SE521572C2 - Procedure for configuring a resource distribution network - Google Patents

Abstract

The invention relates to configuration of resource distribution networks, such as electrical energy supply networks, where the resources are presumed to enter via at least one feeding point and exit at a plurality of client points. Geographical coordinate data for each feeding point and a respective amount of resources fed into the network are entered via a supply node list (1310). Correspondingly, geographical coordinate data for each client point and a respective estimated average amount of resources exiting at the client point is entered in the form of a user node list (1320). The node lists are processed such that a network configuration is generated where each client point is connected to a particular feeding point, either directly or via at least one other client point. The processing involves: a sectioning step (1340) through which a station area is formed around each feeding point, such that a specific client point falls within the station area whose associated feeding point is closest to the client point; a groupingstep (1350) through which at least one sub-network is formed within each station area according to a network segmenting algorithm; a clustering step (1370) through which the client points in each station area are associated with each other, such that two or more client points together form at least one client cluster within the sub network to which they belong; and connection steps (1370 and 1380) through which the client points within each client cluster are connected to a specific network station respective the network station in turn are connected to the feeding point(s). Finally, a description of the generated network configuration is delivered (1390).

Description

'lO 521 572 networks, such as telecommunications and data communication networks, it is very important that a specific information flow is directed to an intended recipient. However, all the aforementioned network types have a core of features in common. Namely, for each client point, there is always a minimum allowed amount of resources that should be granted at a certain service level (for example, defined in terms of kVA (kilovolt-amperes) or a maximum number of hours that the network is allowed to be out of service). Consequently, it can actually be a difficult task to design a large network that includes a very large number of client points.

The problem can be further complicated by the fact that the load generated by each client point varies over time.

Sometimes these variations substantially overlap in time, at least for a local majority of clients, while during other periods the load may be more separated from each other in time, so that the combined load from a number of client points becomes comparatively stable even though the load of the individual client points varies considerably.

Traditionally, the capacity of the types of resource distribution networks discussed above is adapted to the demand of already connected clients and possibly expected future clients. In most cases, therefore, the networks gradually grow from a relatively small initial size to a size required by the circumstances. Due to this situation, it is common to apply various ad hoc procedures and rules of thumb when designing networks. Even if a resulting network can meet the demand, the design often becomes deficient with respect to capacity utilization or investment efficiency. In retrospect, it is also generally very difficult to determine how a given network configured in this way could be improved with respect to capacity utilization and/or investment efficiency. 521 572 SUMMARY OF THE INVENTION It is therefore an object of the present invention to mitigate the above problems and thus provide an improved solution for the design of a resource distribution network. It is also an object of the invention to provide a basis for estimating the efficiency of an already existing resource distribution network.

According to one aspect of the invention, these objects are achieved by a method for configuring a resource distribution network in which resources are introduced via at least one input point and output at a plurality of client points. The proposed method comprises three principle steps in which input data is received, the input data is processed and a generated network configuration is presented, respectively. A supply node list is received by a first data input means. The supply node list contains a first set of coordinate data indicating a geographical position and a corresponding amount of resources that are input into the network for each of the at least one input point. In a similar manner, a user node list is received via a second data input means. The user node list contains a second set of coordinate data indicating for each client point a geographical position and a corresponding estimated average amount of resources that are output at the client point.

The supply node list and the user node list are then processed in a digital processor. The processing generates a network configuration in which each client point is connected to a particular input point, either directly or via at least one other client point. The processing in turn comprises the following steps. An initial partitioning step, by which a station area is formed around each input point so that a particular client point falls within the station area whose associated input point is closest to the client point. However, if the estimated sum of resources output at the client points associated with an input point exceeds the capacity of this point, a sufficiently large proportion of the client points are instead associated with 521,572 a second-closest input point. (Of course, the proportion of client points can only be associated with this second-closest input point if its capacity allows. Otherwise, the proportion of client points must be associated with a third-closest input point, and so on). A grouping step then generates at least one sub-network within each station area according to a network segmentation algorithm. A clustering step then associates each client point within the station area with each other so that two or more client points together form at least one client cluster within the sub-network to which they belong. A connection step then assigns each client cluster a respective network station. The client points within each client cluster are connected to their respective network stations and the network stations are in turn connected to the at least one input point, so that a particular network station is fed by a particular input point. A description of the network configuration is thereby obtained, which is delivered via a data output means.

An important advantage achieved with this procedure is that a network configuration is achieved that is very favorable from a geometric point of view. Although it will rarely be possible to build a physical network exactly according to this configuration, the result provides an excellent basis for an actual network design. In addition, the generated network configuration can be used in evaluating the properties of an existing network with the specified entry points and client points.

According to a preferred embodiment of this aspect of the invention, the grouping step comprises a district grouping sub-step. Here, each client point in each station area is linked up to the respective station area's input point so that a particular client point is linked to this input point either directly or via at least one other client point. The processing is advantageous because the client points are thereby connected to the input point via relatively short connections. This in turn guarantees a short average inter-connection length for the connections in the resulting network configuration.

According to another preferred embodiment of this aspect of the invention, the network segmentation algorithm includes the following steps. First, a preliminary subnetwork is generated that interconnects all the client points therein with comparably short connection lengths. Thereafter, a subnetwork is partitioned from the preliminary subnetwork whenever the connection length between two client points or between a client point and the input point exceeds a threshold distance. Thereafter, a group node list of the client points within each respective subnetwork is generated. The group node list specifies for each client point: (1) a radial distance to a geographic location that represents a balance point with respect to the geographic locations and estimated average amounts of resources output by the client points within the subnetwork, and (2) an angle measure that reflects an angular coordinate between the client point and a client point that is located at the nearest greater and/or nearest lesser degree of angle relative to the balance point. The group node list is arranged in increasing radial order such that the first entry corresponds to the client point located at the smallest radial distance from the balance point, a second entry corresponds to a client point located at a second smallest radial distance from the balance point, and so on.

