A generalized framework for optimization with risk

Zipperer, Damaris R, Brown, Andrew N

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Includes bibliographical references (pages 51-52). / Supply chains are facing increasingly volatile environments. Traditional optimization solutions provide a baseline understanding for industry applications, but cost-efficient solutions require a more robust approach. In high-tech capital construction projects, the construction of facilities requires complex project schedules, forecast well in advance. These forecasts are used to hire contract workers of varying contract lengths. In this thesis, we develop a risk integration methodology for contract workforce hiring optimization, and explore the capability of generalizing this approach for other supply chain problems. We first create a risk-integrated, optimal solution for workforce hiring that strategically covers areas of high risk density in construction forecasts. We first develop a program to simulate schedule variations based on the associated risk parameters of the scheduled tasks. Using the risk statistics resulting from these simulated schedules, we build new schedule requirements using two different methods. The first method addresses the gap from a daily perspective (bottom-up), while the second method addresses it from an overall schedule perspective (top-down). These new requirements are each overlaid on the input schedule, re-optimized, and excess daily coverage is trimmed. Using both methods, we found that higher levels of risk coverage were achieved at lower costs than the traditional solutions. In the studied case for Intel, a 23% additional risk coverage was generated for equivalent cost. Ultimately, the results show that strategic risk integration can result in a lower final cost, and a generalized framework for risk integration can be applied across many supply chain problems. / by Damaris R. Zipperer and Andrew N. Brown. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Effect of override size on forecast value add

Baker, Jeffrey A. (Jeffrey Arthur)

January 2018

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2018. / Cataloged from PDF version of thesis. / Includes bibliographical references (pages 65-68). / Business forecasting frequently combines quantitative time series techniques with qualitative expert opinion overrides to create a final consensus forecast. The objective of these overrides is to reduce forecast error, which enables safety stock reduction, customer service improvement, and manufacturing schedule stability. However, these overrides often fail to improve final forecast accuracy. Process mis-steps include small adjustments, adjustments to accurate statistical forecasts, and adjustments to match financial goals. At best, these overrides waste scare forecasting resources; at worst, they seriously impact business performance. This report offers a framework for identifying overrides that are likely to improve forecast accuracy. A new class of metrics, Dispersion-Scaled Overrides, was developed as an input to the framework. Other inputs included statistical forecast accuracy and auto-correlation. Classification techniques were used to identify whether an override was likely to create forecast value add. These techniques were found to be approximately 80% accurate in predicting success. This result suggests that using Dispersion-Scaled Overrides alongside common forecast accuracy metrics can reliably predict forecast value add. In turn, this can maximize the value that experts add to the business forecasting process. / by Jeffrey A. Baker. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Balancing product flow and synchronizing transportation

Andleigh, Priya, Bullock, Jeffrey Scott

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Includes bibliographical references (page 46). / Traditionally, production and transportation planning processes are managed separately in organizations. In such arrangements, order processing, load planning, and transportation scheduling are often done sequentially, which can be time consuming. Establishing a proactive steady flow of products between two nodes of a supply chain can bypass this order-plan-ship process. A steady flow of products can reduce transportation costs, increase cross-dock productivity, and reduce bullwhip effect upstream in the supply chain. This thesis develops an analytical framework to calculate this steady flow. The determination of eligible SKUs in this approach is performed by analyzing each SKU's historical and forecasted demand. The level of flow of each SKU is found using optimization with the objective of maximizing total savings. The methodology was tested on a plant-to-warehouse lane of a fast moving consumer goods company. The relationship between demand characteristics and optimal steady flow was studied. It was found that as the coefficient of variation decreases, the optimum steady flow moves closer to the mean of the non-zero demand and selected forecast over the model horizon. The methodology developed in the research, with its potential to reduce transportation cost and improve warehouse productivity, also presents the opportunity for new and innovative contract types with transportation providers. / by Priya Andleigh and Jeffrey Scott Bullock. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

SKU stratification methods in the consumer products industry / Stock Keeping Unit stratification methods in the consumer products industry

