PT108176A - COMPUTER METHOD FOR INTEGRATED PROJECT PLANNING - Google Patents

Abstract

The present invention relates to a computer method, subdivided into a holistic unit (1,4), through which modulation of the object-oriented planning (2), the resource space (4) and the product space (1) ), IS CONFIGURED IN THE PROCESSING GOVERNANCE OF COMPLEX SYSTEMS, WITH CRITICAL BEVEL AXLES (5,6). HAVING HOLISM AS A BACKGROUND IN THE SYNCHRONIZED INTEGRATION OF ALL SUBSYSTEMS, WITH CERTAIN CRITICAL ENVIRONMENT (3), THE WASTE OF RESOURCES IS MINIMIZED. IT IS ON THE BASIS OF THE EXISTENCE OF MOBILE COMPUTATIONAL USE, WHICH IS GUARANTEED THE FUNCTIONAL OPERATION OF ALL PARTICIPANTS, THROUGH THE TRANSMISSION OF INTEGRATING SUBSYSTEMS, WHETHER BY WAY, OF THE ITERATIVE PANEL (9), WITH SWITCH (7), OR SIMPLY THROUGH A GRAPHIC DYNAMICS CONSTANTLY ESTABLISHED IN THE HOLISTIC DIAGRAM OF THE PLANNING, WHICH IS REPRESENTATIVE OF THE FRACTAL SYSTEM AS A WHOLE (8), HOWEVER HIS HANDLING IS EXERCISED ON ANY COMPUTER DEVICE, OF PREFERENCE OF TOUCH USE.

Description

Technical Field of the Invention:

One of the biggest dilemmas in planning and project management is resource allocation. The start and end times resulting from the application of reductionist techniques, such as the critical path method, imply an uncontrolled distribution of resource utilization over time.

Allocating a resource is one of the greatest challenges for the instrumentalist, becoming an even bigger problem, in case resources are limited. The holistic paradigm, which rests on the belief of the possibility of total knowledge, presupposes the total interdependence of the areas of knowledge, in this sense a universal unity of planning governance was established, which is presented in fig. 1.

In the sense of integration by object-oriented automation, which was established, the holistic space of the project was architected, fig. 3, based on the holistic diagram, Fig. 2, which represents a structure of information organization, capable of being manipulated according to general or partial objectives of the project, which may be optimized costs, optimized deadlines, imposition of resources, greater confidence of constructive quality, or any other criterion, which is not connected with the system, which is defined as an open system.

In this context, a computer program was developed, substantiating the computer method created for integrated project planning, which is executable in any programmatic device, fixed or mobile of simple understanding and handling, with the technological and computational support of the present time, taking into account integration of all parameters associated with the environment, economy and society. The previous technique: Project management, according to the concept developed in the middle of the last century, arose from different social aspects, often resorting to various support techniques. Taylor, one of the first celebrities to work on these scientific project management issues, demonstrated that any task could be broken down into a set of elementary activities, analyzed on the basis of scientific theories. Until then the only way to increase production was achieved by increasing the number of hours worked or the number of workers affected by these activities or by a radicalized technological change. Gantt has already studied in detail the order in which operations succeeded each other on the basis of a project which consisted in the construction of a ship. This author would eventually become a project management reference when, in 1903, he developed the Gantt Chart, one of the tools still in use today, due to its graphic simplicity in the representation of the various phases and activities of a project. It is a computable technique that allows us to find the best way to analyze the temporal location of all the activities, according to the temporal and sequential relations, taking into account the respective limitations of costs or available resources. Each activity is represented by an isolated bar, usually with a connection to the activities that have a sequential relationship with it and with its compliance being proportional to its duration.

It was with the appearance and vulgarization of the first computers that the use of increasingly complex methods came to try to fill the need to respond to increasingly demanding organizational structures.

In the mid-twentieth century, a new algorithm to support the governance of the various activities of each project, commonly known as the Critical Path Method or CPM (critical path method), appeared and, although reductionist, quickly became the computational method commonly used. The main difference between the fact that the CPM considers deterministic durations for the activities, and the PERT method, take into account the probabilistic factor always associated with the predicted for the durations, being contemplated three types of values: pessimistic, expectant and optimistic.

In the beginning of the computer world, when computers were still very ineffective, in solving relatively complex problems, the first methods developed were approximate methods, which still prevail today, of a very reductionist nature, which considered the decomposition of the project into several phases, which were analyzed separately and later overlapped, thus allowing to reduce the computational effort needed to solve the algorithms.

