Using TOC To Improve Project Management. ________________________________________Most projects, whether big or small, are undertaken either to create a new structure, such as a plant, an airport, an Olympic stadium, a bridge, a new product, etc.
, or to modify an existing structure, such as a plant expansion, adding a new production line, expanding a highway, etc. In most cases, the late completion of the project, such as finishing the Olympic stadium two weeks after the opening of the Olympics, or having a new airports’ opening delayed until after the elections, etc. , generally carries with it some significant negative ramifications for the project owner. At the same time, there are many cases where the early completion of the project will provide the project owner with significant positive ramifications, such as the market share gained by preempting the competitions’ launching of a new product, or the increase in sales achieved by bringing the plants productive capabilities on-line sooner, etc.Order now
Another important characteristic of most projects is that many of the resources performing the individual project tasks are sub-contracted resources, at least in terms of their relationship to the project manager. As sub-contracted resources, they are often committed to completing more than one project specific task during any given window of time. The issue of resource availability is often further complicated by the nature of the disturbances associated with most project specific tasks. As a result, most sub-contractors will only commit to completing a project specific task within a window of time and by a specific date, regardless of the fact, that the actual time required to complete the project specific task is generally much smaller than the allotted time window. Hence, the detail scheduling of the sub-contractors resources is generally something that most project managers have little or no direct control over. Lastly, most projects usually involve the investment/expenditure of one or more limited resources, such as money, peoples time, skills, equipment, etc.
As a result, most people try to maximize the return on these investments/expenditures, thus making the overall lead time, from start to finish, the key factor in almost every project. As with most decisions involving the use of limited resources, there is the need to consider trade-offs. Trade-offs that often appear as a conflict between the availability of the limited resource, which is usually money, and the overall project lead time from start to finish. As long as the decisions involve trade-offs which cannot be quantified into a single measurement, that is without a Final Judge, then the determination of "best" will always remain somewhat less than objective. Hence, the problem of "how to best evaluate" the myriad of proposed projects, particularly when all of them promise great benefits, also remains highly subjective.
Through the use of the TOC Thinking Processes it becomes apparent why the existing methods used to quantify such decisions, such as "Net-Present-Value" or "Net-Future-Value", did not really provide the sought after Final Judge. The main reason stems from the fact that the true investment value of a limited resource is not adequately represented by considering only the number of limited resource units to be invested. As with any limited resource, the real key to its value resides in its limited nature. Hence, determining the true value of any limited resource investment requires a quantification that is based on both the number of limited resource units (dollars) to be invested, and even more importantly, the number of time units (days) that these limited resource units (dollars) will not be available. This combined unit of measure, often referred to as "dollar-days", is used in a number of the TOC applications. In the TOC application to project management, the "dollar-day" unit of measure is used to quantify a projects’ limited resource investments as a function of time.
When all of the limited resource investments of a project are quantified in this way the end result is a single measurement that does, in fact, prove to be good Final Judge. This Final Judge is commonly referred to as ;Flush;. Having a Final Judge solves only part of the problem as it addresses only the quantification of limited resource investments but not the timing of these investments. The planned .