Jiang, Jiaxin, M. Eng. Massachusetts Institute of Technology, Steverson, Andrew

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Includes bibliographical references (page 40). / For companies with a large number of Stock Keeping Units (SKUs), it is extremely challenging, if not impossible, to manage the SKUs individually. Therefore, companies stratify SKUs into different classes and manage them by class. Currently, most companies identify SKU stratification based on the single factor of sales volume. This thesis explores more comprehensive analysis methods that can consider multiple SKU characteristics. We applied four methods (Single Factor Analysis, Dual-Matrix Analysis, Analytical Hierarchy Process, and Cluster Analysis) to the data of a company in the Consumer Packaged Goods industry. The factors considered were velocity, volatility, and profit margin. Our research indicates that the Analytical Hierarchy Process is the most viable and comprehensive method for stratifying SKUs. It allows for a flexible number of stratification factors, different importance levels of the factors, and user control of the number of classes and class sizes. By applying the Analytical Hierarchy Process to SKU stratification, companies will be able to carry the right inventory for the right SKUs, and improve customer service. / by Jiaxin Jiang and Andrew Steverson. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Simulated annealing algorithm for customer-centric location routing problem

Sohn, Eugene

January 2018

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2018. / Cataloged from PDF version of thesis. / Includes bibliographical references (pages 36-38). / In today's world, the e-commerce market is growing rapidly and becoming more competitive. While many players in the industry are attempting to get their share of pie, consumers are demanding faster deliveries and free shipping. This market growth and change in consumer behavior provides an exciting opportunity for companies to compete. In order to meet the new consumer demand, companies need to find better ways to deliver faster. Faster delivery times can be achieved by using an optimization model to plan delivery network and operations. Typically, this optimization model has been based on minimizing cost. However, in the current market, lowest cost is not necessarily the best driver of sales as the consumer culture enters an era of instant gratification. We argue that minimizing customer waiting time will bring better performance and win over market share by providing the quickest delivery service that is expected by the majority of consumers. We propose solving the location routing problem (LRP) aiming at minimizing customer waiting time with capacitated depots and vehicles. We take two approaches to solve this problem: mathematical model and heuristic algorithm. The mathematical model obtains the optimal solution, but it has a limitation on the size of the problem due to the NP-hardness of the LRP. Therefore, we introduce three different variations of Simulated Annealing (SA) algorithm to solve the Capacitated Latency Location Routing Problem (CLLRP). According to the comparison results on a popular benchmark test, one of the designed SAs, the Iterative Simulated Annealing algorithm, consistently provides the best combination of performance and computation time compared to the other two SAs. Therefore, this specific algorithm is further compared to the mathematical model on some problem instances. The comparison results demonstrate that the proposed algorithm performs competitively with the algorithms in the literature and the mathematical model. / by Eugene Sohn. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Impact of Drug Supply Chain Security Act on US pharmaceutical industry under decentralized information flow / Impact of DSCSA on United States pharmaceutical industry under decentralized information flow

Chang, Meng Ying, M. Eng. Massachusetts Institute of Technology./, Mohan, Raghavendran

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Includes bibliographical references (pages 46-47). / Drug counterfeiting is one of the major issues in the pharmaceutical industry across the world. These products could cause damages from ineffective treatments to death of patients. In order to fight against counterfeit drugs, the US government introduced Drug Supply Chain Security Act (DSCSA) mandating that all prescription drugs should be serialized. In addition, it mandates all pharmaceutical companies in the U.S. to provide tracking documents in response to a tracing request from FDA. While the act aims to improve drug security across the pharmaceutical industry, it poses a huge impact across the supply chain on both physical flow and information flow. This research evaluates the supply chain impact at an industry level. In this thesis, we evaluate the supply chain impact of Matryoshka model and Unit level model supported by a decentralized information flow. The thesis then evaluates the supply chain impact from three aspects, operational cost, IT infrastructure cost and capital investment. We reference Nabiyeva and Wu's research on centralized information flow model to conduct an exhaustive supply chain impact evaluation across the centralized model and the decentralized model. We conclude that among all these scenarios, unit level model under centralized information flow design bears the highest cost as it requires higher IT investment. On the other hand, the matryoshka model under decentralized information flow has a least supply chain impact from the cost perspective with low IT investment. / by Meng Ying Chang and Raghavendran Mohan. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Unlocking value in healthcare delivery channels

