Fact-checked by Grok 2 weeks ago

Advanced process control

Advanced process control (APC) is a suite of sophisticated strategies designed to optimize and manage complex industrial processes by addressing multivariable interactions, operational constraints, and dynamic disturbances in , extending beyond basic single-loop regulatory controls such as proportional-integral-derivative () controllers. At its core, APC employs techniques like (MPC), which utilizes explicit process models to forecast future system behavior, solve optimization problems over a finite , and compute actions that minimize deviations from setpoints while respecting constraints on inputs, outputs, and states. This approach enables precise handling of coupled variables in large-scale systems, making APC essential for achieving superior performance in industries where traditional methods fall short due to process complexity. The development of APC traces back to the mid-20th century, with early computer-based control systems appearing in refineries during the 1950s, but it gained momentum in the 1970s through the introduction of MPC algorithms tailored for chemical and processes. By the , MPC had become the dominant APC technology, with over 2,000 industrial installations worldwide, primarily in oil refining and polymer production, demonstrating its practical viability through improved stability and economic returns. As of 2023, the global APC market was valued at USD 2.17 billion, reflecting continued expansion and thousands more installations. In recent years, advancements have integrated APC with (AI) and (ML), enabling adaptive modeling, fault detection, and real-time optimization to further enhance robustness and predictive capabilities in dynamic environments. APC finds broad applications across sectors including chemical manufacturing, semiconductors, pharmaceuticals, and energy production, where it supports continuous processing, quality assurance, and resource efficiency. For instance, in pharmaceutical production, APC facilitates dynamic adjustment of critical process parameters to maintain product quality attributes and enable real-time release testing, reducing reliance on end-product testing. Key benefits encompass reduced process variability, which can yield 3-5% energy savings in units like olefin crackers, increased plant throughput by up to 5%, and minimized waste through constraint management and disturbance rejection. Overall, these capabilities not only boost operational profitability but also align with sustainability goals by optimizing energy and material use in intensive processes.

Overview and Fundamentals

Definition and Scope

Advanced process control () encompasses a suite of computer-based techniques that leverage process models to predict future behavior and optimize control actions in industrial settings, extending beyond the capabilities of traditional proportional-integral-derivative () controllers. These methods integrate dynamic modeling to handle complex interactions among multiple variables, enabling proactive adjustments rather than reactive alone. Unlike basic process control, which relies primarily on single-loop mechanisms to maintain setpoints, APC incorporates optimization algorithms and predictive simulations to achieve superior performance in multivariable environments. The primary objectives of APC include maximizing throughput by pushing processes to optimal operating limits, minimizing through precise , ensuring consistent product quality by reducing variability, and managing interactions across interconnected process variables to avoid constraints. For instance, serves as a core example within APC, outcomes to balance these goals in . APC's scope is primarily confined to continuous processes in industries such as , , and chemicals, where fluid flows and reactions demand ongoing regulation, while it generally excludes involving assembly-line production of individual items. Key benefits, drawn from industry benchmarks since the , include improvements of 2-5% and reductions of 3-15%, contributing to enhanced profitability and without major hardware changes.

Historical Development

The origins of advanced process control (APC) trace back to early computer-based control systems in refineries during the 1950s, with significant momentum gained in the 1970s when the global oil crisis of 1973 prompted refineries to prioritize energy optimization and operational efficiency amid volatile crude prices and supply disruptions. This economic pressure accelerated the shift from basic loops to multivariable strategies, laying the groundwork for (MPC) techniques that could handle complex, constrained processes in facilities. In the late and , pioneering multivariable predictive control methods emerged to address these challenges. A seminal development was Dynamic Matrix Control (DMC), introduced in 1979 by C. R. Cutler and B. L. Ramaker at Oil's Cuthern Laboratories, which utilized dynamic models to predict and optimize process responses while respecting operational constraints. This innovation marked a technological shift toward explicit handling of multivariable interactions, initially applied in operations to improve and reduce energy use. The 1990s saw the commercialization and widespread adoption of , driven by vendors such as AspenTech and , who acquired key technologies like and integrated them into robust software platforms. These tools facilitated deployment across industries, with hundreds of applications in refineries enhancing throughput and stability. During the 2000s, APC expanded beyond petrochemicals into sectors like power generation and pharmaceuticals, supported by standardized software that simplified implementation and model maintenance. Vendors such as AspenTech, , and enabled nonlinear extensions and broader industrial integrations, improving process reliability in diverse applications. Post-2010 advancements integrated APC with () and , enhancing scalability by enabling real-time data sharing and remote optimization across distributed systems. This evolution aligned with Industry 4.0 principles introduced in 2011, which emphasized cyber-physical systems and data-driven decision-making to elevate APC from local to enterprise-wide control.

Core Techniques and Strategies

Model Predictive Control

Model predictive control (MPC) utilizes explicit dynamic models of the process to forecast future system behavior over a prediction horizon and optimizes the sequence of control moves to achieve desired performance objectives. This predictive capability enables proactive adjustments to manipulated variables, distinguishing MPC from traditional feedback controllers by incorporating future constraints and setpoints directly into the decision-making process. Originating in the process industries in the late 1970s, MPC has become a standard for multivariable control in applications requiring constraint handling and optimization. The core components of MPC include a process model, often formulated in state-space form x_{k+1} = A x_k + B u_k or as transfer functions for input-output representations, and an objective function that balances tracking accuracy with control effort. The at each time step solves for the optimal input sequence by minimizing a cost, subject to linear or nonlinear constraints on states, inputs, and their rates. This formulation ensures economic and safe operation by penalizing deviations from references and excessive manipulations. A standard representation of the optimization problem in output form is: \min J = \sum_{k=1}^{P} (y_k - r_k)^T Q (y_k - r_k) + \sum_{k=0}^{M-1} \Delta u_{k}^T R \Delta u_{k} subject to model predictions y_k = y_{k|k-1} + \sum_{i=1}^{k} G_i \Delta u_{k-i}, input constraints u_{\min} \leq u_k \leq u_{\max}, output constraints y_{\min} \leq y_k \leq y_{\max}, and rate limits \Delta u_{\min} \leq \Delta u_k \leq \Delta u_{\max}, where y_k denotes predicted outputs, r_k are reference trajectories, \Delta u_k = u_k - u_{k-1} are input changes, Q \geq 0 and R > 0 are weighting matrices, P is the prediction horizon, and M \leq P is the control horizon. Only the first optimized move is implemented, with the problem resolved at the next step using updated measurements. Implementation of MPC proceeds through key steps: model identification via methods or prediction error minimization to obtain a reliable linear or nonlinear model from input-output data; controller tuning by selecting horizons P and M, and weights Q and R to achieve desired closed-loop response, often guided by ; and constraint handling through solvers that incorporate hard limits on actuators and soft limits on outputs to prevent violations while maintaining feasibility. These steps ensure robustness to model mismatch and disturbances. MPC variants address different process characteristics: linear MPC applies to systems near operating points with small perturbations, using linear models and for computational efficiency; nonlinear MPC extends this to processes with strong nonlinearities, such as chemical reactors, by employing nonlinear models and solving nonconvex optimizations, often with stability guarantees via terminal constraints. A representative involves MPC application in columns for temperature setpoint optimization, where multivariable interactions between feed rates, reflux ratios, and steam inputs are managed. In a unit, implementation resulted in increased throughput, reduced energy usage, and lower product variability by dynamically adjusting to constraints like heater limits and column flooding, achieving a typical of less than six months.