In order to deal with the increasing complexity of today's projects and to respond to the ever increasing demands of an ultracompetitive market over the years, a growing number of projects that seek to optimize and better represent the reality, in order to guarantee the success of the ventures. The CPM technique assumes, in a first iteration, the minimum costs in each activity, which are then compressed with a view to achieving it within the desired time, assuming a strictly linear relationship between time and cost for each activity.

Another planning technique, which was also developed in the United States shortly thereafter, is dictated by the line of balance method, hence the LOB designation. This technique, which is most advised when the units of the project has a repetitive character. At present, it is already spilled in several versions in an attempt to complement other techniques, such as PERT and CPM.

Although more and more approaches to reality have been attempted, by means of approximate methods, trying to improve certain aspects, namely, the relation between time and costs of the projects, focused only on the critical activities of the project. Since project management could be seen as a cycle, which begins in planning, then goes to execution, and finally to control implementation, and if necessary, with the implementation of corrective measures.

One of the biggest, if not the biggest, dilemma of planning and managing works is the allocation of resources. The start and end times resulting from the application of established techniques imply a distribution of resource use over time. Allocating a resource is the same as reserving it for a given activity in a given period of time, taking into account that the consumption must not be less than the availability of this resource, or the supply of the resource is greater than the demand and, in this In this case, resources are not the governing elements of the process. Or demand is greater than supply in some units of time and, in this situation, resource allocation problems can be classified into three main types, respectively: the problem of resource leveling, the problem of shortening projects, and the problem allocation of limited resources. The original Gantt Chart formulation among other network-based planning techniques that are time-based programming do not provide for a procedure that addresses these resource problems.

Description of the figures:

In order to provide a better interpretation of the invention of the computer method for integrated project planning, a description is given of the figures corresponding to the accompanying drawings, in which: Fig. 1 represents the establishment of the universal planning governance identity in a holistic perspective; - Figure 2 is the holistic diagram of the project; - Figure 3 is the holistic design space, which is represented at the base of the holistic design diagram; - Figure 4 is the typification of the holistic diagram for the elementary resource types Rl and R2; - Figure 5 is the typification of the holistic diagram for the elementary resource types R3 and R11,2; Figure 6 is the representation panel of the global view of the processes in the holistic design diagram, where the black bars indicate unavailability; Figure 7 is an example of the iteration between two levels of abstraction, Nj and Nj + 1, for j + l <k; - Figure 8 is the representation of the temporal and conditional limitation of the modification of the state of an element; 9 is the representation of an end-to-end connection between two elements (A) and (B); - fig.10 is the representation of the criticality parameters of a given system; Fig. 11 is the production control guided by the holistic diagram, with production delay being verified; Figure 12 is the production control based on the holistic diagram, verifying unpaid resources expenditures; - Figure 13 is the representation of resource allocation, based on the holistic diagram; - Fig. 14 is the holistic diagram of a project subsystem; - Figure 15 is the holistic planning diagram, which is a computer manipulation tool; Fig. 16 is the graphical representation typified in line for allocation of individual preference of a particular type of resource; - Fig. 17 is the constructive panel with iterative capability, which enables the manipulation of digraphs; - Fig. 18 is the general flowchart of the computer method for integrated project planning.

DETAILED DESCRIPTION OF THE INVENTION:

Based on the holistic design diagram, fig. 2, a governance panel consisting of five chronologically interconnected spaces, whose interdependencies are portrayed in the flow chart of Fig. 18, is defined and should be governed exclusively by those individuals, where their credentials are eligible for effects. The integration of these spaces leads to a holistic span of governance that has been labeled as holistic planning space, fig.3. This space is constituted by five subspaces and presents itself as a chronologically indecomposable support tool, in which each subspace depicts global interests in articulation with certain governmental aspects. These subspaces are in particular titled: by base planning, transformations, constraints, planning and the results. The first subspace is the one of the base planning, in which the first outline of the governmental process of what one has to produce, through the definition of an initial planning P °, is made at a procedural level, which is understood as basic. The second subspace is the one of transformations, with close connection to the base planning, it is in this larger space, that are realized reforms of logic and foundation with imputations coming from all authorized actors. The third subspace is that of constraints, or political decisions, in which the decision must be a reflex, but there are situations in which reason is not met and the trajectories assumed in the processes are not understood. The fourth subspace is that of planning, which helps to inform and equip those who try to control the processes of a valid instrument, if this space does not exist, all the space created would be of no use because it is in the walk that the legs feel. The fifth and last, subspace is that of the results, in which much information is filtered, which is generated when a simple parameter is modified in the process. It is in this subspace that the attempt to represent the reality is translated to all the observers and actors of the processes, and it should be divulged, in a systemic way, all that information processed.

