{actual},i} is the actual RUL at the i-th , and n is the number of predictions. Lower RMSE values indicate better performance, with this metric emphasizing larger errors due to squaring. Relative error complements RMSE by normalizing errors relative to the actual RUL, providing a dimensionless measure suitable for systems with varying lifespans. It is defined as: \text{Relative Error} = \frac{|RUL_{\text{pred}} - RUL_{\text{actual}}|}{RUL_{\text{actual}}} This allows fair comparisons across units, where values closer to zero signify higher . For interval-based evaluations, the α-λ accuracy metric assesses whether predictions remain within a specified tolerance α (e.g., 20%) of the true RUL over a normalized time λ of the remaining life, capturing both and as progresses. It outputs a binary value of 1 if the condition |RUL_{\text{pred}}(\lambda) - RUL_{\text{actual}}(\lambda)| \leq \alpha \cdot RUL_{\text{actual}}(\lambda) holds at time λ, and 0 otherwise, with aggregation across λ values yielding overall performance. This metric is particularly useful for distinguishing early-stage predictions, which are often less reliable due to limited data, from late-stage ones near failure. The prognostic horizon () further quantifies the practical provided by a model, defined as the duration from the earliest point where predictions satisfy the α-λ criteria to the actual end-of-life (EoL). PH = EoL - t_{\text{start}}, where t_{\text{start}} is the time when accuracy first meets the , emphasizing the advance warning period critical for timely interventions. Standardization efforts, such as IEEE Std 1856-2017, outline categories for PHM metrics including accuracy, robustness, and computational , recommending their use to ensure consistent across prognostic systems while considering early versus late prediction challenges. These guidelines promote metrics that balance error minimization with operational foresight, as seen in benchmarks where PH often correlates with cost savings in real-world deployments. Recent reviews, such as a 2024 of 19 prognostics metrics, continue to refine these evaluations for emerging applications.

Uncertainty Quantification

In prognostics, uncertainty arises from two primary sources: aleatory uncertainty, which stems from inherent randomness and variability in physical processes such as material properties or environmental loads, and epistemic uncertainty, which results from a lack of knowledge, including inaccuracies in model parameters, incomplete sensor data, or unknown future operating conditions. For instance, aleatory uncertainty may manifest in the stochastic nature of crack propagation in fatigue-prone components due to microscopic material defects, while epistemic uncertainty often appears in the imprecise estimation of degradation rates from limited historical data. Distinguishing these sources is crucial, as aleatory uncertainty is irreducible and reflects true system variability, whereas epistemic uncertainty can be reduced through additional data or refined models. To model these uncertainties, probabilistic approaches are employed, providing a framework to represent and quantify variability in prognostic predictions. simulations, for example, generate numerous sample paths of system degradation by propagating random inputs through physics-based or data-driven models, yielding probability density functions for outcomes like time-to-failure. complements this by updating beliefs about model parameters with observed , enabling the construction of posterior distributions that capture epistemic in remaining useful life (RUL) estimates. These methods often produce confidence intervals for RUL predictions; for instance, a Bayesian approach might yield a 95% for a component's RUL based on sequential measurements, reflecting both data-driven updates and parameter variability. Uncertainty propagation techniques extend these models by forecasting how initial uncertainties evolve over time in nonlinear systems. The unscented (UKF), a sampling-based method, approximates state distributions using sigma points to propagate and covariance through degradation dynamics, particularly effective for handling varying loads in crack growth prognostics. For analytical propagation, via the first-order second moment (FOSM) method estimates RUL variance by linearizing the prediction function around nominal inputs, assuming uncorrelated uncertainties: \text{Var}(RUL) = \sum_{i=1}^{n} \left( \frac{\partial RUL}{\partial x_i} \right)^2_{\mu_x} \text{Var}(x_i) where x_i are input variables (e.g., initial damage state or loading profiles), and the partial derivatives represent sensitivities evaluated at the mean \mu_x. This approach is computationally efficient for or , providing bounds on RUL distributions without exhaustive simulations. Effective underpins risk-based in prognostics and health management (PHM), allowing engineers to assess probabilities and associated costs for maintenance scheduling or safety-critical operations. By integrating quantified uncertainties into PHM frameworks, such as those discussed by the Prognostics and Health Management Society, systems can prioritize interventions based on credible risk intervals rather than point estimates alone.