This network segmentation algorithm is desirable, because the resulting subnetworks provide a well-founded basis for the distribution of so-called network stations, i.e. local service stations for a lower hierarchical level in the network, so that one (or if required several) network station(s) can be assigned to serve each subnetwork.

According to another preferred embodiment of this aspect of the invention, the clustering step comprises the following steps. A currently last client point in the group node list is added to be a first element in a client cluster and is then removed from the group node list. Then, a client point, which is located geographically closest to the client point corresponding to the first element, is added to the client cluster as a later element. However, the later element is added if and only if at least one boundary condition is met. Otherwise, the client cluster is defined as filled and the later element instead constitutes a first element in a new client cluster. The client points in the group node list continue to be added to new client clusters in a corresponding manner until all client points in the group node list have been added to a client cluster.

This clustering method is advantageous because it effectively groups the client points that are preferably served by one and the same service point together, that is, which should be interconnected to an immediately higher hierarchical level in the network.

According to another preferred embodiment of this aspect of the invention, it implies at least one boundary condition that: (a) a distance between two client points that are connected to each other must be less than the boundary distance and (b) that the sum of the estimated average amounts of resources output at the client points within a given client cluster must be less than a boundary amount. These boundary conditions are advantageous, since security and quality rules can thereby be met while taking into account various technical limitations in the network nodes.

According to another preferred embodiment of this aspect of the invention, the connection step comprises the following actions: (i) positioning the network station at a geographical position corresponding to a balance point with respect to geographical positions and estimated average amounts of resources output at the client points within the client cluster and (ii) allocating capacity to this network station that is sufficient with respect to the sum of the estimated average amounts of resources output at these client points.

These measures are of course advantageous because a suitable network station will thus be proposed at an optimal -21 572 geographical position. In practice, however, the network station may need to be positioned at a different location, for example due to topographical reasons.

According to another preferred embodiment of this aspect of the invention, it is assumed that a single network station is only allowed to have a certain maximum capacity. Therefore, an integer number of network stations is positioned at the balance point. This integer number is at least equal to the sum of the estimated average amounts of resources output at the client points within the client cluster divided by the maximum allowed capacity of a single network station. Thus, certain technical limitations of the network stations can be modeled with additional accuracy.

According to another preferred embodiment of this aspect of the invention, the client points are connected to the network station by performing the following operations: (i) connecting a first client point located closest to the network station and (ii) connecting the remaining client points in increasing radial order from the network station, such that each client point is connected either to an already connected client point and/or to the network station, which is geographically closest to this specific client point.

According to yet another preferred embodiment of this aspect of the invention, the network stations are connected to the at least one entry point by performing the following steps. First, a particular network station is associated with the entry point serving the station area within which the client points connected to the network station are located.

Then, for each input point, a network station node list is created of the network stations associated with the input point. The network station node list specifies for each network station: (1) a radial distance to the input point and (2) an angular measure corresponding to an angular coordinate between the network station and a network station located at the nearest greater and/or nearest lesser angular degree relative to the 521,572 input point. The network station node list is arranged in an increasing radial order, such that a first entry corresponds to the network station located at a minimum radial distance from the input point, a second entry represents a network station located at a second minimum radial distance from the input point, and so on. A corresponding topmost network station in the network station node list is connected to the input point either directly or via another network station depending on which is located geographically closest to this not yet connected network station. As soon as a network station has been connected, it is removed from the station node list, so that a network station at the next greater radial distance to the feed point instead becomes the top entry in the list. Network stations continue to be connected accordingly until the network station list is empty.

Client points whose estimated average resource requirements are in the order of the capacity of a typical network station are preferably treated as network stations. In this way, such client points are included at appropriate positions in the station node list as if they were network stations. This connection procedure is advantageous, since it effectively groups together those network stations (and thus also client points) that should preferably be served by the same entry point, i.e. be linked together to the next higher hierarchical level in the network.

According to another preferred embodiment of this aspect of the invention, the processing includes calculating a density measure corresponding to an average investment per client point required to build a physical network according to the generated network configuration. Preferably, the density measure expresses a required connection length per client point.

This provides a figure that is useful in evaluating the efficiency of an existing network. The ratio between the calculated average investment per client point and a corresponding actual investment can serve as such an efficiency indicator. 521 572 According to another aspect of the invention, these objects are achieved by a computer program, which is directly downloadable into the internal memory of a digital computer, which includes software for controlling the method described above when said program is run on a computer.

According to yet another aspect of the invention, these objects are achieved by a computer-readable medium having a program recorded thereon, which program is for causing a computer to perform the method described above.

In addition to serving as an exceptionally powerful network design tool, the invention provides an objective way to evaluate various characteristics of existing resource distribution networks. In particular, the invention makes it possible to measure the utility added to a given network by a particular operator. This is a very important metric, for example, for regulatory authorities when considering subsidies or when comparing price levels and other valuation-related quantities between different operators.

The invention described in this document proposes a strategy for configuring a network for distributing resources to a lowest hierarchical level, i.e. to end users. However, the invention is applicable at any higher or intermediate network level. For example, the invention can be used to design or evaluate national networks, regional networks, primary networks as well as secondary networks for distributing electrical energy.

In fact, the invention is applicable to any type of network where certain amounts of resources are to be allocated to each of a number of clients. Thus, in addition to networks intended for the distribution of electrical energy, water, sewage, gas and heat, respectively, and the allocation of resources for telecommunications and data traffic, the proposed solution can be applied to any other type of network that meets this condition.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will now be explained in more detail with the aid of preferred embodiments, which are shown by way of example, and with reference to the accompanying drawings.