It is reinforced here, the idea that these five subspaces are part of an undecipherable government space, of direct representation in a holistic diagram of the project, fig.2, with such distribution, that allows to develop the modeling, that can be approached by different stakeholders. The integration in the same space of the whole process of management and planning is thus a global instrumentalization of the possible portrait that one wishes to draw from the reality of the projects. It is in the substructures of the base planning and of the transformations that the process elements are governed in the temporal field of the resources to be spent or in the temporal field of the products to be manufactured. These elements will share the same time, thus mitigating the financial, labor, material and equipment waste, and so this approach will inevitably lead to an optimal temporal distribution of the associated basic elements, fig. clear and precise. The universal identity of planning governance, fig. 1, is established by the prior consideration of a changeable number j, which is the indexer of certain levels of abstraction Nj, which number should be the instrumentalist to consider, 2, where for each of these levels Nj is incorporated a set of Ej, i elements, which elements, which commutatively represent resources or products, as the sense of level-crossing is done, denoting itself as a "creative" sense, when the scanning is done from the level NI to level Nk, in which case the starting elements are considered products, and in the opposite sense the "aggregator" sense, when the scanning is done from level Nk to level NO and there the elements are seen as resources. Excluding this switching principle, the elements of the set corresponding to the first level Nl, which should only be considered as basic products and the elements of the last level Nk set, which represent the elementary resources or also referred to as word resources.

For a given project, which is intended for planning dominance and its integrated management, each element Ej, i of the set of dominant elements at the level Nj, (j> 0) is defined and labeled in a list, as well as, for each one, it is possible to create lists of parameters of interest and their dependencies among the remaining elements of the lower level, Nj + 1. The definition of all the elements El, i of the set of elements corresponding to the base level Nl gives sustainability to the first sketch of the desired planning (base planning), for which the first logical paths of the temporal flows between its elements are defined, taking taking into account innumerable factors, namely, technological, financial, glider experience, among others, creating at that level, for this purpose, the proper precedence links in a usual way to that of classical planning and possibly designing an estimate for the durations of the processes for the creation of these commodities.

Similarly, at the other levels Nj, (K> j> 1) the procedure is recreated for each Ej, i, (K> j> 1), considering the Ej + 1, i, up to j <K, at each level Nj, (K> j> 0), and for each Ej, i, we will be before a network oriented and plotted by a weighted digraph, Gj, i (Vj + 1, n, Ej + 1, l, s), where Vj + l, n, are the vertices, Ej + l, r, the arcs (some of the elements of level Nj + 1) and Wj + l, s are the amplitudes of each process (corresponding to the product), which, taking into account the direction of aggregating scanning and before the Gj, i, is switched from product to resource, as a holonic element.

In this process of creating the Gj, i, there will naturally occur the need to increment the Ej + 1, r, and successively up to Ek, r. As mentioned above, when it comes to the set of the last level, Nk of the universe considered for planning, its elements Ek, i, are designated elementary resources, better denoted now, by Rtipo, i, to which we can identify three types, fig.4 and fig.5. In this graphical representation of elementary resources, the three types of resources, Rl, R2, and R3, are configured: the first elementary resource of type RI is the pure utilization resource, which is something that is used in a given unit of time and is reused successively in the following units of time, having as a representation, a column that accompanies each unit of time, as an example, a team of labor or equipment; The second elementary resource of type R2 is the pure consumption resource, which is something that is consumed in a given unit of time and is not reused in the following units of time, whose representation is made by temporal diagonalization, as an example, are the materials of the cement type, diesel-type consumptions or a subcontract; and the third elementary resource of type R3 is the mixed or dependent resource, which mediates between consumption and its re-use, that is to say, although it is possible to reuse it, behaves as a consumption resource, and its representation trajectory represented by a diagonal and subsequently by a column that accompanies in each unit of time, or vice versa, as an example, of this type of resource, for example the formwork type equipment. In this type of elementary resource you can also configure the dependency between more than one resource, which taking into account its characteristics of non-dissociation, you can also consider its elementary pairing. Since these elementary resources constitute in themselves the so-called primitive constraints, which are vital elements for the system. In that the subspace of the restrictions, which is made, by intermediating between justified transformations with the design of the planning, whose existence is forced by human nature itself, refers, for example, to the folly of some leaders, whose decisions are of a purely political nature. In Fig. 3, an imposition of the distorted trajectory is sometimes represented, which sometimes overrides all the scenarios that were based on technological and management criteria, and when this happens, the decision is neither weighted nor dazzled. basis of sustainability. The subspace of planning, which is in addition to a valuable auxiliary tool for those who try to control the processes, also allows a retrospective view of the processed plans and their future prospects, demonstrating the non-linearity of the processes in an open system, which is dynamic and representative of the government of a complex project.

