Supply Chain Models

These models and simulations have been tagged “Supply Chain”.

It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
12 months ago
Reengineering the Supply Chain Challenge from pg. 741 of Business Dynamics by Sterman
Reengineering the Supply Chain Challenge from pg. 741 of Business Dynamics by Sterman
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
12 months ago
 Multi-echelon inventory optimization (sounds like a complicated phrase!) looks at the way we are placing the inventory buffers in the supply chain. The traditional practice has been to compute the safety stock looking at the lead times and the standard deviation of the demand at each node of the su
Multi-echelon inventory optimization (sounds like a complicated phrase!) looks at the way we are placing the inventory buffers in the supply chain. The traditional practice has been to compute the safety stock looking at the lead times and the standard deviation of the demand at each node of the supply chain. The so called classical formula computes safety stock at each node as Safety Stock = Z value of the service level* standard deviation * square root (Lead time). Does it sound complicated? It is not. It is only saying, if you know how much of the variability is there from your average, keep some 'x' times of that variability so that you are well covered. It is just the maths in arriving at it that looks a bit daunting. 

While we all computed safety stock with the above formula and maintained it at each node of the supply chain, the recent theory says, you can do better than that when you see the whole chain holistically. 

Let us say your network is plant->stocking point-> Distributor-> Retailer. You can do the above safety stock computation for 95% service level at each of the nodes (classical way of doing it) or compute it holistically. This simulation is to demonstrate how multi-echelon provides better service level & lower inventory.  The network has only one stocking point/one distributor/one retailer and the same demand & variability propagates up the supply chain. For a mean demand of 100 and standard deviation of 30 and a lead time of 1, the stock at each node works out to be 149 units (cycle stock + safety stock) for a 95% service level. You can start with 149 units at each level as per the classical formula and see the product shortage. Then, reduce the safety stock at the stocking point and the distributor levels to see the impact on the service level. If it does not get impacted, it means, you can actually manage with lesser inventory than your classical calculations. 

That's what your multi-echelon inventory optimization calculations do. They reduce the inventory (compared to classical computations) without impacting your service levels. 

Hint: Try with the safety stocks at distributor (SS_Distributor) and stocking point (SS_Stocking Point) as 149 each. Check the number of stock outs in the simulation. Now, increase the safety stock at the upper node (SS_stocking point) slowly upto 160. Correspondingly keep decreasing the safety stock at the distributor (SS_Distributor). You will see that for the same #stock outs, by increasing a little inventory at the upper node, you can reduce more inventory at the lower node.
This model is based on the Beer game model from Martin Smits. The link is at the bottom of the description.  We extended the model with the following: - Cost per week for Factory, Distributor, Wholesaler, Retailer, and the Supply Chain  - Total cost for Factory, Distributor, Wholesaler, Retailer, an
This model is based on the Beer game model from Martin Smits. The link is at the bottom of the description. 
We extended the model with the following:
- Cost per week for Factory, Distributor, Wholesaler, Retailer, and the Supply Chain
- Total cost for Factory, Distributor, Wholesaler, Retailer, and the Supply Chain
- Added variable 'Inventory cost' this determines how much it cost to have one item in stock. This is the cost per item. This can be adjusted by the slider. 
- Added variable 'Backorder cost'  this determines how much it cost to have one item in backorder. This is the cost per item. This can be adjusted by the slider. 

https://insightmaker.com/insight/5ACHf6NAuB0GiipNFQqqVm/Beer-game-06-2017-B


Reengineering the Supply Chain Challenge from pg. 737 of Business Dynamics by Sterman
Reengineering the Supply Chain Challenge from pg. 737 of Business Dynamics by Sterman
8 months ago
Análisis de Datos y Simulación - S20
Análisis de Datos y Simulación - S20
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
Reengineering the Supply Chain Challenge from pg. 742 of Business Dynamics by Sterman
Reengineering the Supply Chain Challenge from pg. 742 of Business Dynamics by Sterman
4 months ago
Sterman, J. (2002). System Dynamics: systems thinking and modeling for a complex world.
Sterman, J. (2002). System Dynamics: systems thinking and modeling for a complex world.
5 months ago
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
12 months ago
Reengineering the Supply Chain Challenge from pg. 742 of Business Dynamics by Sterman
Reengineering the Supply Chain Challenge from pg. 742 of Business Dynamics by Sterman
4 months ago
Little's Law has various applications in Supply Chain. One of the application is the impact of Transit Times on In Transit Stocks and Total Stocks. This example demonstrates the relationship and the trade-off.
Little's Law has various applications in Supply Chain. One of the application is the impact of Transit Times on In Transit Stocks and Total Stocks. This example demonstrates the relationship and the trade-off.
last month
Reengineering the Supply Chain Challenge from pg. 742 of Business Dynamics by Sterman
Reengineering the Supply Chain Challenge from pg. 742 of Business Dynamics by Sterman
last month
Sterman, J. (2002). System Dynamics: systems thinking and modeling for a complex world.
Sterman, J. (2002). System Dynamics: systems thinking and modeling for a complex world.
5 months ago
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
It's a model simulating well-known beer game in supply chain management. In this supply chain simulation, there are four sub-levels namely order, policy, back-order and cost level which reflect different kind of factors in a supply chain.
last month
Little's Law has various applications in Supply Chain. One of the application is the impact of Transit Times on In Transit Stocks and Total Stocks. This example demonstrates the relationship and the trade-off.
Little's Law has various applications in Supply Chain. One of the application is the impact of Transit Times on In Transit Stocks and Total Stocks. This example demonstrates the relationship and the trade-off.
2 weeks ago