Figure 1 Figure 2 Figure 3 shows a block diagram of a general system for configuring a resource distribution network according to the invention, station areas are formed around input points according to an embodiment of the invention, shows how the client points within the station areas are linked up to a relevant input point according to an embodiment of the invention, Figures 4a, b show schematically how subnetworks are divided from Figure 5 Figure 6a Figure 6b preliminary subnetworks within the station areas according to an embodiment of the invention, shows a preferred method for ranking client points based on their angular position relative to a balance point according to an embodiment of the invention, shows ranking lists according to an embodiment of the invention, where the client points in Figure 5 are arranged in ascending and descending order with respect to their angular positions in relation to the balance point, shows a group node list of the client points in Figure 5, where the client points are arranged in increasing radial order from the balance point, Figure 7a shows a first step, by which, according to an embodiment of the invention, a first client cluster is formed based on the group node list in Figure 6b, Figure 7b shows a second step, by which the first client cluster in Figure 7a is formed according to an embodiment of the invention, Figure 7c shows a process stage in the proposed clustering process, where a second client cluster is formed according to an embodiment of the invention, 8a-c show how the client points in Figure 7c are interconnected to a respective network station according to an embodiment of the invention, Figures Figure 9a shows a group of client points in a subnet, where the radial distances of the client points from a balance point are indicated, which balance point takes into account the geographical positions and estimated average amounts of resources output at the client points within the subnet, Figure 9b shows an angle measure which, according to an embodiment of the invention, reflects a relationship between the client points in Figure 9a and the balance point, Figure 9c shows a connection node list according to an embodiment of the invention, whereby the client points in Figure 9a are interconnected to a network station based on this, 10a, b shows the working principle of a proposed connection algorithm, Figures Figure 11 shows a graph of a cost function that can be applied in calculating a proposed cost measure, Figure 12 shows an exemplary graph of a network utilization rate as a function of the number of client points, and Figure 13 shows with the help of a flow diagram the general procedure for configuring a resource distribution network according to the invention.

DESCRIPTION OF PREFERRED EMBODIMENTS A block diagram of a general system for configuring a resource distribution network of the invention is shown in Figure 1. It is assumed here that resources are input via at least one input point and output at a plurality of client points. A supply node list 110a contains a first set of coordinate data indicating, for each of the at least one input points, a geographic location X1, Y1 and a respective amount of resources A1 being input into the network. Similarly, a user node list 110b contains a second set of coordinate data indicating, for each client point, a geographic location X1, yj and a respective estimated average amount of resources aj being output at the client point.

A first data input means 120a is adapted to receive the supply node list 110a and forward the data therein to a digital processor 130. A second data input means 120b is adapted to receive the user node list 110b and forward the data therein to the digital processor 130. The first and second data input means 120a and 120b are any computer device through which data can be entered manually or automatically for digital processing. Accordingly, a keyboard, a touch screen, a voice recognition interface, an OCR (Optical Character Recognition) scanner, a disk system, a CD-ROM (Compact Disc-Read Only Memory) drive, a hard disk drive and interfaces to communication networks correspond to examples of such data input means. Furthermore, one and the same input means 521 572 13 can be used for inputting both the supply node list 110a and the user node list 110b. In fact, it is preferable if the first and second data input means 120a and 120b are identical.

The digital processor 130 processes the supply node list 110a and the user node list 110b, so that a network configuration 150 is generated, where each client point is connected to a certain input point, either directly or via at least one other client point. The description of the generated network configuration 150 is delivered via a data output means 140, which, analogous to the data input means 120a and 120b, is constituted by any data device through which digital data can be displayed in a format adapted for human understanding.

Thus, the data output means 140 may be, for example, a text screen, a graphic display, or an acoustic interface.

Figure 2 shows schematically how station areas SA1, SA2, SA3 and SA4 are formed around the respective input points F1, F2, F3 and F4, using a proposed division procedure. This procedure implies that the station areas SA1-SA4 are primarily given such boundaries that a given client point (each illustrated by a star symbol) falls within the station area SA1-SA4 whose associated input point F1, F2, F3 or F4 is closest to the client point. However, if the sum of resources output at the client points, which are thus associated to an input point, is estimated to exceed the capacity of this point, a sufficiently large proportion of the client points are instead associated to a second closest input point.

Preferably, this proportion only includes client points that are located relatively close to a station area boundary. This allows relatively short distances between the client points and the input points F1-F4 to be obtained. This in turn is one of the requirements for an efficient network configuration.

Figure 3 shows how the client points within each of the station areas SA1_SA4 are linked up to the relevant input point F1-F4 using a so-called district grouping procedure. A station area SA4 is used here as an illustrative example.

The district grouping procedure involves determining a balance point CB4 taking into account the geographical positions and estimated average amounts of resources output at the client points f1-f10 within the station area SA4. According to an alternative embodiment of the invention, the balance point CB4 is not the actual balance point but is instead an assigned geographical position that can be selected taking into account topographical conditions. In any case, a first client point fö that is geographically closest to the balance point CB4 is identified and defined as "connected". Normally, the actual balance point C84 does not coincide with the position of the first client point fö. Then, a second client point fö that is the second closest to the balance point CB4 is linked up to the first client point fö. The second client point fö is thus also defined as "connected" via the link to the already connected first client point fö.

After this, a third client point f; is identified, which is geographically the third closest to the balance point C84, after which a first and a second distance are determined between this point f; and the first client point fö and the second client point fö, respectively. The shortest of the first and second distances determines to which of the first fö and the second fö client points the third client point f; is connected. Here, the first distance between the third client point f; and the first client point fö is shorter than the second distance between the third client point f; and the second client point fö. The third client point f; is then linked up to the first client point fö and is thus also defined as "connected".