In the default configuration, fig.3, which will be used in the development of a given project, it was taken care that, in addition to displaying the planning processed at a certain moment with its successors and predecessors, the configuration is also articulated, either with restrictions imposed, or with the results produced. The control can be achieved integrally for a given time t, fig. 1, where it is found that the production level, right triangle, is below that programmed by the planning, thus leading to two gaps, one and a negative one, which concerns the delay in production, which is not acceptable if the objective is to respect the production deadline.

In figure 12, something similar happens, in this case, it is verified that the level of production is above the programmed, implying the appearance of two new clearances, one positive, regarding the execution time for the production and another negative effect on uncontrolled consumption of resources. The subspace of the results, fig.3, which is the last chronologically portrayed in the holistic space of planning, has the objective of clearly and unequivocally revealing all the information that has occurred for each eminent or already suffered procedural restructuring, with a reading connected and easy to interpret with planning. Monetary resource governance is one of the major pillars of process management, an elementary resource of the type Rl, so that in this new method, the treatment and monitoring of this resource is guaranteed in a very lucid way. This technique contemplates at any moment the possibility of associating a single cost center for each element representative of the Ni sets, thus dominating the allocation of this imperative elementary resource.

One result of interest, among others, is to be informed at any time, what is the true allocation of the nominative resources, fig.13. One of the current conditions for the existence of the elementary resources of Ek, i is that the project has a valid budget, so it is vital that this tool be able to govern beyond the logical understanding of the flows of nominative resources, that is:

If, in addition to the elements Ek, i of the level Nk, which are considered as the last elements understandable in the logic of the programming of interdependencies, a higher level (monetary level) Nk + 1 is still considered, in such a way that most elements of Ek, i, that is, the Rtipo, i, are elements, still defined by direct dependence of the elements currencies, Ek + 1, i dominant at the level Nk + 1, then we can on a basis of extension of the procedures of aggregation of elementary resources, make follow-up and integrated planning management through the hyper-resource elemental currency, better denoted by Mk + 1, i.

As mentioned above, taking into account the monetary level, Nk + 1, whose elements are the hyper-resources, Mk + 1, i, we are thus provided with the necessary basis for the quantification procedure and the control of the flows of costs in all the levels Nj and their respective elements Ej, i.

In the subspace of transformations, logical and grounded transformations are carried out with imputations originating from mobile or fixed devices, from all actors authorized by the database. For each level of iterativity, Ni, duly identified, its instrumentalists must have a global view of the transformations process, fig.6, which in addition to facilitating visual reading of interactions and precedence between elements for a given product, a clear view of its by-products as well as the resources associated with each of these by-products, and the availability of the product at each time level, or in the case of by-products, their temporal occupation. Given the need to compartmentalize some concepts, it is clarified some of the transformations that can occur between two levels of the universe of a given planning through the graphical exemplification of the iterations between two levels of abstraction, fig.7, since well, it is the elements of the sets Ni, such that i> le i + l <k, which will be commutatively referred to as resources or products of a given process, taking into account that for a given planning level the set Nj is composed of three elements, Nj = {A, B, C}, as well as for a level, Nj + 1, immediately below the elements, constituents are A1 *, A2 *, A3 *, A4 *, Bl *, B2 *, Cl *, C2 *, C3 * and C4 *, that is, the set Nj + 1 = {A1 *, A2 *, A3 *, A4 *, Bl *, B2 *

Cl *, C2 *, C3 *, C4 *).

Considering also that, starting from an initial planning, at the level Nj, there is a schedule, which translates into an initial period of 21 units of time to complete the desired process objective, in which a temporal distribution of (B) is completed, implying the start of the production process of (A), when (A) is produced in at least 9/13 parts of the whole thereof, then , (C) you can begin your production process.

Such chronology, which was initially drafted taking into account almost everything, of the procedural involvement in question, may undergo changes governed by the restrictions of lower levels. Let us see that considering the initial planning reflex at the Nj level to a higher level, Nj + 1, there is a distortion of that initial schedule, taking into account that chronological governance is also imposed by the resources / elements of the set Nj + 1, or simply its performance is imperative, guiding itself by any rule of decision making.

Soon after the improvement of the chronology of the elements in the level Nj + 1, as well as their re-evaluations of interdependencies between these same resources, it is verified that, in a process of return to the level Nj, the following: - Production (B) goes to start a unit of time in arrears compared to the originally planned but which will maintain its date for the completion of the production process, but there is a slight contraction in the initially planned production period; - The product (A) is broken down into three by-products A1, A2 and A3, while preserving its calendar period overall. There is an effective suspension in a unit of time of its production process; - As regards element (C), it is also found that it is decomposed into four by-products C1, C2, C3 and C4 and that, in addition to a marked change in its overall start and end dates, break in the overall production process, which may be advantageous or detrimental to the achievement of the pre-required objectives.