Applications and Implementations

System-Level Prognostics

System-level prognostics extends component-level remaining useful (RUL) to entire systems by accounting for interactions among components, fault , and overall system performance degradation. Unlike isolated component analyses, this approach integrates multiple degradation processes to predict system RUL, enabling proactive and improved operational reliability. Key approaches include bottom-up methods, which aggregate individual component prognostics—such as using to combine RUL estimates from subsystems like gearboxes or hydraulic systems—top-down methods that model the system holistically through health indices derived from overall performance metrics, and hierarchical fusion techniques that blend multi-level data for comprehensive predictions. These methods are categorized into model-based (e.g., physics-informed simulations like particle filters), data-driven (e.g., neural networks trained on sensor data), and hybrid approaches that leverage both for robustness in uncertain environments. Challenges in system-level prognostics arise primarily from interdependencies, where degradation in one component accelerates failures in others, and cascading failures that propagate across the system, complicating accurate RUL forecasting. For instance, a bearing fault may exacerbate gear wear, requiring models that capture dynamic interactions to avoid underestimating system risks. Applications are prominent in aircraft systems, such as turbofan engines using the C-MAPSS dataset for integrated health monitoring, and wind farms, where system-level models assess turbine arrays to optimize energy output. Relevant metrics include system availability, which quantifies operational uptime and is enhanced through prognostics by enabling timely interventions to minimize downtime.

Commercial Platforms and Tools

Commercial platforms and tools for prognostics and health (PHM) encompass a range of and software solutions that facilitate the deployment of PHM in settings, enabling the collection, analysis, and prediction of system health from sensor data to advanced . These tools support condition-based by integrating with predictive algorithms, reducing and optimizing asset lifecycle across sectors like and . Hardware components form the foundational layer of PHM systems, primarily through sensor networks that capture environmental, operational, and data. Common examples include accelerometers for in rotating machinery and thermocouples for temperature assessment in thermal systems, which provide critical inputs for detection. systems, such as devices, process this locally to enable PHM decisions, minimizing latency in harsh environments like engines or floors. For instance, 's PHM implementations utilize distributed networks with processors to monitor electrical power systems, demonstrating robust fault detection in applications. Software platforms bridge raw with prognostic models, offering tools for algorithm development, simulation, and deployment. ' within and allows users to design condition indicators, estimate remaining useful life (RUL), and deploy PHM algorithms on embedded hardware, supporting -driven prognostics for industrial assets. ' Simcenter portfolio, including the Maintenance Aware Design Ecosystem (MADE) and Senseye platform, integrates for health prediction, achieving up to 85% improvement in downtime forecasting accuracy in manufacturing equipment. Similarly, GE Vernova's APM Health software provides and prognostic analytics for asset performance, incorporating for real-time risk prediction in and systems. Open-source alternatives, such as the PHMD library, enable accessible handling and PHM dataset analysis for research and custom implementations. Case studies illustrate practical adoption of these tools. In , NASA's Integrated Systems Health Management employs sensor-embedded PHM for , achieving high-accuracy fault and supporting mission-critical reliability. In , IoT-integrated PHM platforms like Advantech's WISE-IoT suite with have been deployed for equipment health monitoring, reducing unplanned downtime by enabling proactive maintenance in magnetic core . These implementations highlight seamless fusion with PHM software for scalable, prognostics.