The procedure then continues accordingly until the client points f1-f10 within the station area SA4 are interconnected to form a preliminary subnet N4. Corresponding 59.1 572 preliminary subnetworks Nj, NZ and N3 are formed in the other station areas SA1, SA2 and SA3 according to the same district grouping procedure.

Figure 4a shows the station areas SA1-SA4 in Figure 3 and their associated preliminary subnetworks N1-N4. A boundary distance Dm is defined that represents a maximum allowable distance between two points in the network (i.e. between two client points or between a client point and another kind of node, such as a network station). The boundary distance Dm can be determined based on safety and/or quality factors. For example, if the resource distribution network transports electrical energy, the boundary distance normally depends on a maximum acceptable tripping time for fuses and a maximum acceptable voltage drop (say 10%).

When water is transported instead, the limit distance Dm is normally based on a maximum permissible connection without intermediate safety valves and a minimum renewal rate. In the case of sewage, the corresponding conditions can be based on safety and hygiene considerations. Similarly, for gas or district heating, requirements in terms of flow, safety and/or energy losses determine the limit distance Dm.

In any case, a subnet is divided from a relatively preliminary subnet whenever a connection length between two network points exceeds the boundary distance Dm. In this example, a first preliminary subnet Nj in a first station area SAm is divided accordingly into two subnetworks N11 and N12 due to a connection between client points f12 and fm exceeding the boundary distance Dm, a second preliminary subnet N2 in a second station area SA; is similarly divided into new subnetworks N21 and N22 due to a connection between client points fm and f" exceeding the boundary distance Dm and a fourth preliminary subnetwork N4 in a fourth station area SA., is finally divided into two subnetworks N41 and N42 due to a connection between client points fa and f12 exceeding the boundary distance Dm. However, a third preliminary subnetwork N3 in a third station area SA3 remains intact, since there are no connections exceeding the boundary distance D11.. Thus, the subnetwork in this area becomes identical to the preliminary subnetwork Ng. The resulting subnetworks N11, N12, N21, N22, N3, N41 and N42 in the station areas SA1-SA4 are shown in Figure 4b.

Figure 5 shows a proposed method for ranking client points based on their angular position relative to a balance point CB4 according to an embodiment of the invention. The client points f1-f11 in the sub-network N41 within the fourth station area SA4 in Figure 4b are used here to illustrate the working principle of a proposed clustering method.

First, a balance point CB4 is determined taking into account the geographical positions and estimated average amounts of resources output at the client points f1-f11 within the subnetwork N41. A first client point f1 located at a longest radial distance r1 from the balance point CB4 is then identified and a first angular measure reflecting an angular coordinate to this client point f1 is recorded (i.e. the angular coordinate describes a relationship between the balance point CB4 and the first client point f1). After this, a client point fp is identified, which is closest to the first client point f1 in terms of a positive angular measure d* relative to the balance point CB4.

Then a client point f4 is identified which in turn is closest to this client point f3 in terms of the positive angle measure a* in relation to the balance point CB4 and so on until a last client point f2. Preferably, a corresponding linkage between the client points f1-f11 is also determined in terms of a negative angle measure ot' in relation to the balance point CB4. This listing can begin with the client point f2 and end with the client point f1.

Figure 6a shows two such ranking lists of client points f1-f11 which are arranged in ascending angular order of from f1 to f2 and in descending angular order or' from f2 to f1 with respect to their angular positions relative to the balance point CB4. Furthermore, both ranking lists are cyclic, so that the last element (f2 521 572 17 and fi respectively) further links to the first element (fi and f2 respectively).

Based on the radial distances ri of the client points fi-fii from the balance point CB4 and the ranking lists in Figure 6a, a group node list of the client points fi-fii within the subnetwork N4i is formed. Figure 6b shows such a group node list 610, where the client points are arranged in an order of increasing radius from the balance point CB4. A first entry in the list 610 thus represents the client point fi; which is located at a minimum radial distance from the balance point CB4, a second entry corresponds to a client point f5 which is located at a second minimum radial distance from the balance point CB4 and so on down to the client point fi which is located at the longest distance from the balance point CB4. The first entry in the group node list 610 (i.e. the client point f0) is then defined as representing an artificial balance point and is therefore instead referred to as fGCB. A column on the left specifies for each client point fi the identity of a client point that is located closest to the client point fi in terms of the negative angle measure d' and a column on the right specifies in a corresponding manner the identity of a client point that is located closest to the client point fi in terms of the positive angle measure oÜ.

Figure 7a shows how a first client cluster Ci is defined based on the group node list 610 in Figure 6b according to an embodiment of the invention. A currently last client point in the group node list 610, that is, the client point fi, is added as a first element in the first client cluster Ci. The client point fi is thereby also removed from the group node list 610. Consequently, the client point fiii now becomes the last client point in the group node list 610.

In accordance with a search procedure, which is described in detail below with reference to Figures 9a-c and 10a-d respectively, a client point f2 is identified as being positioned geographically closest to the client point fi. Therefore, the client point f2 is provisionally assigned to become a further later element in the first client cluster. In order to test whether the client point f2 satisfies a boundary condition, such as being sufficiently close to the client point f1 to actually be added to the first client cluster G1, a first temporary balance point CBTQ is determined taking into account the geographical positions and estimated average amounts of resources output at the client points f1 and f2. The client point f; is found to be located within a boundary distance Dm from the first temporary balance point CBTQ. Therefore, the client point f2 is assigned to be a further later element in the first client cluster C1 and is consequently also removed from the group node list 610. However, the client point fm remains the last client point in the group node list 610.