Thus, what levels of detail modify the chronology of the elements to the lower levels and which may or may not be instrumentalized by other participants in the universe of processes, not explicitly but that govern a part of the whole or interact on he, this modification, which is however, fig. 8, limited in most cases by time or by the condition of something. The movement of each product, that is to say resource, is conditioned by two corridors, a conditional and a temporal corridor. The temporal corridor is marked by two conditional limits, upper and lower, and the conditional corridor is delimited by two limits of criticality. The primary condition for the realization of any element Ej, i (j <k) is characterized for any element E'j, i aggregate belonging to a given level Nj, where any FGRt, s, f, (defined at the front) concerned, is made available and is fit to be consumed or to be used in its due time of consumption and, or uses, respectively. It should be noted that in any open system it is allowed to establish any other priority rules, which in no way obeys the logic followed by the processes, thus assuming other criteria not controlled by the procedural reason, but by the operational decision .

In order to create priorities for the enjoyment of a target resource, among the three types of elementary resources defined, type Rl, R2 and R3, where type RI is the pure utilization resource, type R2 is the resource of and type R3 is the mixed or dependent resource, the one that can be configured most urgently in the matter of priorities, is the IR type of pure utilization, since its impatient wait behavior leads to a zero waiting condition, its Allocation will be more pertinent to other types of resources, as we will be talking about, for example, labor, whose costs inherent to such wastes are generally of greater magnitude than is found in R2 and R3 resources. It should be noted that resources of type Rl, pure utilization, are generally considered as dominant, since they reaffirm themselves as aggregators of the other types of resources, and for that reason also each of their temporal fragments, can be considered of born critics, and within this group, degrees of importance may be established in their use. Resources of type R2, pure consumption and R3, mixed or dependent, are considered as aggregators, and become potential aggregates, when some direct dependence is created on at least one fragment of a given resource of type Rl. The risk that some fragment of consumption of these resources becomes critical should be constantly taken into account. In this context, this scenario for creating priorities for the enjoyment of a target resource is characterized in that a satisfaction of a given fragment FGRt, s, f of the subtype resource, Rl, s is used in a given word resource RNl, s, n, in order to be able to be used again in another time fragment FGR, t, s, f + 1, preferably in the same physical space of operation and in continuous mode of enjoyment; that is, without null fragments being interposed between them. In that, the set of fragments, which can first enjoy the use of the resource Rl, t, is the one belonging to the FGR, t, s, f with a greater degree of criticality, that is, there will be a dispute for such enjoyment of the resource, by the pure fragments of the base level, or by fragments of the level that flank or intersect other levels. However, for a given level Nj, it will be expected that the fragments considered critical at this level are preferred for the effective and early enjoyment of that resource, thus concluding that the priorities to be established in fragments of that level Nk for the enjoy the target resource, is conditioned by the order of criticality (defined at the front) of these fragments at the Nj level.

Given the valid hypothesis, that at the level, Nk-1, all Ek, i, that is, the corresponding fragments FGR, 1, s, f (where type = 1) are critical. In the aggregate sense, in each successive level visited, some fragments will have use clearances and thus will no longer be critical. At the level, NO, the FGk, i, v (Rtipo, i) fragments that are still critical should be the first ones to be allocated and successively, taking into account the tables appropriate to the intended studies for application of algorithm dedicated to allocation, in that for each Ek-1, and its corresponding digraph G'k-2, i, there exists a univocal relationship with its aggregation fragments, FGR, t, s, that for each fragment FGR, t, s, f , due to the holism of the system, is replaced in its list, LRt, s, according to mutant criteria of preferential positioning of use. The correspondence of a given set of fragments contained in FGR, t, s, f and the available consecutive word resource RNt, s, n °, is done by applying an algorithm {FGk, i, v (Rtype, g), LRtype , g (RNtype, g, f °)} -> · Te (RNtype, g, f °), which is intended to be efficient in allocating a given word resource RNt, s, n, resulting in an optimization of its use, namely maximizing the continuous flow of use to a particular physical space of its domain. In which the presentation of the allocation in reference, is made through a nominative allocation table, Te (RNt, s, n).