Challenges and Future Directions

Key Challenges

One of the primary technical challenges in prognostics is the poor quality of input , including , incompleteness, and heterogeneity from faults or inconsistent formats, which undermines the reliability of models for remaining useful life (RUL) . Imbalanced datasets, often skewed toward healthy states with scarce fault examples, exacerbate this issue, leading to biased predictions and in data-driven approaches. Additionally, handling event-based —such as discrete failure logs or maintenance records—presents difficulties due to temporal dependencies, rare event detection, and limited labeled datasets, complicating pattern extraction for prognostics. Model remains a hurdle, as complex algorithms like require substantial computational resources to process large-scale, multi-source without sacrificing accuracy. computation further strains systems, particularly for physics-informed models that demand intensive processing to adapt to dynamic conditions, often exceeding the capabilities of devices. Practical implementation faces obstacles in integrating prognostics systems with legacy , where outdated and software create issues, dynamic reconfiguration challenges, and difficulties in fusing PHM outputs with existing tools. The lack of , evident in varying definitions of RUL across applications and inconsistent data protocols like formats, hinders interoperability and benchmark comparisons between models. For small and medium-sized enterprises (SMEs), cost-benefit concerns are pronounced, as high upfront investments in sensors, software, and expertise often outweigh short-term gains, limiting adoption despite potential long-term maintenance savings. Domain-specific challenges arise in harsh operational environments, such as offshore wind energy systems, where corrosive saltwater, , and variable loads accelerate degradation and introduce high variability in data, making accurate RUL predictions elusive without adaptive models. Ethically, over-reliance on prognostic predictions can lead to safety risks, including misinterpreted alerts that prompt incorrect operator actions or autonomous decisions based on biased datasets, potentially endangering human lives in critical sectors like or . emerges as a core challenge, amplifying these risks by complicating confidence assessments in predictions under incomplete or noisy conditions.

Emerging Trends

The integration of (AI) and (ML) into prognostics is advancing rapidly, particularly through techniques for anomaly prognostics. models, such as convolutional neural networks and recurrent neural networks, enable the detection of subtle degradation patterns in complex systems by processing high-dimensional sensor data in . For instance, these models have been applied to predict anomalies in cryogenic safety valves, achieving improved accuracy in remaining useful life (RUL) estimation compared to traditional methods. Additionally, the emergence of PHM Large Models—large-scale AI frameworks tailored for prognostics—combines vast datasets with advanced architectures to enhance predictive capabilities across industrial applications. A key trend within AI integration is the adoption of explainable AI (XAI) to build trust in prognostic decisions, addressing the "black box" limitations of deep learning. XAI techniques, including feature importance analysis and counterfactual explanations, allow engineers to interpret model outputs, such as why a specific fault prognosis was issued for rotating machinery. Systematic reviews highlight that XAI improves reliability in safety-critical PHM systems by quantifying uncertainty and aligning predictions with domain knowledge. This shift toward interpretable models is essential for and validation in sectors like and . Digital twins, as virtual replicas of physical assets, are transforming simulation-based prognostics by enabling scenario testing for . These models synchronize sensor data with physics-based simulations to forecast degradation under varying conditions, reducing downtime in systems through integrated vehicle health management (IVHM). Reviews of digital twin implementations emphasize their role in bridging diagnostics, RUL prediction, and maintenance scheduling, particularly for assets with nonlinear behaviors. The fusion of edge and cloud computing is enabling distributed prognostics and health management (PHM) for IoT-enabled systems, allowing localized processing at the edge while leveraging cloud resources for complex analytics. Edge devices handle real-time anomaly detection with low latency, essential for remote IoT networks in wind turbines or smart grids, while cloud platforms aggregate data for global model updates. This hybrid architecture supports scalable PHM in cyber-physical systems, enhancing responsiveness through ML deployments. Recent advancements include event-based methods, which process discrete events like fault triggers rather than continuous streams, as outlined in 2025 PHM Society proceedings; these techniques focus on critical state changes for efficient prognostics. Prognostics is increasingly oriented toward , particularly in green energy applications like (EV) batteries and renewable systems, where accurate health management extends asset life and minimizes waste. AI-driven PHM for lithium-ion batteries in EVs predicts capacity fade using analytics, supporting second-life repurposing and reducing environmental impact from mining raw materials. For renewables, such as inverters, prognostic models forecast RUL to optimize energy yield and lower operational costs in off-grid setups. Interdisciplinary links to are emerging, adapting PHM frameworks for human health monitoring—e.g., wearable devices that prognose physiological degradation akin to mechanical wear—fostering hybrid approaches in and sustainable healthcare systems.