Statistical and Adaptive Control Methods

Statistical process control (SPC) and adaptive control methods complement advanced process control (APC) by emphasizing data-driven approaches to manage uncertainty and variability in industrial processes, focusing on monitoring stability and dynamically adjusting control parameters without relying on explicit forward-looking models. These techniques complement other APC strategies by prioritizing real-time detection of deviations and responsive tuning based on observed process behavior, particularly useful in environments with time-varying dynamics or limited prior modeling information. Unlike predictive methods that simulate future states, statistical and adaptive controls leverage historical data patterns to maintain process performance and quality. Statistical Process Control (SPC) employs to monitor process stability and identify anomalies by establishing statistical limits derived from process data. The foundational Shewhart control chart, developed in the , plots process variables over time against upper and lower control limits typically set at three standard deviations from the mean to distinguish variation from special causes signaling instability. For an \bar{X} chart monitoring subgroup means, the upper control limit (UCL) and lower control limit (LCL) are calculated as: \begin{align*} \text{UCL} &= \mu + \frac{3\sigma}{\sqrt{n}}, \\ \text{LCL} &= \mu - \frac{3\sigma}{\sqrt{n}}, \end{align*} where \mu is the process mean, \sigma is the process standard deviation, and n is the subgroup sample size; these limits enable early detection of shifts in process centering or spread. Cumulative Sum (CUSUM) charts, introduced by Page in 1954, enhance sensitivity to small, sustained shifts by accumulating deviations from a target value, providing quicker anomaly detection than Shewhart charts in stable processes. SPC also incorporates process capability indices to assess quality potential: C_p = \frac{\text{USL} - \text{LSL}}{6\sigma} measures the ratio of specification width to process variation, while C_{pk} = \min\left(\frac{\text{USL} - \mu}{3\sigma}, \frac{\mu - \text{LSL}}{3\sigma}\right) accounts for process centering relative to upper (USL) and lower (LSL) specification limits, with values above 1.33 indicating capable processes for six-sigma quality levels. Adaptive control strategies adjust controller parameters in real-time to accommodate process changes, such as varying gains or time delays, ensuring robust performance without manual retuning. Gain scheduling, a classical adaptive technique, predefines controller gains as functions of measurable scheduling variables like operating points, allowing seamless transitions across nonlinear regimes common in chemical processes. Model Reference Adaptive Control (MRAC), originating from Whitaker's 1958 work on flight systems, uses a to define desired dynamics and tunes plant parameters to minimize , often via gradient-based methods like the MIT rule. Parameter estimation in adaptive systems frequently employs recursive least squares (RLS), which iteratively updates model coefficients by minimizing a weighted sum of squared prediction errors, enabling online identification of time-varying parameters with forgetting factors to emphasize recent data. In batch processes, where models degrade over cycles due to inconsistencies in raw materials or equipment wear, adaptive controls like MRAC and gain scheduling maintain trajectory tracking by continuously refining parameters, as demonstrated in semi-batch reactors where they reduce cycle time variations and improve yield consistency compared to fixed controllers. These methods differ from predictive approaches by focusing on reactive to historical patterns rather than proactive optimization via simulations, making them ideal for scenarios with high variability and limited computational resources for model-based forecasting.

Applications and Industries

Chemical and Petrochemical Processes

Advanced process control (APC) finds dominant application in the chemical and petrochemical industries, particularly in fluid catalytic cracking (FCC) units and ethylene crackers, where it optimizes yield maximization through multivariable predictive strategies. In FCC units, APC employs model predictive control to adjust catalyst circulation rates, reactor temperatures, and feed rates, enhancing light olefin and gasoline yields while minimizing coke formation. Similarly, in ethylene crackers, APC focuses on cracking severity control by manipulating furnace firing and coil steam ratios, which sustains optimal reaction extents and boosts ethylene and propylene recovery by up to 3-5% through refined distillation column operations. These processes present specific challenges that must address, including nonlinear dynamics from varying reaction kinetics, feedstock variability due to fluctuating crude compositions, and stringent constraints such as limits in high-temperature reactors to prevent . Nonlinear behaviors in towers, for instance, cause model errors of up to 25%, necessitating adaptive tuning to maintain amid furnace and uncertain feed properties. protocols integrate hard constraints into frameworks to mitigate risks like . APC implementations have demonstrated tangible impacts. A notable real-world example comes from 's deployments in chemical plants, including butadiene recovery units, where reduced steam consumption by 12 MBTU/hr and saved approximately $800,000 annually through stabilized operations across 40 manipulated inputs. In ethylene facilities, similar applications increased feed throughput and , yielding comparable economic benefits. Seamless integration of with distributed control systems (DCS) is essential for real-time operation in these industries, enabling direct manipulation of valves and setpoints while leveraging DCS data historians for model updates. This allows APC to overlay on existing DCS infrastructure, such as or ABB systems, facilitating closed-loop control without disrupting base-layer automation. Key metrics of APC success include reduced variability in product specifications, exemplified by precise octane number control in gasoline blending, where multivariable optimizers minimize deviations to within 0.5 RON units, cutting giveaway losses by 1-2% and enhancing blend consistency. Post-2020 trends highlight hybrid APC approaches for carbon capture processes in petrochemical facilities, combining with to dynamically adjust amine absorption rates and stripper reboiler duties, achieving up to 90% CO2 capture efficiency while minimizing energy penalties of 20-25%. These hybrids address fluctuating compositions in post-combustion systems, integrating with existing APC for sustainable operations.

Power Generation and Manufacturing

In power generation, advanced process control () is extensively applied to systems in plants to enhance and responsiveness. By integrating techniques, APC optimizes processes, maintaining stable steam pressure and while enabling rapid load following to match fluctuating demands. This approach stabilizes key parameters such as drum level and furnace pressure, reducing variability during startups and transients. APC also plays a critical role in emissions compliance, particularly for nitrogen oxide (NOx) reduction in fossil fuel-fired plants. Through precise adjustment of fuel-air ratios and burner operations, APC minimizes NOx formation while adhering to environmental regulations, achieving reductions of up to 30% in some installations without compromising output. For instance, in combined-cycle gas turbine plants, APC systems coordinate turbine firing and steam generation, yielding improved fuel efficiency and lower emissions. These controls address challenges posed by transient operations in turbines, where sudden load changes can lead to instability, by employing predictive models to anticipate and mitigate pressure swings and thermal stresses. In combined-cycle plants, such implementations have delivered 5-10% fuel savings through optimized heat recovery and load balancing, alongside improved ramp rates for faster grid response—up to 50% quicker startups—and enhanced overall stability. In manufacturing sectors, APC ensures uniformity in semiconductor fabrication facilities (fabs) by dynamically adjusting parameters during wafer processing. In high-precision environments like and , APC uses real-time feedback to compensate for tool drift and material variations, maintaining critical dimensions within nanometer tolerances and reducing defect rates. Challenges arise from high-speed variability in fab operations, where rapid throughput demands continuous adaptation to equipment states and environmental factors, often mitigated through run-to-run strategies. Outcomes include enhanced and throughput, with reported reductions in variability by up to 50% in production lines. APC extends to automotive assembly for quality control, where it monitors and adjusts variables in welding, painting, and component integration to ensure dimensional accuracy and surface consistency. By analyzing sensor data from robotic arms and conveyor systems, APC detects deviations in , preventing defects and enabling just-in-time corrections that align with principles. Adaptations of APC to renewables, such as wind farm curtailment implemented post-2015, further demonstrate its versatility in managing intermittent generation. These systems curtail turbine output strategically to prevent grid overloads, using predictive algorithms to balance power injection and maintain frequency stability, thereby reducing curtailment losses by 10-20% in variable conditions. Adaptive methods briefly complement these efforts by handling inherent variability in wind speeds.

