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The Good Tech Companies - Mahesh Babu MG: Pioneering AI-Augmented Decision Quality in SAP Manufacturing Planning
Episode Date: August 14, 2025This story was originally published on HackerNoon at: https://hackernoon.com/mahesh-babu-mg-pioneering-ai-augmented-decision-quality-in-sap-manufacturing-planning. Mahes...h Babu MG’s AI co-pilot for SAP PP/DS boosts decision speed by 30% and cuts late orders by 12%, transforming manufacturing planning efficiency. Check more stories related to machine-learning at: https://hackernoon.com/c/machine-learning. You can also check exclusive content about #ai-in-manufacturing-planning, #sap-ppds-automation, #mahesh-babu-mg, #ai-co-pilot-sap-joule, #manufacturing-efficiency-ai, #hana-prototyping-sap, #late-order-reduction, #good-company, and more. This story was written by: @jonstojanjournalist. Learn more about this writer by checking @jonstojanjournalist's about page, and for more stories, please visit hackernoon.com. SAP manufacturing expert Mahesh Babu MG pioneered an AI co-pilot study for SAP PP/DS, showing 30% faster decisions, 20% higher sequence acceptance, and 12% fewer late orders. Leveraging HANA prototyping and targeted use cases, his research proves AI can automate routine alerts, enable “manage by exception,” and enhance manufacturing agility and on-time delivery.
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Mahesh Babu M.G. Pioneering I augmented decision quality in SAP Manufacturing Planning by John
Stoy and Journalist. The global manufacturing landscape is in a state of perpetual evolution,
confronted by the intricate dance of complex supply chains, fluctuating market demands,
and an unyielding pressure for hyper-efficiency. Traditional production planning systems,
long the bedrock of manufacturing operations, are increasingly strained by the need for real-time
adaptability and the capacity to manage a vast array of variables. This environment has cultivated a
critical demand for more intelligent and responsive planning paradigms. AI is emerging as a
profoundly transformative force, holding the promise of significantly enhancing decision-making
capabilities, optimizing the allocation of scarce resources, and streamlining operational
workflows across the manufacturing value chain. Indeed, traditional manufacturing paradigms often
grapple with challenges such as reliance on outdated machinery and processes, alongside high labor costs.
In contrast, AI-based planning systems can leverage sophisticated algorithms top-reform real-time data
analysis, predict demand shifts with greater accuracy, and dynamically adjust production schedules
to changing conditions. This transition represents not merely a technological upgrade but a fundamental
reshaping of how manufacturing excellence is pursued and achieved. At the vanguard of integrating
AI into the sophisticated domain of SAP manufacturing solutions is Mahesh Babu M.G, a distinguished
SAP supply chain manufacturing leader. His career, spanning over 19 years, reflects extensive
experience and profound expertise in SAP Manufacturing and Planning Solutions, encompassing
SAPE-C, SAPA, APO, and SAPS, 4 HANA. M.G has
demonstrated a deep understanding of manufacturing business processes and architectural design
across a multitude of industries. In his current capacity, he directs the SAP Premium Hub Co-Manufacturing
and PLM team, a role that underscores his leadership and considerable technical acumen.
A certified SAPS, 4 HANA Production Planning and Manufacturing Expert, MGI is also the acclaimed
author of two editions of the SAP Press Book, PPDDS with SAPS, 4 HANA, specifically,
the first edition, ISBN 978-1-493-2-18721, and THE 2nd edition.
These comprehensive guides on advanced planning and scheduling, covering critical areas like
master data, heuristics, the P-P-DS optimizer, and alert monitoring, have been catalogued
by the Library of Congress, cementing his statuses a preeminent authority in the field.
This unique combination of deep, practical SAP phosphorus mono-phosphide, D.E.
knowledge and forward-thinking research into AI
augmentation positions him as a vital link
between established enterprise systems
and the next wave of intelligent technologies.
This ensures his insights are both innovative
and readily applicable in real-world manufacturing contexts.
Combining his extensive background in SAP Phosphorus Monophosphide,
DS and his proficiency in HANA prototyping, MG conceptualized
and executed a significant behavioral study.
FIS research was designed to meticulously investigate the quality
of management decisions when operating under I augmented planning systems. The experiment featured a
conceptual AI co-pilot, modeled on the capabilities of SAP Jewel, integrated directly with
PPDDS functionalities. Within the structured environment of controlled workshops, participating planners
were tasked with comparing traditional heuristic-based outputs against AI-driven recommendations.