References

  1. [1]
    [PDF] Prognostics - C3
    Prognosis is here strictly defined as “predicting the time at which a component will no longer perform its intended function.” Loss of function is oftentimes ...
  2. [2]
    Prognostics & Health Management (PHM) | www.dau.edu
    Definition. Prognostics and health management (PHM) is an advanced approach to minimize maintenance costs while maximizing operational availability and ...
  3. [3]
    Prognostics and Health Management (PHM) - MATLAB & Simulink
    Prognostics refers to an approach to designing algorithms to estimate the remaining useful life of systems or components. The term is often used interchangeably ...Prognostics vs. Diagnostics · Health Management · Prognostics Algorithm...
  4. [4]
    [PDF] Prognostics | PHM Society
    How is prognostics used? – Reliability. – Scheduled maintenance – based on reliability. – Kinds of prognostics – interpretation & applications. • ...
  5. [5]
    Prognostics: a literature review | Complex & Intelligent Systems
    Jun 30, 2016 · In engineering, prognostics can be defined as the process of RULs estimation of system/subsystem/component that is degrading due to either ...
  6. [6]
    [PDF] Standards Related to Prognostics and Health Management (PHM ...
    Jul 7, 2014 · Prognostics and health management (PHM) technologies reduce burdensome maintenance tasks of products or processes through diagnostic and ...<|separator|>
  7. [7]
    [PDF] IEEE Standards for Prognostics and Health Management
    PHM has been defined as “a maintenance and asset management approach utilizing signals, measurements, models, and algorithms to detect, assess, and track ...
  8. [8]
    [PDF] Prognostics and Secure Health Management of Electronic Systems ...
    ABSTRACT. Prognostics and health management (PHM) is a multifaceted discipline for the assessment of product degradation and reliability.
  9. [9]
    [PDF] A Short History of Reliability - NASA
    Apr 28, 2010 · By the 1940s, reliability and reliability engineering still did not exist. The demands of WWII introduced many new electronics products into the ...
  10. [10]
    Highlights from the early (and pre-) history of reliability engineering
    In this short communication, we highlight key events and the history of ideas that led to the birth of Reliability Engineering, and its development in the ...
  11. [11]
    [PDF] INTEGRATED VEHIC_HEALTH MANAGEMENT (IVHM)
    Oct 10, 1992 · In the early 1980s, interest in expanding launch vehicle health management capabilities and making launch operations more efficient led to.
  12. [12]
    [PDF] A Survey of Health Management User Objectives Related to ...
    The origins of Integrated Vehicle Health Management are complex and entwined in aerospace developments by the National Aeronautics and Space Administration. ( ...
  13. [13]
    A Survey of Predictive Maintenance: Systems, Purposes and ... - arXiv
    Mar 22, 2024 · This paper highlights the importance of maintenance techniques in the coming industrial revolution, reviews the evolution of maintenance techniques,
  14. [14]
    Challenges and Opportunities of System-Level Prognostics - MDPI
    Nov 18, 2021 · Prognostics and health management (PHM) has become an essential function for safe system operation and scheduling economic maintenance.4. Datasets For System-Level... · 4.2. Phm Data Challenge 2018 · 5.1. Systematization Issues...
  15. [15]
    Event-Based Data in Prognostics and Health Management
    Oct 26, 2025 · This review paper systematically surveys the state-of-the-art methodologies and frameworks for extracting, modeling, and utilizing event-based ...
  16. [16]
    About the Prognostics and Health Management Society
    The Prognostics and Health Management Society (PHM Society) is a non-profit organization dedicated to the advancement of PHM as an engineering discipline.Missing: IEEE history
  17. [17]
    Prognostics and Health Management: A Review on Data Driven ...