Related Technologies and Integrations

Optimization and Simulation Tools

Real-time optimization (RTO) is a supervisory layer in advanced process control systems that periodically adjusts setpoints for underlying controllers to achieve economic objectives, such as minimizing costs or maximizing profits, by solving steady-state optimization problems based on current measurements. These problems typically involve formulations, expressed as minimizing an objective function f(\mathbf{x}) subject to constraints \mathbf{g}(\mathbf{x}) \leq \mathbf{0} and constraints from models, where \mathbf{x} represents decision variables like flow rates or temperatures. RTO operates on timescales of 15 to , allowing sufficient time for settling while responding to changes in conditions, feed quality, or equipment status. Simulation software plays a crucial role in designing and validating RTO and other advanced process control strategies by enabling dynamic modeling of complex systems and testing what-if scenarios before deployment. Tools like provide comprehensive steady-state and dynamic simulations of chemical processes, incorporating thermodynamic models, , and unit operations to predict behavior under varying conditions and support the development of accurate RTO models. These simulations facilitate offline optimization studies that inform online RTO implementations, ensuring robust performance without risking operational disruptions. In hierarchical control architectures, RTO integrates atop (MPC) by supplying economically optimal setpoints that MPC then tracks dynamically, bridging strategic economic goals with tactical regulatory actions. This layered approach allows RTO to handle plant-wide objectives, such as across units, while leveraging linear or solvers within MPC for feasible execution. Key benefits of RTO include enhanced economic performance through direct incorporation of profit-maximizing criteria, such as yield optimization or energy minimization, often yielding measurable gains like increased throughput or reduced utility consumption via integrated linear and solvers. For instance, in operations, RTO can coordinate crude allocation and product blending to lower overall costs, with reported cases achieving significant incremental profits through improvements. The adoption of RTO marked a historical shift in the from predominantly offline, periodic optimizers—reliant on manual model updates—to fully online systems that use for continuous adaptation, driven by advances in computational power and measurement technologies. An illustrative example is the Petrobras RECAP unit in , where an Aspen-based RTO system optimizes operations in two-hour cycles, maximizing profit by adjusting setpoints for and cracking units while reducing operational inefficiencies.

Digital Twins and Real-Time Systems

Digital twins in advanced control () represent virtual replicas of physical es, constructed using data from sensors to enable between the physical and digital domains. These models allow for the testing of various operational scenarios, such as adjustments or failure simulations, without risking disruptions to actual production lines. By continuously updating with live sensor inputs, digital twins facilitate predictive analysis and optimization of complex industrial systems, enhancing overall control precision. Real-time systems complement digital twins in APC by employing to process data closer to the source, minimizing delays in feedback loops critical for dynamic control. Protocols such as OPC UA play a pivotal role, providing a standardized, secure mechanism for low-latency data exchange across devices, controllers, and higher-level systems in APC architectures. This integration ensures that control decisions, such as setpoint adjustments, occur with sub-second responsiveness, supporting applications in high-stakes environments like continuous . OPC UA's platform-independent design further promotes between legacy equipment and modern infrastructures. The implementation of digital twins in APC relies on hybrid approaches that merge physics-based models—derived from fundamental engineering principles—with historical operational data to enable robust predictive simulations. Physics-based models capture underlying process dynamics, such as fluid flows or thermal exchanges, while historical data refines these models through calibration, improving their ability to forecast deviations under varying conditions. For instance, offline simulations generate datasets that inform , allowing the digital twin to adapt dynamically to observed states. This methodology has been applied in sectors like and to create interpretable for ongoing performance monitoring. Post-2018, the adoption of digital twins in APC has surged as part of Industry 4.0 initiatives, driven by advancements in cloud platforms and scalability. As of 2025, the digital twin market, including applications in APC, is projected to grow from €16.55 billion to €242.11 billion by 2032, with a of 39.8%, fueled by integrations with and analytics. A notable example is ' Insights Hub (formerly ), an open operating system that supports the creation of plant-wide digital twins by aggregating sensor data and running simulations in the cloud. Insights Hub enables seamless linkage of , production processes, and performance metrics, allowing for virtual commissioning and remote optimization of APC strategies. This platform has been instrumental in demonstrating operational digital twins in real settings, fostering new efficiencies in predictive control. The integration of digital twins and real-time systems yields significant benefits in APC, including accelerated fault detection and enhanced capabilities. By analyzing real-time data against simulated baselines, these systems can identify anomalies earlier, leading to reduced unplanned and improved process ; for example, case studies in show 1-3% throughput gains and over 5% improvements through better disturbance rejection. In operations, digital twins simulate potential failures like leaks, enabling predictive rerouting of flows or preemptive repairs to prevent disruptions, as demonstrated in oil and gas applications where virtual models forecast risks and optimize maintenance schedules. Despite these advantages, challenges persist in deploying digital twins and real-time systems for , particularly around and model . Cybersecurity threats, such as unauthorized access to feeds or manipulation of control , pose risks to interconnected systems, necessitating robust and access controls aligned with standards like those from NIST. Model —the degree to which the representation accurately reflects physical behaviors—remains difficult to maintain amid evolving conditions or incomplete , potentially leading to unreliable predictions if not regularly validated against real-world observations. Addressing these issues requires ongoing advancements in secure protocols and modeling techniques to ensure trustworthy implementations.

Artificial Intelligence Enhancements

Machine Learning in APC

Machine learning augments traditional advanced control () by leveraging data analytics and to handle nonlinearity, uncertainty, and high-dimensional data in , enabling more adaptive and efficient control strategies. techniques, particularly neural networks, are widely used for soft development, which estimates unmeasurable variables such as product metrics or internal states that are costly or impossible to measure directly with . These soft sensors integrate measurable inputs like temperature, pressure, and flow rates to infer outputs, improving monitoring and control in APC systems. For example, in chemical processes, neural network-based soft sensors have demonstrated high accuracy in predicting variables like polymer indicators, with hybrid models combining physics-based and data-driven components achieving low errors. Integration of with (MPC) forms hybrid MPC-ML frameworks, where ML components update process models online using streaming data, enhancing adaptability to drifts or disturbances without full re-identification. Traditional model identification often requires weeks of plant testing and data collection, but ML-accelerated methods, such as or incremental training, can significantly reduce this time by leveraging historical data and parameters in . This approach has been shown to improve control performance in dynamic environments, such as distillation columns or reactors, by maintaining tighter adherence and reducing optimization computation time by up to 50%. Key methods in APC include for control policy optimization, where agents interact with process simulations to learn reward-maximizing actions, such as setpoint adjustments, often outperforming classical MPC in nonlinear or settings like batch reactors. via autoencoders, unsupervised neural networks that reconstruct input data and flag high reconstruction errors as deviations, enables proactive fault identification in multivariate time-series data from sensors. These methods extend by incorporating learning from operational feedback, with policies achieving improved energy efficiency in simulated chemical processes. Since 2020, explainable AI (XAI) has emerged as a critical trend in to address opacity in black-box models, ensuring interpretable decisions for in safety-critical industries like . Techniques such as SHAP (SHapley Additive exPlanations) attribute predictions to input features, revealing how variables like feed composition influence control outputs and facilitating audits under standards like for . This transparency aids in validating ML-enhanced against regulatory requirements, with XAI-integrated models showing no loss in predictive accuracy while improving user trust. A representative application is ML-based yield prediction in polymer plants, where supervised models like random forests or analyze process data to forecast production , improving prediction accuracy over baseline methods and enabling optimized operating conditions to minimize waste. The core mechanism involves a , \hat{y} = f(Wx + b) where \hat{y} is the predicted , x represents input features (e.g., , catalyst concentration), W the weight , b the , and f an like ReLU; the model is trained via to minimize loss functions such as , allowing rapid inference in APC loops.