The outcomes of this experiment were compelling. Users augmented by the AI co-pilot were able to reach
scheduling decisions 30% faster, demonstrated a 20% higher acceptance rate for optimized sequences,
and, crucially, contributed to a 12% reduction in late orders. These statistically significant findings
robustly underscore how an AI assistant, such as a Jewel-like entity, can not only accelerate
the planning cycle but also materially enhance the quality of decisions made. The concept of
AI co-piles like SAP Jewel, which deliver contextual insights and automate tasks via natural language,
is central here. Although a standard Jule 4 P.P.D.S. was not available at the time of the study,
M.G's exploration of this paradigm through a conceptual model is particularly insightful.
The direct link between AI augmented decision quality and a 12% reduction in late orders
highlights a tangible business outcome, addressing a major pain point in manufacturing
related to customer satisfaction and operational costs. The insights gleaned from this
pioneering research have subsequently informed the content of MG's executive workshops and his
various publications. This has further solidified his reputation as an influential thought leader
in the rapidly advancing field of eye-driven manufacturing planning. MG's professional endeavors are
sharply focused on empowering manufacturing industries across North America to optimally harness
the capabilities of SAP supply chain manufacturing solutions. The ultimate aim is to
significantly improve their manufacturing planning and scheduling operations. The manufacturing
sector, especially in North America, is currently navigating a period of profound transformation,
largely propelled by widespread digitalization and an urgent need to build more resilient
and agile supply chains. The adoption of AI is widely recognized as a pivotal enabler in this
ongoing shift, with a substantial percentage of companies actively exploring or already
implementing AI technologies within their operations. MGs worked
directly confronts the practical challenges and unlocks the opportunities inherent in this
evolving industrial landscape. North America stands as a significant market for SAPSCM consulting
services, with numerous large manufacturing enterprises actively seeking specialized expertise to navigate
these changes. The conceptual nature of the SAP jewel in phosphorus monophosphide,
DS for MGs study points to a proactive stance, exploring AI's future potential even before standard
solutions are universally available. This is a critical approach for organizations aiming to stay ahead
of rapid technological advancements. Addressing traditional phosphorus mono-phosphide DS challenges with
eye-driven insights traditional production planning and detailed scheduling PPDS systems, while robust,
present inherent challenges that prompted an exploration into eye augmentation. M.G notes,
in traditional PPDS, the planners and schedulers really on automated background execution planning
and scheduling algorithms and the optimizers in PPDS to resolve planning and scheduling issues
related to the manufacturing of finished products and assemblies. However, not all such
planning and scheduling problems can be solved by the planning, scheduling algorithms and or the
optimizer. This gap often necessitates considerable manual intervention.
Planners dedicate significant time to sifting through alerts generated by interactive
transactions, identifying problems such as potential delays in salesorder deliveries due to
capacity unavailability on an assembly line or day's supply calculations falling below critical
thresholds. In these instances, planners manually reprioritize manufacturing orders or create
new ones to mitigate issues. Traditional production planning methodologies often struggle with
aspects like demand variability, a lack of real-time operational visibility, and inherent
inflexibility when faced with dynamic changes, all of which can exacerbate these manual
efforts. The objective of the conceptual study was shaped by these existing limitations sand
the emerging potential of AI. SAP Jewel is a co-pilot that understands the business semantics in the
connected cloud ERP system. For PPDS, there are no jewel capabilities available in the standard
solution as of now. So, this conceptual study focuses on the impact and benefits of a CO pilot,
chatbot enabled production planning and detailed scheduling, MG explains. The core use
case was to train an AI model using historical P.P.D.S. Alert data and THE corresponding
resolution actions taken by planners. This approach aimed to automate decision-making for the
more frequently observed and oftentimes consuming alerts within the alert monitor within the
PPS system and enhance metrics such as lead times and on-time delivery by meticulously
considering resource and component availability. However, its effectiveness often hinges on
heuristics and an alert monitor for managing exceptions, requiring planners to manually
intervene for alerts like day's supply calculation results in a value which is under a defined
threshold, or delay in delivery of a sales order driven by non-availability of capacity.