    May 19, 2015 · Our paper describes the entire process of data-driven approach related to PHM, addresses the three PHM objectives (fault diagnostics, ...2.3. 2. Markovian... · 2.3. 4. Regression Based... · 3. Illustrative Case Studies
  18. [18]
    Prognostics and Health Management of Industrial Assets: Current ...
    Prognostic and Health Management (PHM) systems are some of the main protagonists of the Industry 4.0 revolution. Efficiently detecting whether an industrial ...
  19. [19]
    Remaining useful life estimation – A review on the statistical data ...
    Aug 16, 2011 · Remaining useful life (RUL) is the useful life left on an asset at a particular time of operation. Its estimation is central to condition ...
  20. [20]
    Remaining Useful Life Prediction through Failure Probability ...
    Oct 18, 2015 · The remaining useful life of an engineering component/system is defined as the first future time-instant in which a set of safety threshold ...Missing: seminal | Show results with:seminal
  21. [21]
    Remaining Useful Life Estimation in Prognosis: An Uncertainty ...
    Aug 19, 2013 · This paper proposes that the task of estimating the remaining useful life must be approached as an uncertainty propagation problem.Missing: definition seminal
  22. [22]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC7861342/
  23. [23]
    Remaining Useful Life (RUL) Prediction of Equipment in Production ...
    Jan 30, 2021 · 4. Methodology. Instead of direct measurements of RUL, usually, indirect measures are adopted. For this reason, the concept of the health index ...
  24. [24]
    [PDF] Standardizing Research Methods for Prognostics - C3
    RUL is expressed using units corresponding to the primary measurement of use of the overall system. For example, the primary measurement that correlates ...
  25. [25]
    [PDF] RUL Prognostics: Recursive Bayesian Ensemble Prediction with ...
    Prognostics is used to predict the remaining useful lifecycle (RUL) by assessing the degradation of equipment and deviation of their operating conditions from.
  26. [26]
    https://ieeexplore.ieee.org/document/7726039
  27. [27]
    Prognostics uncertainty reduction by right-time prediction of ...
    Mar 31, 2021 · Prognostics uncertainty reduction by right-time prediction of remaining useful life based on hidden Markov model and proportional hazard model. ...
  28. [28]
    Machine Health Indicators and Digital Twins - PMC - PubMed Central
    Apr 2, 2025 · Health indicators (HIs) are quantitative indices that assess the condition of engineering systems by linking sensor data with monitoring, ...
  29. [29]
    A generic probabilistic framework for structural health prognostics ...
    To overcome the shortcoming of the PHI, we propose the synthesized health index (SHI), which is a normalized health index bounded in [0,1] through appropriate ...
  30. [30]
    A Health Index Construction Framework for Prognostics Based on ...
    When the health indicator is scaled between 0 (healthy) and 1 (failure), the health indicators should converge to similar values at key degradation stages, ...
  31. [31]
    Intelligent health indicator construction for prognostics of composite ...
    Background on health indicators. In order to visualize data and continuously characterize the health state of the structure over its entire life, HIs can be ...
  32. [32]
    [PDF] Health indicators for diagnostics and prognostics of composite ...
    Prognostics and health indicators. Two major categories can be identified in the implementa- tion of prognostics. First, there are model based or physical.
  33. [33]
    [PDF] Identifying Optimal Prognostic Parameters from Data - PHM Society
    An ideal prognostic parameter has three key qualities: monotonicity, prognosability, and trendability (Coble and Hines, 2009). Monotonicity characterizes the ...
  34. [34]
    [PDF] Identifying Optimal Prognostic Parameters from Data : A ...
    These metrics include monotonicity, prognosability, and trendability are used in conjunction with a Genetic Algorithms optimization routine to identify an ...
  35. [35]
    Identifying optimal prognostic parameters from data - ResearchGate
    In literature, a collection of metrics called Monotonicity (Mo), Prognosability (Pr), and Trendability (Tr) (Coble and Hines, 2009 ) have been suggested to ...