AI-Driven Predictive Maintenance

AI-driven predictive maintenance (PdM) in advanced process control (APC) leverages to analyze sensor data and forecast equipment failures, enabling preemptive adjustments to control strategies that maintain process stability and efficiency. By integrating PdM models with APC systems, operators can dynamically modify setpoints or operational parameters to mitigate risks before disruptions occur, shifting from reactive to proactive maintenance paradigms. This approach is particularly valuable in continuous processes where can cascade into significant production losses. Key techniques in AI-driven PdM for APC include time-series forecasting using (LSTM) networks, which process sequential to predict trends over time. For instance, LSTMs excel in modeling the temporal dependencies in , , and signals from equipment like pumps, allowing for accurate remaining useful life (RUL) estimations. analysis, another core method, employs algorithms to detect anomalies in spectra from rotating machinery in process units, such as centrifugal pumps, identifying early signs of imbalance or bearing wear through . These techniques enhance APC by feeding failure predictions directly into loops for automated responses. The typical for implementing -driven PdM in begins with data ingestion from IoT sensors and historical logs, capturing high-frequency streams like vibration and flow rates. This is followed by , where domain-specific transformations—such as transforms for or rolling statistics for trend detection—are applied to raw data to improve model interpretability. Models are then offline and deployed via edge devices for , ensuring low-latency predictions that integrate seamlessly with software for closed-loop adjustments. Data from digital twins can supplement this by providing simulated failure scenarios for robust . Benefits of AI-driven PdM in APC include a 10-20% reduction in unplanned outages through timely interventions, alongside lower maintenance costs and improved asset utilization. A notable example is Shell's 2022 deployment of AI-PdM in its refineries, where the system scaled to monitor over 10,000 pieces of equipment using C3 software, resulting in proactive repairs that cut by approximately 20% and enhanced operational reliability. These outcomes stem from AI's ability to prioritize high-risk assets, optimizing across plants. Recent advancements since 2023 include the adoption of () frameworks, which enable multi-site PdM models by training across distributed datasets without centralizing sensitive operational data, thus preserving in global process industries. By 2025, has facilitated collaborative PdM in sectors with stringent needs, such as and chemicals, with applications in cross-plant equipment monitoring. A key metric for evaluating AI-driven PdM success in APC is the extension of mean time between failures (MTBF), which measures reliability gains from predicted interventions. Implementations have shown significant MTBF increases for critical assets like pumps and compressors, as AI enables condition-based that aligns with actual wear rather than fixed schedules. This metric underscores PdM's role in sustaining APC performance over extended operational cycles.

Implementation Challenges and Business Aspects

Deployment Strategies and Economics

Deployment of advanced process control (APC) systems typically follows a phased rollout to mitigate risks and ensure alignment with operational needs. This approach begins with pilot testing on select unit operations or constraint loops, allowing for refinement of control models and algorithms before scaling to full plant-wide implementation. Such incremental deployment minimizes disruptions and enables early demonstration of benefits, such as improved throughput in targeted processes. Vendor selection plays a critical role in APC deployment, with major providers like ABB and offering distinct capabilities tailored to industrial requirements. ABB's solutions, such as the Ability System 800xA, emphasize integration with digital twins for enhanced predictive , while 's DeltaV platform focuses on scalable, embedded APC tools that operate directly within distributed systems (DCS). Organizations evaluate vendors based on , services, and proven in similar applications to ensure seamless adoption. Customization for legacy systems is essential, as many plants rely on older DCS or programmable logic controllers (PLC). APC implementations often involve layering software atop existing infrastructure to leverage historical data while addressing compatibility issues, such as data quality and protocol mismatches, without requiring full hardware overhauls. This adaptation ensures continuity while introducing multivariable predictive control. Economically, APC deployment involves significant initial capital expenditures covering software, modeling, and integration. These investments yield payback periods of 6 to 18 months, driven by profit gains of 3-5% through increased throughput, reduced energy consumption, and optimized raw material use. For instance, APC optimization can boost throughput by up to 15% and cut energy use by 10%, directly enhancing margins in energy-intensive operations. Return on investment (ROI) for APC is commonly assessed using net present value (NPV), calculated as: \text{NPV} = \sum_{t=0}^{T} \frac{\text{Benefits}_t - \text{Costs}_t}{(1 + r)^t} where t represents time periods, r is the , and benefits include operational savings while costs encompass CAPEX and ongoing expenses. This metric is particularly sensitive to energy prices, as fluctuations can amplify or diminish projected savings from efficiency gains; for example, rising energy costs heighten the of APC's optimization in reducing consumption. Real-time optimization (RTO) complements APC by aligning controls with dynamic economic objectives, such as varying feedstock prices. Key challenges in APC deployment include , where operator resistance due to unfamiliarity with automated decisions can hinder adoption, necessitating structured and communication. Model represents another hurdle, with annual costs often amounting to 10-20% of initial CAPEX for recalibration to account for process drifts, equipment wear, or feedstock variations; failure to maintain models can erode benefits within 1-2 years. Best practices emphasize forming cross-functional teams comprising engineers, operators, IT specialists, and management to align objectives and facilitate integration. Pre-deployment testing, using historical to validate models in a , is crucial for identifying issues and building confidence before live rollout. These steps ensure robust performance and sustained value. The APC market was valued at USD 3.1 billion in 2025 (as of mid-2025), projected to grow at a (CAGR) of 10.6% through 2030, propelled by mandates that favor energy-efficient controls to meet environmental regulations and reduce carbon footprints.

Professionals, Training, and Market Trends

Advanced process control (APC) relies on a specialized , including APC engineers who possess expertise in dynamic modeling, multivariable predictive control, and system optimization to design and deploy APC applications across plants. Consultants, such as those from or i-APC Consulting, provide specialized services in implementing and tuning APC strategies for complex processes like or , often bridging gaps between vendor software and site-specific needs. Operators, in human-machine interface (HMI) systems, monitor and interact with APC outputs in real-time to ensure safe and efficient adjustments, requiring familiarity with graphical dashboards and alarm management. Professional training for APC emphasizes certifications and academic programs that build foundational and advanced skills in automation. The International Society of Automation (ISA) offers the Certified Control Systems Technician (CCST) credential, which validates competencies in measurement, control loops, and troubleshooting for technicians supporting APC systems, with requirements including at least five years of combined education and experience. University curricula, such as MIT's ongoing courses in systems and controls (e.g., 2.004 Dynamics and Control II) and feedback control systems (e.g., 16.30 since Fall 2010), provide rigorous instruction in linear systems, state-space methods, and process dynamics essential for APC modeling. Key professionals in APC include pioneers like Rudolf E. Kalman, whose 1960s work on and state-space representations laid the groundwork for modern multivariable predictive control techniques. Contemporary experts, such as Allan Kern, contribute through practical advancements in sustainable APC paradigms, authoring influential papers on agile, model-based optimization without embedded solvers. Communities like the Control.com forum facilitate knowledge sharing among APC practitioners, discussing implementation challenges and best practices in process industries. Market trends in reflect a shift toward cloud-enabled, subscription-based () models post-2020, reducing upfront capital costs and enabling scalable deployment for remote monitoring and updates. Leading vendors, including AspenTech, ABB, and , dominate the sector, with the global market valued at USD 3.1 billion in 2025 (as of mid-2025) and projected to grow at a 10.6% CAGR through 2030, driven by demand in oil & gas and chemicals. Looking ahead, APC demands skilled specialists in AI integration, with employment for related industrial engineers projected to grow 11% from 2024 to 2034, outpacing average occupational growth due to needs in . However, small and medium-sized enterprises (SMEs) face a persistent skills gap in managing APC systems, exacerbated by limited resources for training and expertise in advanced modeling, hindering adoption compared to larger firms.