Considering the set of elementary resources Nk for a given planning universe, in which its elements are designated elementary resources, as already mentioned in three types of resources Rl, R2 and R3, it is verified that after the verification of the need to use one of these resources over time, the next phase is the verification of their availability and possible orderly choice of possible hypotheses. In this procedure of choice, a discussion in the field of optimization will inevitably be reached in order to achieve a certain objective. This discussion may involve the application of usual tools of linear programming for the creation of tables Te (RNtype, g, f °), where index (e) characterizes the type of optimization that is intended. It is possible to list the following possible types of tables, which can be applied generically to the resources or in part: maximization of production, shorter term (e = l), overall cost (e = 2), availability of funds (e = 3), imposition of resources (e = 4), by greater confidence of constructive quality, (e = 5) and others (e = 6).

Within the scope of this invention, there is a clarification of a type of clearance, which has been identified and is referred to as the intrinsic clearance of an element. Being its conceptual survey carried out through its contextualization of a small example, fig. (A) and (B) in the product perspective and their respective associated resources (A ') and (B'), reflections of (A) and (B) resources. Considering that for a given abstraction level Ni, there is a connection from (A) to (B) of the end-end type, that is, when (A) is finished being produced, (B) starts its production process. The question that arises is this: Is this connection, end-start, rigid? Does the beginning of (B) effectively be conditioned by the end of (A), or is there still some slack? When it does, it may be very useful! Let's see:

If (A) and (B) are two elements connected at the base, with an end-to-end connection, then their associated resources, which will be products at a higher planning level, will in principle also have the same type of connection . However, it turns out that these resources may not assume the same identity inheritance. Sometimes we may have resources associated with the same products, but they may be out of time, or they may be consumed by other differentiated resources whose temporal association is different in (A) and (B).

There is, therefore, an important need to have an algorithm capable of revealing this possibility, which is implied in this computer method described here. Consider the product (B) pretension, sliding temporarily, for each unit of time displaced, it is necessary to verify if the resources (A'i) associated with (A), which were also programmed to perform (B), will be or not available (freed); taking into account: - Br * is a set of resources, which are common to the resources (Air and Br) needed to produce and produce their products. That is, Br * = Ar Π Br - For each time step, nT, it is verified whether Br * is contained in Ar ', if so, for that time the position of (B) is fixed. If possible fixation is not possible, that is, the connection initially considered between (A) and (B) is redundant. - In this case, the occurrence of some A * i, which may be reprogrammed for other times, since there is nothing to disturb the initial connection between the products (A) and (B), or another that is adjusted in the direction of the vector v.

After this process of fixing B in the time space of (A), we see the appearance of an intrinsic gap in the production of (B), which we can use at the initial planning level, if so desired by the ruler. The computer method for integrated project planning described is executed in a data processing system, whose database is also instrumented with suitable filters for extracting reports.

Claims (6)