  36. [36]
    A Reliable Health Indicator for Fault Prognosis of Bearings - PMC
    Nov 2, 2018 · Therefore, this paper presents a method for constructing a bearing's HI by considering the non-stationarity of the vibration acceleration ...
  37. [37]
    (PDF) RMS Based Health Indicators for Remaining Useful Lifetime ...
    Mar 31, 2022 · Bearing prognosis plays an active role in preventing excessive or inadequate maintenance for major equipment. This paper develops a hybrid ...
  38. [38]
    New Health Indicator Construction and Fault Detection Network for ...
    May 23, 2024 · The root mean square (RMS) of the original vibration signal is a classic bearing health indicator, which is directly used to represent the ...
  39. [39]
    [PDF] A review of data-driven and physics- based prognostics - PHM Society
    The goal of this paper is to provide a practical review of prognostics methods so that beginners in prognostics can select appropriate methods for their field ...
  40. [40]
    Data-driven prognostics of remaining useful life for milling machine ...
    In this study, the RUL of milling machine cutting tools is predicted through the methodology of autoregressive integrated moving average (ARIMA).<|separator|>
  41. [41]
    Optimized Random Forest Model for Remaining Useful Life ...
    Sep 13, 2022 · This article proposes a new data-driven prediction framework for bearing RUL utilizing an integration of empirical mode decomposition, random forest (RF), and ...
  42. [42]
    A similarity-based prognostics approach for Remaining Useful Life ...
    Wang et al. [9] applied similarity-based prognostics using k-nearest neighbors to estimate bearing RUL, achieving robust predictions through case-based ...
  43. [43]
    [PDF] A data-driven failure prognostics method based on mixture of ... - HAL
    Oct 2, 2012 · In their model, the reliability of the bearing was first initialized to a Weibull distribution, and then progressively updated as the monitoring ...
  44. [44]
    https://ieeexplore.ieee.org/document/8819400/
  45. [45]
    https://ieeexplore.ieee.org/document/9889166/
  46. [46]
    [PDF] Techniques of Prognostics for Condition-Based Maintenance in ...
    Sep 29, 2016 · Hybrid approaches can be classified into two types, pre- estimate and post-estimate fusion. Pre-estimate fusion is usually applied when ...
  47. [47]
    Fusing physics-based and deep learning models for prognostics
    We propose a novel hybrid framework for fusing the information from physics-based performance models with deep learning algorithms for prognostics of complex ...
  48. [48]
    A Bayesian-entropy Network for Information Fusion and Reliability ...
    Sep 24, 2018 · This paper introduces a hybrid network model called the Bayesian-Entropy Network (BEN) that can handle various types of information. The BEN ...
  49. [49]
    A Fusion Prognostics Method for Remaining Useful Life Prediction of ...
    This method integrates the advantage and overcome the limitations of the data-driven methods and the physics of failure methods to provide better predictions.<|control11|><|separator|>
  50. [50]
    [PDF] Probabilistic forecasting informed failure prognostics framework for ...
    Jun 17, 2022 · focused on the development of hybrid prognostics models, that combine ... and an ensemble strategy is used to perform a weighted average of age-.<|control11|><|separator|>
  51. [51]
    A Hybrid Prognostic Approach for Remaining Useful Life Prediction ...
    This study proposes a hybrid prognostic approach that can predict the RUL of degraded lithium-ion batteries using physical laws and data-driven modeling ...
  52. [52]
    [PDF] Metrics for Offline Evaluation of Prognostic Performance
    In the systems health management context, prognostics can be defined as predicting the Remaining Useful Life (RUL) of a system from the inception of a fault ...
  53. [53]
    [PDF] Prognostic Performance Metrics - C3
    Jul 12, 2011 · A survey of health management user objectives related to diagnostic and prognostic metrics. ... Predictions Based on IEEE 1413™ 1413.1TM (pp.
  54. [54]
    IEEE 1856-2017 - IEEE SA
    Dec 13, 2017 · Information for the implementation of prognostics and health management (PHM) for electronic systems is described in this standard.Missing: metrics | Show results with:metrics
  55. [55]
    [PDF] An Uncertainty Quantification Framework for Prognostics and ...