Terminology and Standards

Key Concepts and Definitions

Advanced control (APC) encompasses a suite of techniques designed to manage complex industrial by coordinating multiple interacting variables, enabling optimization while respecting operational boundaries. Central to APC is multivariable control, which addresses the of variables—such as temperatures, pressures, and flows—that influence one another, allowing simultaneous regulation of multiple controlled variables (CVs) through manipulated variables (MVs) like positions or feed rates. This contrasts with single-loop controls by providing a holistic view of the unit, improving overall stability and efficiency. A key feature of APC is constraint handling, which ensures variables stay within safe and feasible operating windows defined by high and low limits (hard constraints that must be strictly satisfied to avoid equipment damage or safety issues) and (soft constraints representing optimal points that can be approached but violated with penalties if necessary). In practice, APC prioritizes maintaining CVs within these hard limits before pursuing optimization toward , dynamically adjusting MVs to balance priorities. APC often employs (MPC), a core methodology where horizons define the temporal scope of predictions and actions: the prediction horizon (typically 10–60 steps) forecasts future system behavior over a finite window, while the control horizon (often 2–5 steps, shorter than the prediction horizon) determines how many future MV moves are optimized at each interval. These horizons enable proactive adjustments, with the prediction horizon capturing process dynamics and the control horizon ensuring computational feasibility. Compared to proportional-integral-derivative () controllers, APC excels in disturbance rejection by using multivariable models to anticipate and counteract external changes—such as feed composition variations or equipment —more rapidly and effectively, minimizing deviations across coupled variables rather than reacting sequentially as in PID loops. This capability stems from APC's integration of elements and predictive modeling, which reduce the impact of disturbances on overall process performance. APC distinguishes between steady-state models, which assume equilibrium conditions and are used for real-time optimization (RTO) to identify long-term optimal operating points, and dynamic models, which account for time-varying transients to handle short-term responses like startups or load changes. Steady-state models focus on balanced inputs and outputs for calculations, while dynamic models simulate trajectories to predict and control non-equilibrium behaviors. Key supporting terms in APC include gain scheduling, a technique that adjusts controller parameters (e.g., proportional gains) based on current operating conditions to accommodate nonlinear process dynamics. Another is the soft sensor, a virtual measurement tool employing mathematical models to estimate unmeasurable or hard-to-measure variables in , such as product quality or concentrations, thereby enhancing monitoring and control without additional hardware. The terminology in APC has evolved from the 1980s emphasis on "predictive control" (e.g., early MPC algorithms like DMC for forecasting and regulation) to contemporary "advanced regulatory control," which broadens to include multivariable strategies for ongoing process stabilization and optimization beyond mere prediction.

Industry Standards and Best Practices

Advanced process control (APC) relies on established industry standards to ensure reliable integration, safety, and interoperability across manufacturing and process industries. The ISA-95 standard, also known as ANSI/ISA-95 or IEC 62264, provides a framework for enterprise-control system integration, defining models and terminology for activities such as production scheduling, resource allocation, and data exchange between enterprise resource planning systems and manufacturing execution systems. This standard facilitates seamless communication between business and control layers, enabling APC systems to optimize operations while aligning with broader enterprise goals. Similarly, IEC 61511 outlines requirements for the specification, design, installation, operation, and maintenance of safety instrumented systems (SIS) within process industries, ensuring that APC implementations incorporate functional safety to mitigate risks associated with hazardous processes. Best practices for emphasize rigorous model validation and ongoing maintenance to sustain . A key practice is periodic retuning of APC models to account for changes such as or feedstock variations, preventing and maximizing benefits like and throughput. Sector-specific guidelines further tailor APC deployment. In the and gas industry, API RP 554-1 provides recommended practices for implementing control systems, covering design, configuration, and testing to enhance reliability in and facilities. Cybersecurity is a critical aspect, addressed by ISA-99 (now part of the / series), which establishes procedures for securing industrial automation and control systems against threats, including and defense-in-depth strategies essential for protecting APC from cyber vulnerabilities. Recent developments in APC standards reflect growing attention to cybersecurity, with the 2024 updates to ISA/IEC 62443 focusing on enhanced , (e.g., software ), and . As of January 2025, ANSI/ISA-62443-2-1-2024 further addresses organization-wide cybersecurity programs for establishing, implementing, and improving programs relevant to APC. Integration of in APC is supported by frameworks like ISA/IEC 62443, as highlighted in the ISA position paper on industrial AI (November 2025), which emphasizes secure, transparent, and reliable AI systems without new ethics-specific standard updates. Compliance with these standards yields tangible benefits, including streamlined regulatory s and cost savings on . Adhering to , for example, demonstrates robust safety practices, often leading to reduced audit durations by providing verifiable and lower insurance premiums through recognized . An illustrative example is the application of , an for integrating life-cycle data in plants, which supports semantic models for simulations in APC. This standard enables between design tools and systems, allowing accurate dynamic simulations of behaviors to predict and optimize strategies in oil and gas facilities.