The clustering procedure now continues by testing whether the first client cluster G1 can be assigned any further client points. For this purpose, a new search is performed to find a client point that is located geographically next closest to the client point fj. This search finds a client point f3, which is not yet assigned to the first client cluster C1. In order to test whether the client point f3 is close enough to the already clustered client points f1 and f2, so that it can be assigned to the first client cluster C1, a second temporary balance point CBT123 is determined taking into account the geographical positions and estimated average amounts of resources output at the client points f1, f2 and f3. Here, the client point fa turns out to be located within the boundary distance Dm from the second temporary balance point CT123. Therefore, the client point f3 is assigned to be a further later element in the first client cluster C1 and is consequently also removed from the group node list 610. This is shown in Figure 7b. Preferably, the positions of the first temporary balance point CBTQ and the second temporary balance point CBtm depend on a non-linear summation of estimated average amounts of resources output at the client points f1 and f2 and f1, f2, and f3, respectively. This summation principle will be discussed in more detail below with reference to Figure 12. 521 572 19 In order to test whether any further client points can be included in the first client cluster, a further search is performed with respect to a not yet clustered client point, which at least satisfies the distance boundary condition. However, no client points are found that are located within the boundary distance Dm from the relevant balance point. Therefore, additional client points cannot be included in the first client cluster C1 and the first client cluster C1 is defined as "filled".

A second client cluster G2 is now created, in which the currently last client point in the group node list 610, i.e. the client point fm, is assigned to be a first element. Figure 7c illustrates the establishment of this client cluster G2. The addition of the client point fm to the second client cluster C2 makes the client point fg the last client point in the group node list 610. (Namely, that the client point f2 is already included in the first client cluster Cj.) A subsequent search identifies a client point fg as being located geographically closest to the client point fm. It is therefore tested whether this client point fg satisfies the boundary condition. A temporary balance point is therefore determined taking into account the geographical positions and estimated average amounts of resources output at the client points fm and fg. As mentioned earlier, the position of the temporary balance point preferably depends on a non-linear summation of the estimated average amounts of resources output at the client points fm and fg. Here it turns out that the client point fg is within the boundary distance Dm range from the temporary balance point and because of this the client point fg is assigned to the second client cluster Cz as a second element. However, no further client points are found that are located within the boundary distance Dm from a relevant temporary balance point with respect to the second client cluster G2. Consequently, the second client cluster G2 (including the client points fm and fg) is now also defined as "filled". 521 572 The procedure is then repeated with the third client cluster G3, where the client point f0 becomes the first element (since the client point fg has already been added to the second client cluster Cz) and so on, until all the client points f1-f11 in the fourth station area SA4 have been assigned to a client cluster. Figure 8a shows this stage of the clustering procedure, where a total of five client clusters have been created and a respective network station NS1-NS5 has been assigned to these clusters. As a further illustration, a column CJ- to the right of the group node list 610 in Figure 6b) and an adjacent sequence diagram illustrate how and in what order the five client clusters C1-C5 are formed.

According to a preferred embodiment of the invention, the clustering algorithm checks whether a client point assigned to a certain client cluster is the artificial balance point (i.e. in this example fBCB). If so, a new artificial balance point is selected as the client point closest to the balance point CB4 that is not yet assigned to a cluster. The procedure then continues as described above, but with this new artificial balance point as a reference. Alternatively, the clustering procedure can then continue according to a different principle. However, this will be described in more detail at the end of this description.

According to a preferred embodiment of the invention, a second boundary condition is defined which, together with the boundary distance Dm, implies that the sum of the estimated average amounts of resources output at the client points within a given client cluster must be less than a boundary amount. Therefore, it is also tested whether the client point can be added without exceeding this boundary amount before the client point is added to a given cluster. If this cannot be done, the cluster is defined in the same way as "filled". Normally, the boundary amount represents a maximum allowed amount of resources delivered via a single network resource such as a local substation in an electrical power supply network. Preferably, the second boundary condition is tested with respect to the non-linear summation function shown in Figure 12. 521 572 21 In Figure 8a, the network station NS1-NS5 in each client cluster C1-C5 is located at the balance point with respect to the geographical positions and estimated average amounts of resources output at the client points f1-f11 within the particular client cluster C1-C5. In addition, the network station N81-NS5 is assigned a capacity that is sufficient with respect to the sum of the estimated average amounts of resources output at these client points f1, f2, f3; fg, fw; fy, fe; f4, fn and f5, fe, respectively.

According to a preferred embodiment of the invention, an integer number (greater than 1) of network stations NS1-NS5, instead of just a single network station, are placed at the relevant balance point. Again, this may be necessary when a maximum allowed amount of resources delivered via a single network resource has been defined. The integer number is of course at least equal to the sum of the estimated average amounts of resources output at the client points within the client cluster in question divided by the maximum allowed capacity of a single network station.

Figure 8b shows a set of first-level networks resulting from an initial stage of the proposed connection procedure where each of the client points f1-f11 has been connected to a network station NS1-NS5 assigned to the client cluster C1-C5, to which the client points f1-f11 belong.

Figure 8c shows a resulting network after completion of a subsequent step in the connection procedure, where each of the network stations NS1-NS5 has in turn been interconnected and further connected to an entry point F., for the station area (SA4 in Figure 3), within which the client points f1-f11 are located.

The principles of the proposed connection procedure are largely the same as those of the district grouping and clustering procedures. One exception is of course that during the clustering procedure the algorithm finds the nearest client point.

However, it is not tested whether this point is connected. Nevertheless, the connection procedure will be discussed in detail below with reference to Figures 9a-c and 10a-b. Therefore, a higher level description of the procedure is given below.