Anspruch [en] 1 - Computer method for integrated project planning, characterized by a governance unit of processing, based on a holistic structure, constituted by levels of abstraction, Nj, (k-1> j> 0) inherent in the governmental scale considered appropriate , for the integrated planning and management of the project in question, as well as for all their respective sets of elements Ej, i (subsystems), constituents and established at those levels; the obtention of the holistic structure goes through the following phases: in the first phase of this procedure, taking into account the mastery of the glider is elaborated in the holistic diagram, or the digraphs panel, the first outline of the base planning, PO at the level, NO, with characterization of El, i, considering for this purpose a non-weighted digraph G0, i (V0, n, El, i), possibly being considered an estimate, so as to be more understandable for the production of each El , i, that is, no deterministic or probabilistic temporal value of processing the E2, p for each El, i; in a second phase, the instrumentalist, in the creative sense, scans the level Nl to the level Nk, which results in the minute construction, in each Nj, (j> 0) of all weighted digraphs, Gj, i (Vj + 1, n, Ej + 1, r, Wj + 1, s), where Vj + 1, n, are the vertices, Ej + 1, r, arcs (some of the elements of level j + 1) and the Wj + l, s, will be the amplitudes (to be determined in the aggregating direction) of each process of transformation of the Ej + 2, p (resources) in the Ej + l, corresponding product, element that, taking into account the direction of aggregate scanning and the Gj, i in question, is switched from product to resource, where in this first instance all Wj + l, s have not taken any parametric value; as an unambiguous result of the construction of each digraph, Gj, i (Vj + 1, n, Ej + 1, r, Wj + 1, s), representable in a holistic diagram, will obtain its respective defining matrices, namely adjacency matrix and the incidence matrix by reading the intrinsic code of each created system, code that is identified by an abstract data type, called holocode, Cj, i; and in the last step, in the scan aggregation direction, from the level Nk to Nl, where for each level Nj (0 <j <k) visited, and for each of the elements Ej, i, their corresponding digraphs, are rewritten in (F, t, s, f, W, t, s, f) at each aggregation level, and that at the limit of this procedure , where j = 0, we obtain G'0, i, which is the oriented digraph that translates the planning into the basis of the intended planning, ie it will be possible on this basis to obtain their adjacency, incidence and weighting matrices, on that basis, by reading and processing the now-added holocode; (V, N), consisting of only one initial vertex, f, referred to as the source, and only one final vertex, s, it is possible to obtain a resulting digraph G '(V'M *, A'N *), by algorithmic application, {G (VM, AN), AT (u, v), G * (V * P , A * Q)} -► G '(V' M *, A 'N *), where G * (V * P, A * Q) is also a digraph of a single initial vertex, f * and a single final vertex, s * (sink), such that G '(V'M *, A'N *) is constructed by the direct exchange of any edge AT of vertices (u, v), belonging to G, where u and u are respectively the apex of the tail and the vertex head of that edge, both belonging to G, and wherein said direct exchange, passes by: to match the vertices u and v of AT, belonging to G, f *) and (v -> s *), leading to a complete integration of the vertices V * P, and the are A * Q, belonging to G * in G, whose renamings remain topological, and that, these exchanges are made without loss of relative position in these sets, and that are remade in an integrated way in M * and N *, giving rise to definition of the resulting digraph G '(V'M *, A'N *), by means of the explicitation of its holocode and its manipulable representation in the holistic planning diagram. A computational method according to claim 1, characterized by a computational implementation achieved through the generic algorithm, referred to as a complex system manipulator, which is capable of managing the construction of the desired holistic structure by recursively applying several dedicated algorithms with (V * M *, A'N *), which is implemented by the algorithm, adds {G (VM, AN), AT (u, v), G * (V * P, A * Q) in the module for the creation of the aggregation order, in which all holocodes are dynamically obtained in all Nj, (k> j ^ 0) and for their representative elements, Ej, i, and in sequence, stored in base (Vj + 1, n, Ej + 1, r)} -> holocodigo (Gj, i (Vj + 1, n + 1, r)} -> holocode , Cj, i, representing the elements, Ej + 1, r, these holocodes being also called p otential holocodigos of aggregation of the fragments of nominative resources, FGR, t, s, f; followed by a first step and for each Ek-1, i, to show for each weighted digraph, G kl, i (Vk-1, m, Ek, i, Wk, i) or better denoted by G'k- (i), where Ek, i is replaced by FGR, t, s, f, since in the process of creating the Ek-1, the Ek, i can be used or consumed in f, temporal fragments of the target resource, Rt, s, fragments thereof, which are denoted by FGRt, s, f, and the amplitude, AMPt, s, f, the value [DFFt, s, f-DIFt, s, f], where DFFt, s, f, DIFt, s, f respectively represents the end date and the date of start of the use or consumption of the fragment, FGRt, s, f, followed for next step; in which for the initial imputation of the value of all amplitudes, AMPt, s, f of the FGRt, s, f, and respective DFFt, s, f, DIFt, s, f, a range of considerations is made, in which it is possible take decisions taking into account the type of resource, its subtype, as well as its nature of temporal expenditure of use or consumption, through consideration of income or charges to be established or already pre-established in income statements or costs; (Vk-2, i, Ek-1, i, Wk-1, i), which is representative of the element, Ek-2, i, belonging to this level is applied successively | k - 1, i | (Gk-2, i (Vk-2, i, Ek-1, i, Wk-1, i), FGRt, s, f (u, v), G ' (1), (2), (2), (2), (2), (3) and (4) t, s, f, whose realization of each G'j, i (Vj, m, FGR, t, s, f, W, t, s, f) at each aggregation level is therefore made by applying , i | successive times of the aggregate algorithm and for each G'j, i obtained, the maximum flow calculation is made and identifies the fragments FGRt, s, f that still remain critical, or became critical for the first time; the digraph G'0 is obtained, and for each of its fragments, FGRt, s, f, its dates DFF't, s, f, DIF't, s, and their critical elements are identified, and in addition, the parameters of criticality, order of criticality and degree of elemental criticality are identified, followed by the process of identification and optimization of the target resources, in which i mpg null values for the free and total clearances of each of the FGRt, s, f, for further holistic representation in the holistic planning diagram. 