References

  1. [1]
    [PDF] Process Control and Energy Efficiency - OSTI.GOV
    Mar 23, 2020 · By contrast, advanced process control consists of multi- loop/multivariable configurations (including MPC, discussed later); regulatory ...
  2. [2]
    [PDF] Model Predictive Controllers: A Critical Synthesis of Theory and ...
    With over 2000 industrial installations, model predictive control (MPC) is currently the most widely implemented advanced process control technology for.
  3. [3]
    [PDF] Artificial Intelligence in Drug Manufacturing - FDA
    ○ Advanced Process Control (APC): APC allows dynamic control of the manufacturing process ... applications to control manufacturing processes by adapting ...
  4. [4]
    New Control Approaches to Enable Quality Assurance and Process ...
    Models are at the heart of advanced process control (APC) strategies, and applications include model predictive control (MPC) (Lee 2011), fault detection and ...
  5. [5]
    What Is Advanced Process Control? - EZSoft Inc.
    Nov 21, 2024 · APC is the use of advanced techniques to enhance the performance of complex industrial processes, surpassing traditional control methods.
  6. [6]
    Advanced process control: Indispensable process optimization tool
    In this article, as in industry, advanced process control (APC) refers primarily to multi-variable control. ... Industry endorses this concept whenever it uses ...
  7. [7]
    Advanced Process Control: Definition, Benefits, and Applications
    Mar 6, 2025 · APC is a collection of advanced techniques and technologies designed to optimize industrial processes beyond basic regulatory systems.
  8. [8]
    ABB Ability™ Advanced Process Control | Solutions - ABB
    Advanced Process Control uses sophisticated Model Predictive Control technology to manage and optimize process units, increase throughput, increase energy ...
  9. [9]
    Advanced Process Control | Maximize profitability - AspenTech
    AspenTech's Advanced Process Control simplifies workflows and helps to maximize profitability by maintaining optimal operating conditions 100% of the time.
  10. [10]
    A Comprehensive Guide to Advanced Process Control Systems
    APC systems are implemented in industries that involve continuous processes, such as chemical, petrochemical, oil and mineral refining, food processing ...Missing: scope discrete<|control11|><|separator|>
  11. [11]
    The potential of advanced process controls in energy and materials
    Nov 23, 2020 · Optimizing advanced process controls can create significant value for critical industrial processes. Maximizing that value requires a comprehensive approach.
  12. [12]
    Advanced Process Control Market Size to Hit USD 5.2 Bn by 2034
    Apr 29, 2025 · According to reports, energy savings from APC implementation range from 3% to 15%, depending on the process and current operations.
  13. [13]
    The 1973 Oil Crisis: Three Crises in One—and the Lessons for Today
    Oct 16, 2023 · The 1973 oil embargo shook the global energy market. It also reset geopolitics, reordered the global economy, and introduced the modern energy era.
  14. [14]
    Advanced process control: a history overview - Simulate Live
    Aug 27, 2015 · During 80s MPC technology slowly started to prove the results to gain wider acceptance during 90s. During 80s, the algorithms had to be improved ...
  15. [15]
    Dynamic matrix control¿A computer control algorithm
    Dynamic matrix control¿A computer control algorithm · C. R. Cutler, B. L. Ramaker · Published 1979 · Computer Science, Engineering · IEEE Transactions on Automatic ...Missing: history Laboratories
  16. [16]
    [PDF] A Proven History of Innovation in Advanced Process Control and ...
    AspenTech has consistently delivered significant innovations in APC over the last three decades and its APC technology has been widely deployed, delivering ...
  17. [17]
    APC and RTO Experiencing Increased Use in China| ARC Advisory
    Working largely with strategic partners, Honeywell and AspenTech, Sinopec implemented hundreds of APC and RTO projects in the years that immediately followed.
  18. [18]
    [PDF] Role of Advanced Process Control in advancing Industry 4.0 - Infosys
    However, Industry 4.0 approaches help shift the overall control from a “local” process control to “process-wide” management, that can elevate on to the next ...<|separator|>
  19. [19]
    Model predictive control: Theory and practice—A survey
    We refer to Model Predictive Control (MPC) as that family of controllers in which there is a direct use of an explicit and separately identifiable model.
  20. [20]
    [PDF] Model predictive control: Theory, computation and design
    This chapter gives an introduction into methods for the numerical so- lution of the MPC optimization problem. Numerical optimal control builds on two ®elds: ...Missing: seminal | Show results with:seminal
  21. [21]
    [PDF] A survey of industrial model predictive control technology - CEPAC
    This paper provides an overview of commercially available model predictive control (MPC) technology, both linear and nonlinear, based primarily on data ...
  22. [22]
    Use Model Predictive Control to Improve Distillation Process
    The advantage of MPC applied to distillation columns is greatest when applied to a series of columns as an entire separation train. The MPC controller can ...
  23. [23]
    Quality Control Charts1 - Shewhart - 1926 - Wiley Online Library
    First published: October 1926 ; Citations · 50 ; A brief description of a newly developed form of control chart for detecting lack of control of manufactured ...
  24. [24]
    6.1.6. What is Process Capability?
    Process capability compares a process's output to specification limits, using capability indices to see if most measurements fall within those limits.
  25. [25]
    Survey of gain-scheduling analysis and design
    The scope of this paper includes the main theoretical results and design procedures relating to continuous gain-scheduling (in the sense of decomposition of ...
  26. [26]
    [PDF] Design of Low Complexity Model Reference Adaptive Controllers
    Controller. Model reference adaptive control (MRAC) derives its name from the use of reference model dynamics to define a desired trajectory for the system ...
  27. [27]
    Continuous-time least-squares forgetting algorithms for indirect ...
    This paper aims at giving a general analysis of the adaptivity of recursive least-squares (LS) algorithms for continuous-time adaptive control.
  28. [28]
    https://ntrs.nasa.gov/api/citations/20120015215/downloads/20120015215.pdf
  29. [29]
    https://www.sciencedirect.com/science/article/pii/S0947358021000728
  30. [30]
    An online optimization strategy for a fluid catalytic cracking process ...
    The CBR method based on big data technology proposed in this study provides a feasible solution for fluid catalytic cracking to achieve online process ...
  31. [31]
    [PDF] ADVANCED CONTROL OF ETHYLENE PLANTS WHAT WORKS ...
    CRACKING SEVERITY CONTROL IS THE MOST IMPORTANT APC APPLICATION. Ethylene cracker most important APC application is reaction severity control. The.Missing: scholarly articles
  32. [32]
    [PDF] Control in the Process Industries
    Process limitations include too many unknown parameters or a process that is too nonlinear for a “standard” APC solution to be applied. Obtaining good ...
  33. [33]
    (PDF) Advanced Process Control in ExxonMobil Chemical Company
    Production scheduling and advanced process control are related tasks for optimizing chemical process operation. Traditionally, implementation of process control ...Missing: 1990s | Show results with:1990s
  34. [34]
    Advanced Process Control Software, Solutions & Systems - ABB
    Advanced Process Control (APC) is a control solution that increases process performance. APC communicates with the plant's distributed control system (DCS) ...
  35. [35]
    [PDF] Strategies for Achieving Optimal Gasoline Blending
    The ratio of olefins to aromatics used in the neat blendstock significantly determines the final blended octane of oxygenated gasolines. An example of this is ...Missing: variability | Show results with:variability
  36. [36]
    Hybrid Advanced Control Strategy for Post-Combustion Carbon ...
    This study introduces a novel centralized and decentralized hybrid control strategy for the post-combustion carbon capture plant.
  37. [37]
    Advanced Process Control for industrial steam automation - ABB
    Advanced process control (APC) using model predictive control (MPC) with System 800xA DCS enables higher automation and optimization of steam power, leading to ...
  38. [38]
    A New Era in Power Plant Control Performance - POWER Magazine
    May 29, 2009 · Siemens Energy has developed an advanced process controller (APC) for controlling the main steam pressure of a steam power plant by adjusting the fuel flow as ...
  39. [39]
    More profitable power plants through advanced process control
    May 14, 2025 · Modern advanced process control systems are designed to work with any existing DCS. They operate independently and remain transparent to the ...
  40. [40]
    Reduced emissions with advanced process control systems - Valmet
    Apr 4, 2019 · Bord na Móna's Edenderry Power Plant in Ireland has reduced its NOx emissions with an advanced process control application, the Valmet DNA Combustion Manager.
  41. [41]
    Advance Process Control solutions for semiconductor manufacturing
    The APC system uses wafer metrology, process models and sophisticated control algorithms to provide dynamic fine-tuning of intermediate process targets that ...Missing: processing | Show results with:processing
  42. [42]
    [PDF] Advanced Process Control in Semiconductor Manufacturing - AIChE