Figure 9a shows a group of client points fa-fk in a subnetwork, where the radial distances of the client points fa-fk from a balance point CB are indicated by concentric circle segments. For illustration purposes, only some of the client points that determine the location of the balance point CB are shown in the figure. (This explains why the balance point CB appears to be offset compared to the shown client points fa-fk.) In any case, it is obvious from the figure that a client point fa is located geographically closest to the balance point CB and a client point fk is located furthest from the balance point CB.

Figure 9b again shows the group of client points fa-fk in Figure 9a.

Here, however, the angular relationships between the positions of the client points are indicated by means of a solid line, which connects the client points that are closest to each other with respect to the angular dimensions of, ot' in relation to the balance point CB. A client point fc is defined to have the smallest positive angular dimension oi* and a client point fd is defined to have the corresponding smallest negative angular dimension or".

According to one embodiment of the invention, the nodes in the resource distribution network (i.e., the client points, the network stations, and the feed points) are interconnected according to a connection algorithm. Based on the different radial distances of the client points fa-fk from the balance point CB (as shown in Figure 9a) and the angular relationships between the positions of the client points fa-fk (as shown in Figure 9b), a connection node list 910 is created. Figure 9c shows such a list, where the client points fa-fk are arranged in increasing radial distance from the balance point CB. The connection node list 910 thus starts with the client point fa and ends with the client point fk.

The connection node list 910 also contains information regarding the angular neighbors of each client point fa-fk as derived from the angular relationships shown in Figure 9b. The two boxes containing 521 572 23 dashed lines correspond to two of the client points that are not illustrated in Figures 9a and 9b, but which nevertheless affect the balance point CB position.

Referring to the client points fg-fk in Figure 9a and Figures 10a and b, the working principle of the connection algorithm according to an embodiment of the invention is illustrated. The client point fa which is located closest to a serving network station NS (i.e. the first entry in the client connection node list) is the first client point fa which connects to this network station NS.

The network station NS is preferably positioned where the balance point CB was determined to be located in Figure 9a. After the first client point fa has been connected, the remaining client points fg-fk are connected in increasing radial order from the network station NS. The rule given by the algorithm is that: "an unconnected client point shall be connected to another client point which is (i) geographically closest and (ii) is in turn already connected to the network station NS, either directly or via another client station".

Figure 10a shows a situation where client points fg, fb, fg, fg, fg and ff have already been connected to the network station NS in accordance with the algorithm and a client point fg is about to be connected.

The client point fg is located at a radial distance rg from the network station NS. Due to the proposed connection order, this means that all the connected client points fa-ff are located at a smaller radial distance (rg < rg < rg < rg < rg < rf < rg) from the network station NS than rg.

Thus, possible candidates for connection for the client point fg are found within a circle with a radius rg from the network station NS. The search for such possible client points begins with a scan in a positive angular direction a* from the client point fg in relation to the position of the network station NS and the search ends when an angle of = ofmgx = 600 is reached. Namely, at this angle the distance between the client point fg and a possible connectable client point is equal to the radius rg. Thus, if no connected client points have been found within this area, the client point fg may as well be connected directly to the network station NS. In this example, however, a first connectable client point fe was found at a distance dg_e s rg from the client point fg.

Relevant information regarding this first connectable candidate fe is therefore stored.

Then the scan for candidate client points is repeated, now however in a negative angle direction a' from the client point tg in relation to the position of the network station NS. Here too the search ends when an angle a' equal to ofmax is = 600 is reached. Within this area a second connection candidate client point ff was found at a distance dg_f < rg from the client point fg.

Thus, relevant information regarding the second connection candidate ff is also stored. The distances dg-f and dg_e are compared with each other and the client point fg is connected to the closest of the two encountered candidate client points, which in this example turns out to be the client point fe (since dg_e < dg_f). Consequently, the procedure continues according to these principles, until the client points fh-fk have also been connected.

In addition, according to the invention, the above-described connection algorithm is applied when the network stations are connected to the input stations. An exception, however, is that the input point cannot normally be located at a balance point in relation to the load generated by the network stations and their geographical positions. Instead, the position of the input point as given by the supply node list will be used. Although it is theoretically conceivable that the position of the input points may also change at this stage.

According to a preferred embodiment of the invention, the network stations are interconnected and in turn connected to at least one entry point along the following lines. A particular network station is associated with the entry point which serves as the station area within which the network station is located.

In other words, the client points determine to which entry point a particular network station should be associated, so that the 521,572 network station is associated with the same entry point as the client points within that station area.

A network station node list is then formed of the network stations associated with the entry point in question.

For each network station, this list specifies: a radial distance to the entry point and an angular measure reflecting an angular coordinate between the network station and a network station located at the next greater and/or next lesser angular degrees relative to the entry point. This list is arranged in increasing radial order, such that a first entry represents the network station located at a minimum radial distance from the entry point, a second entry represents a network station located at a second minimum radial distance from the entry point, and so on. A currently topmost network station in the list is connected to the entry point either directly or via another network station depending on which is located geographically closest to the network station. The network station is then removed from the network station node list after it has been so connected. The network stations are connected in the same way until the network station node list is empty and consequently all network stations within the defined station area have been connected to the relevant entry point.

According to a preferred embodiment of the invention, at least one process step is included in addition to the necessary processing to generate the proposed network configuration.

This step involves calculating a density measure that corresponds to an average investment per client point needed to build a physical network according to the generated network configuration. Preferably, the density measure expresses a required connection length per client point. Figure 11 shows a graph of a cost function that can be applied in calculating this measure to improve the accuracy of the cost estimate. A cost per unit length Cst/l.u., say USD/meter, varies here with a connection length per client point C.|./f, so that the cost per 521 572 26 unit length Cst/l.u. falls from an initial value CstO representing a basic investment to an asymptotic value CstC, which is approached at high connection lengths per client point c1/f (i.e. low densities). It has been empirically found that a typical cost function of this kind is well described by a hyperbolic tangent function.