The vision for an AI co-pilot, capable of understanding business context and interacting
through natural language, directly addresses the manual burden associated with these common
alerts. This automation is anticipated to yield significant efficiency gains, a frequently
cited advantage of AI in the manufacturing sector. The studies focus on training in AI with
planner actions suggests a method to codify and scale the valuable tacit knowledge currently held
by experienced planners, potentially standardizing best practices and accelerating learning
for newer team members. This forward-looking exploration into co-pilot capabilities, even in the
absence of a standard PP-DS-Jule solution, provides a crucial perspective for organizations developing long-term
AI strategies. The pivotal role of HANA prototyping in designing AI augmented experiments the technical
architecture of MG behavioral experiment was significantly Shepedby his expertise in SAP HANA
prototyping. This proficiency was critical in establishing the foundational data structures necessary for
the study. M.G states HANA prototyping expertise is leveraged to create artifacts to capture the
details of the alerts and the actions taken by the planner and HANA models, which can be later
used to train the AI model. These artifacts, primarily HANA tables and views, were meticulously
designed to record the nuances of alerts generated within the PPDS system and the subsequent
corrective actions implemented by human planners. This data capture mechanism was event-driven,
ensuring that the information collected was a dynamic reflection of ongoing planning activities.
SAP HANA and its capabilities are well suited for such real-time data processing and analytics,
providing an ideal platform for capturing the dynamic event data essential for training a responsive
AI model. This aligns with the broader trend of leveraging ML and AI and SAP data analysis
to enhance real-time data analysis and facilitate predictive modeling. The practical application
of this HANA-based data capture is further illustrated by a specific scenario MG describes.
For example, for a level three assembly and manufacturing alerts are raised to notify the planner
on a delay. The planner resolved by executing a planning heuristics manually to regenerate plan,
as at this level there are planning very frequent failures. So this alert, along with the nature of the
product, location, combined with the actions taken, are captured using the HANA artifacts such as tables
and views updated based on events happening in the PPDS system. This detailed example underscores how
operational data, including specific alert types, contextual information about the product and location,
and the precise resolution steps undertaken by planners can be systematically collected and structured.
This process of creating HANA artifacts is a direct application of data preparation techniques
vital for effective machine learning model training and addresses the fundamental need for high
quality, comprehensive data to fuel robust AI performance.
Recent developments, such as data extraction for PPDS for SAPS, 4 HANA covering order details,
operations, and resource capacity, indicate the
industries move towards facilitating such data extraction for analytical purposes, similar to what
MG prototyped. The choice to focus the prototype on a level three assembly with very frequent
planning failures suggests a strategic selection of a high-impact area where AI could demonstrate
significant value by addressing a persistent pain point, a best practice in AI use case
identification. Furthermore, capturing not just alerts and actions but also the nature of the
product, location points to the creation of a rich, contextual data set. Such multidimensional data
is invaluable for training sophisticated AI modelscapable of understanding nuances beyond simple alert
classifications, leading to more accurate and contextually relevant eye-driven recommendations.
Crafting robust comparisons. Participant and scenario selection for AID-E-C-I-S-I-O-N-S-U-P-O-R-T
studies the design of the controlled workshops in M-G's study placed a strong emphasis on meticulous
participant and scenario selection to ensure a robust and meaningful comparison between traditional
human-driven planning decisions and those augmented by the conceptual AI co-pilot. Given the focused
nature of the study, specific choices were made to enhance the validity of the findings. MG clarifies this
by stating, as this study's scope is controlled and limited to two alert types, delay in order
fulfillment and over-utilization of capacities, the role selected were production supervisor for
finished goods and scheduling supervisor for the finished goods assembly lines. This deliberate
limitation of scope to two critical alert types and their corresponding relevant supervisory
roles allowed for a deeper, more controlled analysis of AI's impact on specific, yet crucial,
planning tasks. The selection of production supervisor for finished goods and scheduling supervisor
for the finished goods assembly lines as participant roles is a critical aspect of the experimental
design. These roles are directly and routinely involved in managing the types of alert,
under investigation, order fulfillment delays and capacity over-utilization.
This alignment ensures that the tasks presented during the workshop are ecologically valid,
meaning they closely mirror the real-world responsibilities and challenges faced by the participants.
The scenarios, centered on delay in order fulfillment and over-utilization of capacities,
address common and highly impactful problems in the manufacturing sector.