3. A computer method according to claims 1 and 2, characterized by the representative intrinsic code of a given element / system in reference (IDE), parent (IDEP), external (E), source (F), interior (I) or sinkhole (E), this code is an abstract data type, called a holocode, defined in the generic form: [IDE] IDEPAE <Ff_If, i; Si, s> Ss], where: IDE + IDEP Φ Ee + Ff Φ li + Ss and being, If, i Ui, j = li and Sf, s U Si, s = Ss, whose syntax is composed of five blocks, the first of which, which is the basis of code support and is labeled a root block, whose function is to support the remaining blocks, if any, and be sequenced as follows: root block (IDE; IDEP), in which the subsystem in question was created with the IDE register, until it finds the symbol (;), and then forward until some of the symbols (Λ) or (<) are found, the IDEP is found. the registration of the parent system, each of which is unique and of an immutable nature; (AEe), where the symbol (Λ) indicates to the algorithms that the subsystem designating (Ee) is an external system, and that there will be no precedence predicted by this element, to be added to the system; (Ff), where (<) indicates the algorithms, which follows a subsystem designating (Ff) and that this is one of the source systems, in which the occurrence of the symbol (_) shall indicate to the algorithms that the precedence of that source system consists of interior systems, designated by If, ie by sink systems, designated by Sf, s, successively separated by the symbol (;); (Ii) the block (#Ii_Ii, j, Si, s), where the symbol (#) indicates the algorithms, which follows a subsystem designating (li) and that this is one of the interior systems, ('), which indicates that the precedence of that internal system is constituted by internal systems designated by Ii, and by sink systems designated by Si, s, successively separated by the symbol (;); (Ss), where the symbol (>) indicates the following algorithms a subsystem designating (Ss) and which is one of the sink systems, also indicating that there will be no precedence to add to the system through of this element; only the following of the seven orderly combinations (Ci *) of the last four blocks may occur, so that the integrity of the system is valid: Cl * [(Io) AEe], C2 * [(Io) AEe + (2o) (4 °)> Ss = AEe <FfSf, s> Ss]; C3 * [(Io) AEe + (2o) Ss = AEe + F (i, S, S, S, S, S), C4 * [(Io) AEe + (2o) (4 °)> Ss = AEe <Ff_If, Sf, s # 1, Si, S> Ss], C5 * [(2o) (S), C 6 * [(2 o), F (s), S, S + (3) [(S)], S (S), S (S), S (S), S (S), Si (S) taking for this holocode the basic operations to operate in the constructive panel: that of creating or canceling events; the activation or deactivation of a complete or incomplete subsystem; the conversion of a given elementary subsystem into an incomplete subsystem; the neutralization of a given subsystem; the conversion of an incomplete subsystem into an elementary subsystem; the temporary blocking of a given subsystem; and the creation of a clone subsystem; and being also defined for this type of abstract data, three types of singular subsystems of operatory base, that were denominated by subsystems: invariants; neutralizers; and the complete direct production. 4 - Computer method according to claims 1 and 2, characterized by critical elements identified through critical approach parameters, order of criticality and degree of elemental criticality, where: criticality is the measurable characteristic of a given fragment temporal, FGR, t, s, f, of a particular nominative resource (f), belonging to a given subtype (s), of a type of resource (t), which indicates the level of holistic abstraction n = jk), in the aggregator sense, from which such temporal fragment is no longer critical; order of criticality, quantitative characteristic of a given element El, i, which indicates its appetite, to become or remain critical, whose value is the corresponding to the maximum criticality found by searching in all temporal fragments, FGR, t, s, f contained in that element; and the degree of criticality, which represents the measure of densification of the global criticality of a given planning Pi. 5 - Computer method according to claims 1, 2 and 4, characterized by the holistic diagram, to be a graphic representation of the fractal system, used as a modulation tool for project planning, by manipulating elements with isosceles triangular geometry, representative of subsystems for the understanding of the process dynamics of a project. It is possible to mark the project performance, by means of a relative measurement between the elapsed time, and the current degree of completion of a certain part of the project, compared to what was foreseen, and From this diagram, it is also possible to draw conclusions about its procedural performances in terms of cost and time, and its representation is achieved in the form of a double isoscele triangle, regardless of whether it corresponds to a resource, with a left upper triangular representation or of a product, whose representation is triangular lower right; the holistic diagram of planning is one of the possible applications of the holistic diagram in which all elements / subsystems interact with the project participants and is also used to illustrate the temporal arrangement of each element / subsystem that assumes the role alternately of resource or product, of a given process; the beacon time interval of each element being represented by colored homothetic triangles, arranged on a triangular homothetic base in relation to its reference elements, in which, for each isosceles triangular element, the length of its legs represents its temporal amplitude and its relative positioning is defined by the start and end dates of the process, while its relative positioning is also marked by a conditional corridor, imposed by the degree of relative criticality of each element that competes in the parent process, and its criticality defined in a color base between yellow and red. A data processing system characterized by comprising the program execution means required to perform each of the steps of the method claimed in claims 1 to 5.