Zhang, Qi, M. Eng. Massachusetts Institute of Technology, Zhang, Muching

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Pharmaceutical supply chains are strictly regulated and work within unique constraints. Traditionally, innovator companies that are manufacturing the product have no direct interaction with the end users (treatment sites or individual patients); rather, over 90% of the orders go through intermediary wholesalers and distributors. However, with the introduction of new technologies for patients to manage their own health, federal regulations coming into effect on supplier responsibility for tracking drugs down to the user, and ever more pressure to cut costs and justify the high cost of medicine, manufacturers are actively reshaping their role in the pharmaceutical supply chain. Our objective in this thesis project was to support our Sponsor Company, a "Big Pharma" company with a wide range of medicines, to understand the key cost drivers of their current distribution channel and to explore the impact that a shift to an alternative distribution channel would have from a financial and operational standpoint. We first conducted a literature review to examine the existing research on costing methodologies, the impact of home delivery for clinical care and the drug distribution landscape. The literature shows some evidence that home delivery improves patient adherence and reduces inventory costs for suppliers. We then analyzed a targeted product's distribution network within the US by building a cost-to-serve model, which maps out the end-to-end service components conducted by the Sponsor Company. With this model we were able to test the supply chain impacts of volume change and a gradual shift to alternative distribution channels. The results of the model showed that for this particular product, working capital was a key cost driver, shifting volume to incorporate alternative distribution channels is highly beneficial; even some significant increases in operating costs are effectively neutralized by reductions in working capital for the entire channel. Aside from the model results, we recommend validating the assumptions and suggest that this 'bottom-up' costing model be extended for other products and geographies and used to inform the company's overall corporate strategic planning exercise. The cost-to-serve model framework can also be extended beyond the pharmaceutical industry to benefit consumer facing industries considering an omni-channel strategy. / by Qi Zhang and Muching Zhang. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Multi-echelon inventory modeling and supply redesign

Scott, Patrick (Patrick James), Xu, Boxi

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Includes bibliographical references (pages 46-49). / Many businesses struggle to optimize the flow of inventory and finished goods through existing plants and facilities. The integration of inventory costs, organizational processes, and changing business dynamics make it difficult to determine the optimal flow. This thesis examines the flow of raw materials and finished goods through the supply chain of a multi-national oilfield services company. We study a centralized inventory approach, assessed through heuristics, against the existing decentralized approach. Sensitivity analysis with regard to service level, and mode of transport strengthened the analysis. We show that demand aggregation and lead time are important factors in determining the upper echelon for a company's internal distribution model. Potential safety stock reduction is 2%, which is mainly due to the improved coordination for materials flowing to the final echelon in the supply chain. However, pipeline inventory increases by 12% as a result of longer lead times. / by Patrick Scott and Boxi Xu. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Improving shipping contracts with the use of emerging technologies

Harshvardhan, M. Eng. Massachusetts Institute of Technology

January 2018

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2018. / Cataloged from PDF version of thesis. "June 2018." / Includes bibliographical references (pages 79-80). / A set of contracts guides every movement of cargo from one point to another. In this thesis, we focus on the contract between the charterer and the ship-owner in the liquid bulk ocean-shipping market. The contracting process begins with the two parties finding each other suitable and ends with one party being compensated in compliance with the terms and conditions of the contract for meeting a set of considerations. The question we answer is how emerging technologies, primarily Blockchain, can be used to make this process more efficient in terms of time and cost. Our research shows that while there are a considerable cost and time savings possible for certain aspects of the contracting process, there are some problem areas, such as the negotiations, that cannot be solved with the help of existing technology. We also conclude that the proposed solution needs to offer an end-to-end contract and document management tool rather than just being an improvement for one particular step in the process. An industry-wide consortium led Blockchain-based solution has potential to find wide acceptability and impact in terms of increased efficiency. / by Harshvardhan. / M. Eng. in Supply Chain Management

Supply Chain Management Program.

Capacity planning under demand and manufacturing uncertainty for biologics

Luo, Sifo

January 2017

Thesis: M. Eng. in Supply Chain Management, Massachusetts Institute of Technology, Supply Chain Management Program, 2017. / Cataloged from PDF version of thesis. / Includes bibliographical references (page 58). / Due to the long lead times and complexity in drug development and approval processes, pharmaceutical companies use long range planning to plan their production for the next 10 years. Capacity planning is largely driven by the long-term demand and its forecast uncertainty. The impact of uncertainties at manufacturing level, such as factory productivity and production success rate, are not entirely taken into account since only the average values of each manufacturing parameter are used. Can we better allocate production among manufacturing facilities when both demand and manufacturing uncertainties are considered? In this thesis a stochastic optimization approach is followed to minimize the deviation from target capacity limit under different manufacturing and demand scenarios. The mixed integer linear model incorporates the impact of demand and manufacturing variation on production allocation among manufacturing facilities through Monte Carlo generated scenarios. The thesis model is designed in a way that can be used as a decision tool to perform robust capacity planning at the strategic level. / by Sifo Luo. / M. Eng. in Supply Chain Management

Supply Chain Management Program.