These issues have significant financial and operational ramifications, making their potential
mitigation through AI a compelling proposition for businesses. The use of controlled workshops is a
standard and effective methodology in behavioral science for comparing human performance under different
conditions, such as with and without AI decision support tools. The controlled nature of these
workshops helps to isolate the specific impact of the AI tool by minimizing the influence of extraneous
variables. Furthermore, for a robust comparison in studies evaluating human versus AI decision making,
scenarios must be designed in such a way that normative or optimal decisions can be objectively
identified. The alert types chosen by M.G typically have established better or worse resolution
pathways, allowing for a clear benchmark against which both human and AI augmented decisions can
be assessed. This careful pairing of specific alert types with relevant supervisory roles
enhances the realism of the experiment and, consequently, the applicability OFITS findings to actual
organizational structures and operational workflows. Measuring the impact, key metrics for evaluating
AI augmented planning decisions to rigorously evaluate the impact of the AI co-pilot, M.G prioritized a
set of key metrics focusing on decision speed, the quality of AI recommended action sequences,
and tangible operational outcomes like order timeliness. For measuring how quickly decisions could
be made with AI assistance, the study focused on the AI's responsiveness. M.G explains, the decision
is measured by the latency between the input prompt to the chatbot to the production of the
initial response. For example, for a prompt, how many high priority delayed order alerts are
present for the products I'm responsible for, the chatbot will use AI to understand the prompt
and trigger backend PPDS actions to generate alerts and respond with the number of alerts. This metric
directly quantifies the AI's ability to quickly process natural language queries, interact with the
underlying PPDS system and furnish planners with relevant information, a critical factor in
fast-paced manufacturing environments. Such responsiveness aligns with common AI assistant performance
measures. The quality of the AI's suggestions, specifically the acceptance of its proposed
action sequences, was assessed using a sophisticated measure. Contextual precision was used to measure
sequence acceptance to evaluate the action triggered by AI, comparing it with a manual sequence of
actions with the same prompt, MG states. This approach moves beyond a simple binary acceptance or
rejection of an AI's advice. Finally, order timeliness, a crucial manufacturing KPI often measured
by manufacturing KPIs, was a key outcome measure, reflected in the 12% reduction in late orders
reported in the study's angle. AI model validation techniques were applied to ensure the reliability
and accuracy of these metrics, including verifying chatbot responses for relevance and correctness.
The combination of these metrics, speed, quality of decision, action sequence, and operational outcome provides a holistic framework for evaluating the AI co-pilots effectiveness, ensuring that improvements in one area do not come at the expense of others.
The example prompt for decision speed also highlights the envisioned sophistication of the AI, capable of understanding natural language, user context, E, G, products I'm responsible for and triggering complex back-end system interactions.
This points towards the advanced capabilities of future planning assistance.
Unforeseen dynamics, planner interactions with eye suggestions versus tradition alluristics
the interaction between human planners and AI-driven decision support systems can often
reveal unexpected dynamics, and MG's study provided valuable insights in this regard.
One of the key observations centered on the profound influence of training data characteristics
on the AI's recommendations.
MG notes, with the jewel-like modeled chatbot, the quality of the quality of
and pattern of the training data hugely impacted the AI suggestions. In case of the capacity
overload cases, the training data consisted of scenarios where the orders that caused the
overload were rescheduled to the following week. This initial training regimen led to a specific,
albeit suboptimal, AI behavior. The paramount importance of training data quality is a well-established
principle in AI development. Deficiencies in data can lead to inaccurate predictions and flawed
decision-making. This reliance on observed patterns in the training data led to an interesting
scenario. M.G elaborates, but when capacity is still available within the same week,
the AI suggestion was to reschedule the order to the following week. This was mitigated by
introducing the capacity check as an action before proposing the rescheduling action in the training
data. This AI behavior, where it suggested a less optimal solution due to biases in its training,
exemplifies how AI models can learn unintended patterns if the training data isn't sufficiently
comprehensive or representative of all relevant decision-making logic. Such behavior, if
uncorrected, could negatively impact planner trust and lead topor operational decisions.
The mitigation strategy, enriching the training data to include an explicit capacity check,
reflects an iterative refinement process common in machine learning model development.