    The implementation of scatterometry for STI etch control in. FASL Fab 25 was one of the first large-scale uses of scatterometry in a production semiconductor.
  43. [43]
    APC: Optimize Manufacturing with Data Science & AI | Kalypso
    Advanced Process Control uses AI and process modeling to substantially reduce process variability and improve yield and throughput.<|separator|>
  44. [44]
    [PDF] 2015 Wind Technologies Market Report - Department of Energy
    Aug 16, 2016 · this signal to control wind will lower overall wind curtailments and increase utilization of the transmission system. • MISO incorporated a ...
  45. [45]
    Wind turbine controller design considerations for improved wind ...
    For optimal wind farm level grid setpoint tracking, both farm level and turbine level curtailment strategies need to be co-optimized.<|separator|>
  46. [46]
    Real-Time Optimisation - an overview | ScienceDirect Topics
    Real-time optimization (RTO) is defined as the large-scale, frequent optimization of operating conditions in process units, typically conducted every 30 ...
  47. [47]
    Real-Time optimization as a feedback control problem – A review
    Feedback optimizing control aims to achieve asymptotic optimal operation by directly manipulating the inputs using feedback controllers.
  48. [48]
    Aspen Plus | Leading Process Simulation Software - AspenTech
    Integrated process modeling with economic, energy, safety and emissions analysis to improve time-to-market, process efficiency and sustainability performance.
  49. [49]
    Aspen Process Simulation: Optimization of Chemical and ... - ENCOS
    Aspen Plus is an advanced process simulation software used to optimize chemical processes. It enables precise modeling of chemical reactions, separation ...
  50. [50]
    Integration of real-time optimization and model predictive control
    This paper proposes a controller design approach that integrates RTO and MPC for the control of constrained uncertain nonlinear systems.
  51. [51]
    https://www.encos.de/en/simulation/aspen-process-simulation/
  52. [52]
    Upstream/Downstream Real Time Surveillance and Optimization ...
    Oct 8, 2012 · Reference 14 indicates refinery energy cost minimization, closed loop RTO generating incremental profit of 6,000 bbls. oil equivalent per ...
  53. [53]
    Typical Architecture of Real-Time Optimization - ResearchGate
    The Petrobras S.A. RECAP unit in Mauá, Brazil runs an RTO refinery model with an Aspen RTO optimizer to maximize the profit within two hour cycles. To reduce ...
  54. [54]
    Digital Twin | Siemens Software
    A digital twin is a virtual model mirroring a real-world object or system using sensor data and simulations. It allows real-time monitoring and analysis of ...Digital Twin: From... · Explore Digital Twin Related... · Start With A Free Trial<|separator|>
  55. [55]
    Case study use of a digital twin with Advanced Process Control - ABB
    Digital twins are powerful tools with significant advantages, especially when developing a new control strategy. The virtual environment allows for the ...
  56. [56]
    Industry 4.0 via Real-Time and OPC UA - SYSGO
    Jul 26, 2023 · OPC UA enables secure communication, networking, and remote access, enabling Industry 4.0 by connecting data points and enabling remote ...
  57. [57]
    OPC UA technology bridges gap between IT and OT systems
    Jan 24, 2024 · OPC UA bridges IT and OT systems by providing open, interoperable data exchange, acting as a universal language for industrial automation.
  58. [58]
    OPC UA in Edge Computing and Inner/Outer Loop Control
    This blog illustrates how OPC UA in the context of edge control brings intelligence to data and security to a system. Edge control systems at their core have an ...Missing: APC | Show results with:APC
  59. [59]
    From Physics-Based Models to Predictive Digital Twins via ... - arXiv
    Apr 23, 2020 · This work develops a methodology for creating a data-driven digital twin from a library of physics-based models representing various asset states.
  60. [60]
    [PDF] Data-driven physics-based digital twins via a library of component ...
    Reduced-order modeling produces physics-based computational models that are reliable enough for predictive digital twins, while still being fast to evaluate.
  61. [61]
    Industrie 4.0: Siemens demonstrates digital twin in actual operation
    Apr 24, 2017 · The underlying foundation for new business models for customers is connection to MindSphere, the cloud-based, open operating system from Siemens ...
  62. [62]
    The Digital Twin - Siemens Global
    As a virtual representation of a product, production process, or performance, the digital twin enables all process stages to be seamlessly linked.
  63. [63]
    [PDF] Answering Industry 4.0 with Digital Enterprise and MindSphere
    Digital is not central to their corporate strategy. • They perceive digital only as a tool for incremental efficiency gains.
  64. [64]
    Digital Twin for the Oil & Gas Industry - IBM
    For example, a digital twin of an oil pipeline system can help foresee potential leaks or ruptures, enabling operators to repair the pipeline before a dangerous ...
  65. [65]
    Predictive maintenance using digital twins: A systematic literature ...
    Digital twins provide real-time data for predictive maintenance, which aims to foresee when a component will fail. This review identifies aspects of this ...
  66. [66]
    [PDF] Security and Trust Considerations for Digital Twin Technology
    This report also discusses both traditional and novel cybersecurity challenges presented by digital twin technology as well as trust considerations in the ...
  67. [67]
    Digital Twins for Advanced Manufacturing | NIST
    Apr 15, 2024 · The Digital Twins for Advanced Manufacturing project provides technical contributions to standards to help manufacturers systematically identify digital twin ...
  68. [68]
    [PDF] FIDELITY OF THE DIGITAL TWIN | Dell Learning
    It is difficult to develop a representative Digital Twin simulation environment, particularly if the system splits processing between the Edge, Core, and Cloud.
  69. [69]
    The role of artificial intelligence-driven soft sensors in advanced ...
    This article attempts to explore the state-of-the-art artificial intelligence (Al)-driven soft sensors designed for process industries and their role in ...
  70. [70]
    Nonlinear Dynamic Soft Sensor Development with a Supervised ...
    May 2, 2022 · A supervised hybrid network based on a dynamic convolutional neural network (CNN) and a long short-term memory (LSTM) network is designed by constructing ...
  71. [71]
    Industrial data science – a review of machine learning applications ...
    Apr 21, 2022 · In this work, industrial data science fundamentals will be explained and linked with commonly-known examples in process engineering, followed by a review of ...2.2 Unsupervised Models · 3.4 Process Control And... · Notes And References
  72. [72]
    Accelerating process control and optimization via machine learning
    Dec 24, 2024 · In this paper, we discuss recent advances in (i) the representation of decision-making problems for machine learning tasks, (ii) algorithm selection, and (iii) ...
  73. [73]
    [PDF] APC and Artificial Intelligence - Honeywell Process Solutions
    Learning new models in real-time. An extension of model identification from historical data is to learn the model from operating data, in real-time. In this ...
  74. [74]
    https://pubs.acs.org/doi/10.1021/acsomega.2c01108
  75. [75]
    Where Reinforcement Learning Meets Process Control: Review and ...
    This paper presents a literature review of reinforcement learning (RL) and its applications to process control and optimization.
  76. [76]
    How to support decision making with reinforcement learning in ...
    In this review article, we explore the application of reinforcement learning (RL) at the different levels of hierarchical chemical process control.
  77. [77]
    Enhancing Autoencoder-Based Machine Learning through the Use ...
    Sep 23, 2024 · The methodology employed herein consists of a comprehensive data-driven approach using advanced process control and machine learning techniques ...
  78. [78]
    Explainable AI for trustworthy intelligent process monitoring
    To address that issue, this Short Communication discusses the necessity of embedding explainable artificial intelligence (XAI) in AI-based control charts.
  79. [79]
    Machine learning approach for prediction of the grafting yield in ...
    Among machine learning algorithms as a prediction model on the grafting yield, XGBoost and random forest models showed higher prediction accuracy, compared to a ...
  80. [80]
    Preventing First Pass Yield Losses In Polymers Before They Happen
    ### Summary of ML Improving Yield in Polymer Plants
  81. [81]
    Integrating AI-Driven Predictive Maintenance and Process Control in ...
    Aug 4, 2025 · This research explores the application of AI technologies, with a specific focus on predictive maintenance and process optimization, to enhance ...
  82. [82]
    AI's Transformative Role in Predictive Maintenance - Automation World
    May 7, 2025 · Predictive maintenance combines data, sensors and artificial intelligence (AI) to forecast equipment failures before they occur and enable timely interventions.
  83. [83]
    https://www.sciencedirect.com/science/article/pii/S0360835225005534
  84. [84]
    AI-Enabled Predictive Maintenance in Manufacturing - InfoBeans
    Aug 22, 2025 · Vibration Analysis Technology: A key part of rotating machinery monitoring—AI models can detect subtle changes in vibration patterns linked ...
  85. [85]
    AI for Predictive Maintenance in Manufacturing: -70% Downtime
