Logistics engineering
Logistics engineering is a field of engineering dedicated to the scientific organization of the purchase, transport, storage, distribution, and warehousing of materials and finished goods.
Logistics is generally a cost centre service activity, but provides value via improved efficiency and customer satisfaction. It can quickly lose that value if the customer becomes dissatisfied. The end customer can include another process or work center inside of the manufacturing facility, a warehouse where items are stocked or the final customer who will use the product.
Another much more popular derivative and a complete usage of the logistic term which has appeared in recent years is the supply chain. The supply chain also looks at an efficient chaining of the supply / purchase and distribution sides of an organization. While Logistics looks at single echelons with the immediate supply and distribution linked up, supply chain looks at multiple echelons/stages, right from procurement of the raw materials to the final distribution of finished goods up to the customer. It is based on the basic premise that the supply and distribution activities if integrated with the manufacturing / logistic activities, can result in better profitability for the organization. The local minimum of total cost of the manufacturing operation is getting replaced by the global minimum of total cost of the whole chain, resulting in better profitability for the chain members and hence lower costs for the products.
Logistics engineering as a discipline is also a very important aspect of systems engineering that includes reliability engineering. It is the science and process whereby reliability, maintainability, and availability are designed into products or systems. It includes the supply and physical distribution considerations above as well as more fundamental engineering considerations. For example, if we want to produce a system that is 95% reliable (or improve a system to achieve 95% reliability), a logistics engineer understands that total system reliability can be no greater than the least reliable subsystem or component. Therefore our logistics engineer must consider the reliability of all subcomponents or subsystems and modify system design accordingly. If a subsystem is only 50% reliable, one can concentrate on improving the reliability of that subsystem, design in multiple subsystems in parallel (5 in this case would achieve approximately 97% reliability of that subsystem), purchase and store spare subsystems for rapid change out, establish repair capability that would get a failed subsystem back in operation in the required amount of time, and/or choose any combination of those approaches to achieve the optimal cost vs. reliability solution. Then the engineer moves onto the next subsystem.
Logistics engineers work with complex mathematical models that consider elements such as mean time between failures (MTBF), mean time to failure (MTTF), mean time to repair (MTTR), failure mode and effects analysis (FMEA), statistical distributions, queueing theory, and a host of other considerations. Obviously, logistics engineering is a complex science that considers trade-offs in component/system design, repair capability, training, spares inventory, demand history, storage and distribution points, transportation methods, etc., to ensure the "thing" is where it's needed, when it's needed, and operating the way it's needed all at an acceptable cost.
Performance metrics
Different performance metrics (measures of performance) are used to examine the efficiency of an organization's logistics. The most popular and widely used performance metric is the landed cost. The landed cost is the total cost of purchasing, transporting, warehousing and distributing raw materials, semi-finished and finished goods.
Another performance metric equally important is the end customer fill rate. It is the percentage of customer demand which is satisfied immediately off-the-shelf (from on-site inventory). An alternative to fill rate, is system availability.
In recent years, the United States Department of Defense (DoD) has advocated the use of performance-based logistics (PBL) contracts to manage costs for support of weapon systems.
Education
Many top universities offer Logistics Engineering programs at undergraduate and graduate levels. These programs generally combine strategy, operations, facility design, technology and management. The following institutions provide Logistics Engineering programs around the world:
- Ohio State University – Master of Business Logistics Engineering [1]
- University of Hong Kong – Bachelor of Engineering in Logistics Engineering and Supply Chain Management[2]
- Hong Kong Polytechnic University – Bachelor of Science in Logistics Engineering and Management
- Dalian Maritime University – Masters Program in Logistics Engineering & Management
- Shanghai Maritime University – Bachelors & Doctoral Programs in Logistics Engineering
- South China University of Technology – Masters and Ph.d. Programs in Logistics Engineering and Management
- Hong Kong University of Science and Technology – Bachelor of Engineering in Logistics Management and Engineering
- Széchenyi István University – Masters and Ph.d. Programs in Logistics Engineering and Management
- JAMK University of Applied Sciences – Bachelor of Engineering in Logistics Engineering[3]
- Taiyuan University of Science and Technology – Bachelor of Engineering in Logistics Engineering
See also
- Physical distribution, not to be confused with a statistical distribution
- Document automation
- Industrial engineering
- logistics
- Liquid logistics
- Logistics support analysis
- Operations research
- Supply chain management
- Transportation management system
- Warehouse management system
- Fleet management software
- Associations
References
External links
- The Council of Logistics Engineering Professionals
- SOLE – The International Society of Logistics
- Definition of Landed Cost by 3CE