This experience highlights the challenge of embedding, common sense, or
implicit contextual rules that human planners intuitively apply, such as checking for more
immediate capacity availability before suggesting a longer deferral. AI models learn from patterns,
and if the training data does not fully encapsulate all desired decision logic, the AI will
exhibit these gaps. The ability to diagnose why the AI made a suboptimal suggestion,
due to training data patterns, was crucial for its correction, underscoring the value of transparency
and explainability in AI systems, which are vital for building user trust and enabling
effective human oversight. This iterative loop, where AI behavior influences potential
user interaction and the anticipation of negative interaction due to AI flaws, drives AI
refinement, which is critical for devloping practical and reliable AI decision support tools.
Tangible benefits. The operational and financial impact of reducing late ORDERS WITHA
the 12% reduction in late orders achieved in MG's conceptual study translate acinto significant and
multifaceted benefits for manufacturing organizations, spanning both operational efficiencies and
financial improvements. Traditional approaches to resolving order delays, especially those
stemming from shop floor disruptions, are often cumbersome and reactive. As MG describes,
in traditional planning scenarios, when a delay for a sales order is caused by shop floor
delays to manufacture the products at the scheduled duration, the nightly background runs will have
to be executed to schedule the backlog manufacturing orders to the future available capacity slots.
Then the backorder processing for sales orders will have to be executed to calculate the new
sales order promise dates. Furthermore, managing high-priority sales orders frequently demands
manual intervention by planners to reschedule other manufacturing orders, a time-consuming
and potentially error-prone process. The I augmented chatbot approach,
as explored in the study, offers a paradigm shift towards more agile and automated resolution.
MG highlights this contrast. With the chatbot-based approach,
the planner can simply ask the chatbot if any of the high-priority sales orders are
delayed and instruct to resolve the issue, which in turn leverages AI capabilities to trigger
corresponding rescheduling actions automatically. This capability directly addresses
a major source of inefficiency and cost. A 12% decrease in late orders represents a substantial
operational enhancement. Industrially, late deliveries and back orders are known to inflate
operational costs through expedited shipping and overtime, diminish customer satisfaction,
leading to reduced retention, and can even cause reputational damage. Consequently,
reducing late orders yields improved resource utilization and smoother production flows.
The financial implications are equally compelling, with potential for direct cost
savings, poor on time delivery can account for nearly 10% of costs, increased revenue from
enhanced customer loyalty, and healthier profit margins. Research from entities like the Aberdeen
group has shown a correlation between higher on-time delivery rates and improved project
profitability, with best-in-class firms significantly outperforming others in this metric.
Moreover, the automation of rescheduling for critical, high-priority orders not only lessens
the planner's direct workload, but, more importantly, ensures that strategic business
objectives, such as fulfilling key customer orders, a reed dressed with consistency and efficiency.
This minimizes the revenue risk associated with these vital accounts, showcasing how AI can safeguard
critical income streams and bolster important customer relationships by ensuring prioritized
and effective handling of urgent fulfillment challenges. The shift from reactive, batch-oriented
rescheduling to proactive, AI-driven resolution signifies a fundamental enhancement in
planning agility. This enables manufacturers to respond to disruptions more rapidly and thereby
minimize their cascading negative impacts across the supply chain. From experiment to expertise,
shaping executive workshops and thought L-E-A-D-R-S-H-I-T-A-I insights the compelling outcomes
from M-G's behavioral experiment, particularly the demonstrated gains in planner efficiency and
the enhancement of decision quality, have become foundational elements in shaping his executive
workshop sand influential writings, including his authoritative SAP press books. A central tenet
of his message to industry leaders and practitioners is the transformative potential of AI to
enable a, manage by exception, paradigm in manufacturing planning. As MG observes, a typical planner or
scheduler manages thousands of materials within their area of responsibilities, and they're spending
time to resolve the more common and trivial planning, capacity alerts in PPD stakes most of their time.
This extensive involvement in routine alert resolution often detracts from more strategic activities.
The introduction of eye-driven tools offers a clear pathway to alleviate Thespardin.
M.G. emphasizes the critical shift in focus that AI facilitates when their attention and focus
are needed for more complex alerts and managing the business. This eye-driven manufacturing planning
drives the businesses and their planning team towards the goal of, do not manage the system,
just manage the real exceptions. This philosophy,
where AI systems adeptly handle common and less critical alerts, empowers human planners to
dedicate their expertise and cognitive bandwidth to navigating genuinely complex scenarios,
managing significant business exceptions, and undertaking strategic planning initiatives.