As mentioned at the beginning, due to partial time overlap between the loads generated by each of a plurality of client points, the combined load created by a group of client points is generally different compared to a linear summation of the individual loads. Figure 12 shows an exemplary graph modeling this condition. The graph describes a network utilization rate t[h/year] as a function of the number of client points #f, which is preferably applied both when associating the client points to the station areas and in the proposed clustering step when two or more client points are associated with each other so that a sub-network is formed within the station area to which the client points belong. Thus, the size of the station areas, as well as their capacity, can be determined more accurately.

For the purpose of summarizing, the general procedure for configuring a resource distribution network according to the invention will now be described with reference to the flow chart in Figure 13.

A first step 1310 receives a supply node list containing a first set of coordinate data indicating for each of the at least one input points a geographical position and a corresponding amount of resources being input into the network.

A second step 1320 receives a user node list containing a second set of coordinate data indicating for each of the client points a geographical position and a corresponding estimated average amount of resources output at the client point. A step 1330 checks whether both the supply node list and the user node list have been received, and if so, the procedure continues to a step 1340. Otherwise, the procedure returns to the start and waits for any lists not yet received.

Step 1340 forms a station area around each input point.

The station areas are formed so that a given client point falls within the station area whose associated input point is closest to the client point. However, according to a preferred embodiment of the invention, a sufficiently large proportion of the client points thus associated are instead associated with a second closest input point if the estimated sum of resources output at the client points exceeds the input point's capacity. This proportion of client points can only be associated with the second closest input point if its capacity allows it. Otherwise, the proportion of client points must be associated with a third closest feed point, and so on.

Next, a step 1350 forms at least one sub-network within each station area. These sub-networks are formed according to a network segmentation algorithm. It is worth mentioning here that step 1350 may be empty or trivial, so that the at least one sub-network does not necessarily have to represent an actual network but may instead merely constitute a common reference to the client points within a particular station area. After this, a step 1360 forms one or more client clusters, in which the client points in each station area are associated with each other, so that two or more client points together form at least one client cluster within the sub-network to which they belong. A first connection step 1370 then connects the client points within each client cluster to a respective network station, after which a second connection step 1380 connects further network stations to the at least one input point. Finally, a description of the generated network configuration is provided in a step 1390.

All process steps, as well as any subsequences of steps described with reference to Figure 13 above, can be controlled by means of a computer program that is directly downloadable into the internal memory of a computer that includes appropriate software to control the necessary steps when the program is run on a computer. In addition, such computer programs can be written down on any type of computer-readable medium, as well as transmitted over any type of network and transmission medium. For example, the computer program can be downloaded into a computer from a signal from the Internet.

According to a first alternative embodiment of the invention, the algorithm for the proposed clustering and connection methods does not involve a shift of the balance point to an artificial balance point (such as from CB4 to fÖCB in Figures 7a-c). Instead, the actual balance point is retained (e.g. CB., in Figure 5).

Consequently, it will not be necessary to select new artificial balance points. This may be appropriate for some applications. However, retaining the actual balance point will make clustering a slightly more time-consuming process, especially for station areas that include a very large number of client points.

According to a second alternative embodiment of the invention, the algorithm for the proposed clustering and connection methods does not consider any angular relationships between the client points. Thus, in this embodiment, for example, the of and oÜ columns can be removed from the group node list 610 in Figure 6b. Namely, only the radial order of the client points determines how the clustering method is performed. However, the method involves generating repeated listings of all unclustered client points with respect to their distance to a first element in each client cluster. Below is a description of this alternative clustering method with reference to the client points f1-f11 in Figure 5.

After the balance point CB4 has been determined taking into account the geographical positions and estimated average amounts of resources output at the client points f1-f11, the client points are arranged in a group node list in increasing radial order from the balance point CB., (i.e., according to the fi(ri) column of the group node list 610 in Figure 6b). Then, the last element of the group node list (i.e., the client point f1) is assigned a first client cluster C1 and removed from the list, thus making the client point fw the last element of the group node list.

A list is then generated that ranks all client points in increasing radial order from client point f1. The client points fz, f3, f5, and point f4 represent the first four entries in this list. Thus, client point f2 is identified as the geographically closest to client point f1, client point f3 as the second closest, and so on.

After this, a test is performed whether the client point f2 satisfies at least one boundary condition and can thus be added to the first client cluster C1. The boundary condition normally involves determining a first temporary balance point CBTQ as described above with reference to Figure 7a. According to a preferred embodiment of the invention, however, the boundary condition also involves testing against a boundary quantity, that is, whether the sum of the estimated average amounts of resources output at the client points f1 and f2 exceeds the boundary quantity. Provided that the client point f2 satisfies any such boundary conditions, it is assigned to be a further subsequent element in the first client cluster G1. The client point f; is also removed from the group node list.

Then the test for the boundary condition above is repeated for client point f3. This client point fg is found to satisfy the boundary condition and is consequently also assigned to the first client cluster C1 and removed from the group node list. However, the next entry in the list, client point fs, fails the boundary condition test and therefore cannot be assigned to the first client cluster C1.

Instead, a second client cluster G2 is formed, where the currently last element in the group node list, i.e. the client point fm, is a first element. After this, a repeated listing is generated that 521 572 ranks all the client points in increasing radial order from the client point fm. The client points fg, fn, and fö, respectively, correspond to the first three entries in this listing. Thus, the client point fg is identified as the geographically closest to the client point fw, the client point fu as the second closest, and so on.