    Apr 29, 2025 · Covers pumps, gearboxes, and fans. AI analyzes vibration patterns, speed shifts, and acoustic emissions to detect early signs of wear or ...<|separator|>
  86. [86]
    SuperEllipse/edge2ai_pred_maint: Predictive Maintenance at Edge
    Conceptual Architecture. The machine learning workflow comprising of data ingestion, exploration, feature engineering and model training is performed in the CML ...
  87. [87]
    How Edge AI is Transforming Predictive Maintenance in Harsh ...
    May 13, 2025 · With Delphisonic's Edge AI-based predictive maintenance systems, rail and industrial operators can ensure safety, reliability, and efficiency— ...
  88. [88]
    Case Study: How Shell and BP Use AI to Prevent Equipment Failures
    Jul 2, 2025 · Shell's experience shows how predictive maintenance helps cut unplanned downtime by 20% and slashes maintenance costs by 15%.
  89. [89]
    Shell Scales AI Predictive Maintenance with C3 AI to 10,000 Pieces
    Mar 8, 2022 · AI predictive maintenance enables Shell to identify equipment degradation and failures before they happen, allowing operators to take proactive ...Missing: refineries | Show results with:refineries
  90. [90]
    Federated Learning for Predictive Maintenance and Anomaly ... - MDPI
    Aug 22, 2023 · Federated learning enables learning without issues with data privacy and leakage. Most DL/ML models learn based on big data, which can cause ...
  91. [91]
    [PDF] Federated Learning for Predictive Maintenance and Quality ... - arXiv
    Federated learning. (FL) enables multiple participants to develop a machine learning model without compromising the privacy and confidentiality of their data.
  92. [92]
    AI-Powered Predictive Maintenance Ultimate Guide 2024
    Rating 4.0 (5) Predictive maintenance enhances equipment reliability by continuously monitoring performance metrics, ensuring that machinery operates at peak efficiency.
  93. [93]
    Advanced Process Control + AI: Here's How Plants are Evolving
    Jul 1, 2025 · Discover how AI-enhanced Advanced Process Control drives measurable efficiency and improves throughput without replacing existing systems.Missing: reduction | Show results with:reduction
  94. [94]
    Top Advanced Process Control Companies & How to Compare ...
    Oct 7, 2025 · Emerson Automation Solutions: Provides scalable APC tools tailored for various industries. ABB: Combines advanced control with digital twin ...
  95. [95]
    Compare ABB Ability System 800xA vs. Emerson Ovation in 2025
    What's the difference between ABB Ability System 800xA and Emerson Ovation? Compare ABB Ability System 800xA vs. Emerson Ovation in 2025 by cost, reviews, ...
  96. [96]
    [PDF] Advanced Process Control (APC) - Siemens
    For example the pay back period of an APC optimized distillation column is typically between 1 to 2 years. Project examples. •. Separation of phenol and acetone ...<|separator|>
  97. [97]
    [PDF] Economic Assessment of APC and RTO Using Option to Expand
    Nov 25, 2016 · Typically, Advanced Process Control (APC) project employs conventional economic assessment such as Net Present Value (NPV) and Payback period ( ...
  98. [98]
    Advanced Process Control - Sustaining Benefits and Costs - Scribd
    Rating 5.0 (1) 1. APC projects are often treated as capital expenditures but typically have short lifespans of 1-2 years if not properly maintained through model recalibration ...
  99. [99]
    Advanced Process Control Market Size & Share Report 2030
    The global advanced process control market size was estimated at USD 2173.6 million in 2023 and is projected to reach USD 4545.2 million by 2030, ...
  100. [100]
    $$75k-$190k Advanced Process Control Engineer Jobs - ZipRecruiter
    Advanced Process Control (APC) Engineers are specialized professionals who design, implement, and maintain advanced control systems in industrial processes, ...
  101. [101]
    i-APC | LinkedIn
    i APC is focused on delivering high quality applications that meet the customer's safety, economic, technical and environmental metrics.Missing: IPA | Show results with:IPA
  102. [102]
    Mastering Advanced Process Control: A Professional Journey | ABB
    Jun 6, 2023 · Advanced Process Control (APC) plays a pivotal role in enhancing process performance, maximizing productivity, and minimizing costs. As a ...
  103. [103]
    Certified Control Systems Technician (CCST)
    To become an ISA CCST, you must meet certain education and work experience requirements and pass an exam. Learn more about CCST requirements. CCST Body of ...CCST Requirements · Prepare for the CCST Exam · CCST Body of KnowledgeMissing: APC | Show results with:APC
  104. [104]
    Feedback Control Systems | Aeronautics and Astronautics
    This course will teach fundamentals of control design and analysis using state-space methods. This includes both the practical and theoretical aspects of ...Lecture Notes · Syllabus · Assignments
  105. [105]
    Advanced process control | Automation & Control Engineering Forum
    Oct 26, 2001 · I have been trying to identify process improvement opportunities in our batch plant where advanced process control can make an impact.
  106. [106]
    Advanced Process Control Market Size, Share And Forecast
    Rating 4.9 (49) Advanced Process Control Market size was valued at USD 5570.88 Million in 2024 and is projected to USD 10182.55 Million by 2032, growing at a CAGR of 9.11%
  107. [107]
    Advanced Process Control Market Size, Growth & Industry Trends
    Jun 18, 2025 · The advanced process control market generated USD 3.1 billion in 2025 and is projected to reach USD 5.1 billion by 2030, advancing at a 10.6% CAGR.Missing: 1980s | Show results with:1980s
  108. [108]
    Advanced Process Control Market industry Analysis 2025 to 2033
    Sep 16, 2025 · Advanced Process Control Market size was valued at USD 22.69 Billion in 2024 & is projected to reach USD 50.
  109. [109]
    Industrial Engineers : Occupational Outlook Handbook
    Employment of industrial engineers is projected to grow 11 percent from 2024 to 2034, much faster than the average for all occupations. About 25,200 openings ...
  110. [110]
    United States Advanced Process Control Market Size 2026 - LinkedIn
    Oct 31, 2025 · Additionally, a skills gap in managing advanced control systems can hinder implementation. Regulatory Landscape and Compliance Requirements.
  111. [111]
    Understand Advanced Process Control | AIChE
    Multivariable processes are controlled by a hierarchical structure of control layers. Field devices and regulatory controls manage individual variables, ...
  112. [112]
    Benefits of multivariable process control - Control Engineering
    Jan 18, 2023 · Multivariable processes have more than one input or output required for proper control. Examples include distillation columns, ...
  113. [113]
    Understanding APC limits and targets - Control Engineering
    Nov 29, 2021 · In APC, limits are acceptable operating windows, while targets are preferred operating points. Constraint control keeps variables within limits ...
  114. [114]
    Choose Sample Time and Horizons - MATLAB & Simulink
    The prediction horizon, p, is the number of future control intervals the MPC controller must evaluate by prediction when optimizing its MVs at control interval ...Sample Time · Duration · Prediction Horizon · Control Horizon
  115. [115]
    [PDF] Chapter 12
    The effects of disturbances are minimized, providing good disturbance rejection. 3. Rapid, smooth responses to set-point changes are obtained, that is, good set ...
  116. [116]
    Steady-State and Dynamic Simulation: What is the Difference
    Steady-state refers to a single point when the system is at equilibrium while dynamic refers to a trajectory where history matters.
  117. [117]
    Gain Scheduling - NI
    **Definition of Gain Scheduling in Process Control:**
  118. [118]
    Advanced Soft-Sensor Systems for Process Monitoring, Control ...
    Soft sensors are mathematical models used to forecast difficult-to-measure variables for real-time process monitoring, control, and optimization.
  119. [119]
    ISA-95 Series of Standards: Enterprise-Control System Integration
    ISA-95, also known as ANSI/ISA-95 or IEC 62264, is an international set of standards aimed at integrating logistics systems with manufacturing control systems.
  120. [120]
    Current NAMUR Recommendations (NE) and Worksheets (NA)
    Current NAMUR Recommendations (NE) and Worksheets (NA). Please click the titles in the table to sort the list by numbers, names, etc.Missing: guidelines | Show results with:guidelines
  121. [121]
    API RP 554-1 - Process Control Systems - Standards | GlobalSpec
    May 1, 2021 · This recommended practice (RP) addresses the processes required to successfully implement process control systems (PCSs) for oil and gas production, refinery, ...
  122. [122]
    ISA99, Industrial Automation&Control Sys Security- ISA
    The ISA99 committee establishes standards, recommended practices, technical reports, and related information that defines procedures for implementing ...
  123. [123]
    Navigating the 2024 Updates to ISA/IEC 62443 - Echelon Risk + Cyber
    May 21, 2025 · This article outlines the major 2024 updates to the ISA/IEC 62443 standards, focusing on changes to governance, supply chain security, ...
  124. [124]
    IEC 61511 Certification: Benefits, Process, and Requirements
    Reduced Insurance Premiums: Many insurance ... IEC 61511 certification and may offer reduced premiums to companies that can demonstrate compliance.
  125. [125]
    Standards-based integration of advanced process control and ...
    ISO 15926 is a standard for data modeling and interoperability that uses several Semantic Web technologies to provide a lifecycle description of oil, gas ...