The manage-by-exception principle is a well-regarded approach in operations management,
focusing attention on deviations that truly require expert intervention, and AI serves as a
powerful enabler for this. M.G.'s experimental results, such as the 30% faster decision-making and
12% reduction in late orders, provide concrete, data-backed evidence that transforms abstract
discussions about AI's potential into tangible demonstrations of value. This empirical grounding
is particularly persuasive in executive workshops, aiding leaders in their AI investment
decisions. Moreover, real-world thought leadership plays a crucial role in the manufacturing sector.
M.G.'s work, therefore, not only contributes to academic understanding but also serves as a practical
tool for advocacy and education, bridging the gap between AI's potential and executive
comprehension and buy-in. This redefinition of the planner's role, from a system operator to a
strategic problem solver, is a crucial aspect of AI integration, necessitating new skill sand
a shift in organizational mindset, topics likely central to MG's educational outreach.
Strategic adoption. Guiding organizations towards IA. Augmented SAP Phosphorus Monofosphide
D.S. Environmentments based on the findings from his research, M.G. provided strategic advice for
organizations contemplating the integration of IA. augmented planning systems within their existing
SAP Phosphorus Monofosphosphide DS landscapes. The initial, albeit limited, study demonstrated a
clear business benefit. As M.G states, with this limited study and experiment, the benefit to the
business was calculated at a 12% increase in-in-time fulfillment of customer orders.
This quantifiable improvement serves as a strong starting point and a testamento AI's potential.
Building on this, a primary recommendation is to initiate AI adoption by targeting high-impact
use cases where the return on investment IS evident and measurable.
This aligns with broader AI adoption strategies that advocate for starting with clear
business objectives and well-defined applications that offer tangible value.
M.G. suggests a specific avenue for valuable expansion. If further use cases, such as analyzing
the planning and optimizer job logs to identify planning and scheduling errors and leveraging
AI to automate the resolution of more common errors, will bring in a lot of value to the
businesses. This council points towards an incremental adoption strategy. Analyzing planning and
optimizer job logs is a strategically astute next step because these logs represent rich, structured
data sources readily available within SAP systems. Tapping into this existing data for AI
initiatives can lower the initial barrier to entry for further AI exploration, offering a pragmatic
path to scale AI benefits. Automating the resolution of common errors identified in these logs
reinforces the manage by exception philosophy. This not only frees up planners but also reduces
the workload on IT support and system administrators, allowing them to concentrate on more complex
systemic issues or enhancements, thereby broadening AI's efficiency impact beyond the planning
department. The initial success of the 12% improvement in on-time fulfillment acts as a crucial
proof of concept. The advice to tackle further use cases implies a strategy of demonstrating
tangible value early and then leveraging that success to champion and guide broader AI adoption
within the organization, a key principle for effective change management and strategic scaling.
Organizations should also ensure robust data quality and governance, as these are critical
prerequisites for any successful AI deployment within SAP environments.
While M.G's advice focuses on use case expansion, the underlying SAP context, including
SAP's strategy for scaling enterprise AI, remains an important consideration for long-term success.
The journey of integrating AI into manufacturing planning, as illuminated by the work of M.G,
reveals a pathway toward significantly enhanced operation AL capabilities.
His behavioral experiment, demonstrating that a conceptual AICO pilot for SAP Phosphorus Monophosphide,
DS can improve decision speed by 30% and reduce late orders B12% offers compelling evidence of AI's practical value.
More profoundly, these findings champion a shift in the planner's role towards a, managed by exception, model.
By automating the handling of routine alerts and common error resolution,
AI empowers skilled planners to dedicate their expertise to complex, strategic challenges that
truly require human ingenuity. This synergy between human intellect and artificial intelligence
is not a distant theoretical concept but an achievable reality, offering manufacturing industries,
particularly those in North America, leveraging SAP solutions, a route to greater efficiency,
improved agility, and a stronger competitive posture. The pioneering research and strategic insights
provided by experts like M.G. Erecrucial in navigating this transformation, ensuring that the
adoption of AI is impactful and aligned with the evolving demands of modern manufacturing.
The continued evolution of intelligent manufacturing planning will undoubtedly be shaped by this
increasing collaboration. Here, human oversight guides ice power to unlock new levels of
performance and innovation. Thank you for listening to this Hackernoon story, read by artificial
intelligence. Visit hackernoon.com to read, write, learn and publish.