    It has been conventional to classify the different sources of uncertainty into aleatory (physical variability) and epistemic (lack of knowledge), where ...
  56. [56]
    [PDF] A fast Monte Carlo method for model-based prognostics based on ...
    This work proposes a fast Monte Carlo method to solve differential equations utilized in model-based prognostics. The methodology is derived from the theory ...
  57. [57]
    [PDF] Uncertainty in Prognostics and Systems Health Management
    While it has been customary to classify the different sources of uncertainty into aleatory (arising due to physical variability) and epistemic. (arising due ...
  58. [58]
    [PDF] Unscented Kalman Filtering for Prognostics Under Varying ...
    In this paper, it is proposed to utilize an unscented Kalman filter (UKF). It is applied to an artificial crack growth problem with varying loading profiles, ...
  59. [59]
    [PDF] Analytical Algorithms to Quantify the Uncertainty in Remaining ...
    Abstract—This paper investigates the use of analytical algo- rithms to quantify the uncertainty in the remaining useful life.
  60. [60]
    Special Issue: Uncertainty in PHM
    The goals of this special issue are to create an open forum for discussing new methods and approaches for uncertainty quantification in PHM, and enhance the ...Missing: 2020s | Show results with:2020s
  61. [61]
    https://www.sciencedirect.com/science/article/pii/S0263224124009230
  62. [62]
    https://ntrs.nasa.gov/api/citations/20140012546/downloads/20140012546.pdf
  63. [63]
    [PDF] A DISTRIBUTED PROGNOSTIC HEALTH MANAGEMENT ...
    The health management paradigm envisaged here incorporates a heterogeneous set of system components monitored by a varied suite of sensors and a particle ...
  64. [64]
    Sensor Systems for Prognostics and Health Management - PMC
    Sensor systems are needed for PHM to monitor environmental, operational, and performance-related characteristics.
  65. [65]
    Predictive Maintenance Toolbox - MATLAB - MathWorks
    The toolbox lets you design condition indicators, detect faults and anomalies, and estimate remaining useful life (RUL). With the Diagnostic Feature Designer ...
  66. [66]
    Maintenance Aware Design Ecosystem (MADE) - Siemens PLM
    Maintenance Aware Design Ecosystem (MADE) offers PHM Technology for model-based reliability, availability, maintainability, and safety (RAMS) analysis.
  67. [67]
    How Senseye Cloud Application works - Siemens
    Designed to integrate seamlessly and provide maximum value, the platform achieves 85% improvement in downtime forecasting accuracy through machine health ...
  68. [68]
    Asset Condition Monitoring – Condition-based Maintenance
    APM Health is a condition monitoring software providing a real-time view of plant operations, helping predict potential asset failure and risk.
  69. [69]
    PHMD: An easy data access tool for prognosis and health ...
    This work introduces a comprehensive open-source Python library designed for seamless access and handling of Prognostics and Health Management (PHM) datasets.
  70. [70]
    [PDF] Integrated Systems Health Management for Intelligent Systems
    The current templates cover accelerometers, strain gages, current loop sensors, microphones, thermocouples, and others. Page 5. Chapter for the AIAA book ...
  71. [71]
    Empowering Manufacturers with Smart, Scalable Pr - Advantech
    Feb 25, 2025 · By leveraging IoT, machine learning, and predictive analytics, Advantech's IoTSuite-powered solutions transformed TCT's operations. The system ...
  72. [72]
    Integrating machine learning and IoT for real-time predictive ...
    This study explores the application of AI in PdM across various manufacturing sectors, highlighting the transition from traditional methods to smart solutions.
  73. [73]
    On the Data Quality and Imbalance in Machine Learning-based ...
    The aim of this survey is to uncover the data challenges in this domain and review the techniques used to resolve them.
  74. [74]
    [PDF] Event-Based Data in Prognostics and Health Management
    This paper presents a comprehensive systematic review of event-based PHM methods, aiming to (i)-highlight the evolution of diagnostic and prognostic approaches ...
  75. [75]
    Prognostics and Health Management Based on Next-Generation ...
    Jul 14, 2024 · This paper summarizes the development of PHM in the field of engineering, from the initial PHM used in aerospace to the current PHM systems ...Prognostics And Health... · 2. Materials And Methods · 5. Application Of Ar To Phm
  76. [76]
    A review of prognostics and health management techniques in wind ...
    This review aims to provide a holistic understanding of prognostics and health management (PHM) techniques in wind energy.
  77. [77]
    Special Issue: PHM for Smart Manufacturing Systems
    PHM applications within manufacturing (e.g. machine tools, robotics); Human performance and reliability issues; Integration of PHM elements into new and legacy ...
  78. [78]
    Special Issue: Standards for Prognostics and Health Management
    This special issue is focused on the development, implementation, and evolution of standards, guidelines, and best practices relevant to condition monitoring, ...
  79. [79]
    Systematic review of predictive maintenance practices in the ...
    Small and medium-sized enterprises (SMEs) face additional challenges related to the high costs of proprietary solutions (Kiangala & Wang, 2020). Developing a ...
  80. [80]
    Industrial data management strategy towards an SME-oriented PHM
    Aug 7, 2025 · However, an adapted approach for data-driven PHM process implementation in small and medium-sized enterprises (SMEs) has not been yet discussed.
  81. [81]
    (PDF) Ethics in Prognostics and Health Management - ResearchGate
    Aug 6, 2025 · This article explores the topic of ethics within the PHM domain: how it is relevant, and how it may be addressed in a conscientious way. The ...Missing: reliance | Show results with:reliance
  82. [82]
    A benchmark on uncertainty quantification for deep learning ...
    We assess some of the latest developments in the field of uncertainty quantification for deep learning prognostics.
  83. [83]
    Deep Learning-Based Prognostics and Health Management Model ...
    Mar 12, 2024 · This research proposes a deep learning-based PHM model for pilot-operated cryogenic safety valves, contributing to safe operation and anomaly ...
  84. [84]
    An outline of Prognostics and health management Large Model
    Jun 1, 2025 · We propose a novel concept and corresponding three typical paradigms of PHM Large Model (PHM-LM) by the combination of the Large Model with PHM.
  85. [85]
    (PDF) Explainable AI (XAI) for PHM of Industrial Asset - ResearchGate
    A state-of-the-art systematic review on XAI applied to Prognostic and Health Management (PHM) of industrial asset is presented.
  86. [86]
    On the Soundness of XAI in Prognostics and Health Management ...
    This paper presents a critical and comparative revision on a number of explainable AI (XAI) methods applied on time series regression models for PM.<|separator|>
  87. [87]
    Digital Twin-based IVHM for Predictive Maintenance - PHM Society
    Oct 26, 2025 · This paper proposes a Digital Twin-based Integrated Vehicle Health Management (IVHM) approach to enable predictive maintenance in aviation ...
  88. [88]
    Digital Twins in Prognostics and Health Management: A Review of ...
    Nowadays, the digital representation of physical machines and their operations has become a popular practice for predictive maintenance. Thus, Digital Twins can ...
  89. [89]
    Machine Learning in Prognostics and Health Management of Cyber ...
    Sep 22, 2025 · To address these challenges, Prognostics and Health Management (PHM) frameworks use modern sensor technologies and machine learning (ML) to ...
  90. [90]
    Battery Prognostics and Health Management: AI and Big Data - MDPI
    The integration of battery PHM, in particular, raises significant concerns related to data privacy and security. These systems, which rely on continuous data ...Missing: reliance | Show results with:reliance<|control11|><|separator|>
  91. [91]
    Special Issue: PHM for Human Health & Performance
    PHM tools developed for monitoring, diagnostic, and/or prognostic techniques in human health and performance; Strategies to increase PHM involvement by ...Missing: interdisciplinary | Show results with:interdisciplinary<|separator|>