The at least one boundary condition is then tested. New clusters are formed and repeated listings are generated accordingly, until all client points f1-f11 have been assigned to a client cluster C1-C5, which is equivalent to the group node list being empty.

Finally, the above-described second alternative embodiment of the invention is also applicable as a viable alternative to the proposed connection algorithm in the district grouping procedure (which similarly involves an angle search to find a next closest client point to be "assigned").

The term "comprise/comprising" when used in this specification shall be construed as specifying the presence of the stated features, integers, steps or components. However, the term does not exclude the presence or addition of one or more additional features, integers, steps or components or groups thereof.

The invention is not limited to the embodiments described in the figures but can be varied freely within the scope of the patent claims.

Claims (21)

10 15 20 25 30 35 521 572 31 PATENT REQUIREMENTS A method of configuring a resource distribution network, in which resources are entered via at least one input point (F1-F4) and output at a plurality of client points, the method comprising: receiving, via a first data input means (120a), a supply node list (110a) containing a first set of coordinate data indicating a geographical position (X1, Yj) and a corresponding amount of resources (A1) entered into the network for each of the at least one entry point (Fi-H), reception, via a second data input means (120b), of a user node list (110b) containing a second set of coordinate data indicating for each client point a geographical position (X1, y1) and a respective estimated average amount of resources (aj) output at the client point, processing in a digital processor (130) of the supply node list (110a) and the user node list (110b), the processing generating a network configuration (150) where each branch ent point is connected to a particular input point (F1-F4) either directly or via at least one other client point, and which comprises: a subdivision step, through which a station area (SA1-SA4) is formed around each input point (F1-F4), which station areas ( SA1-SA2) is formed so that a certain client point ends up within the station area (SA1-SA4) whose associated input point (F1-F4) is closest to the client point, a grouping step, through which at least one subnetwork (N11-N42) is generated within each station area (SA1 -SA4), which at least one subnetwork (N11-N42) is generated according to a network segmentation algorithm, a clustering step, through which the client points in each station area (SA1-SA4) are associated with each other so that two or more client points (f1, f2, f3; f9, fw; f7, fö, f4, fn; f5, fö) together form at least one client cluster (C1_C5) within the subnetwork (N41) to which they belong, and a connection step, through which each client cluster (G1-G5) is assigned to a respective network station ( NSj-NSS), the client points (fj, f2, f3; fg, fw; fy, fa, f4, fn; f5, fö) within each client cluster (G1, G2, G3, G4; G5) being connected to their respective network stations (NS1_NS5) and the network stations (NS1_NG5) in turn are connected to a special input point (F4) of the at least one input point (F1_F4), and delivery, via a data output means (140), of a description of the generated network configuration (150). A method for configuring a resource distribution network according to claim 1, characterized in that the network segmentation algorithm is trivial in that the grouping step only provides a list of client points within each station area (SA1-SA4). A method for configuring a resource distribution network according to any one of claims 1 or 2, characterized in that the grouping step comprises: a district grouping sub-step, by which each client point in each station area (SA1-SA4) is linked up to the station area input point (F1-F4) in such a way that a certain client point is connected to the input point either directly or via at least one other client point. A method for configuring a resource distribution network, characterized in that the district grouping sub-step comprises: determining a balance point (GB4) with respect to the geographical positions and estimated average amounts of resources output at the client points (f1-f13) within the station area (SA4), identifying a first client point (f) which is geographically closest to the balance point (G84), defining the first client point (fß) as connected, 10 15 20 25 30 35 521 572 »mt» 33 identifying a second client point (f5), which is geographically second closest to the balance point (C84), definition of the second client point (fs) as connected and connected to the first client point (fö), identification of any not yet connected client points (f1, f2, f3, f4, f5, fa, fg , fw, f11, f12; fw) with increasing radial distance from the balance point (C84) and subsequent connection of each of these points (f1, fz, f3, f4, f5, f8_ fg, fm, fn, fn; f13) to a corresponding nearest connected client point (f6; f5) until all client points within the station area (SA4) are interconnected in a preliminary subnetwork (N4). A method of configuring a resource distribution network according to claim 3, characterized in that the district grouping sub-step comprises: specifying a balance point with a particular geographical position, identifying a first client point geographically closest to the balance point, defining the first client point as connected, identifying a second client point, which is geographically closest to the balance point, defining the second client point as connected and connected to the first client point, identification of any as yet unconnected client points with increasing radial distance from the balance point and subsequent connection of each of these points to a respectively the nearest connected client point until all client points within the station area are connected to a preliminary subnetwork. A method for configuring a resource distribution network according to any one of the preceding claims, characterized in that the network segmentation algorithm comprises: generating a preliminary subnetwork (N4) in the station area SA4, which interconnects all the client points therein, subdivision of a subnetwork (N41, N42) from the preliminary subnetwork (N4) whenever the length of a connection between two client points (fa, f12) or between a client point and the input point exceeds a boundary distance (Dm), and the generation of a group node list (610) over client points (f1_ fn) within each respective subnetwork (N41), which group node list (160) for each client point specifies: a radial distance (rj) to a geographical position representing a balance point (CB) with respect to the geographical positions and estimated average quantities of resources output at the client points (f1- fm) within the subnetwork (N41), and an angular measure (oU, of), which reflects an angular coordinate between the client point and a client point located at a nearest major and / or a nearest minor degree angle relative to the balance point (CB4), the group node list (610) being arranged in an order of increasing radius so that a first record corresponds to the client point (fÖCB) located at the smallest radial distance from the balance point (CB) and a second record corresponds to the client point (f5) located at the second smallest radial distance from the balance point (CB) and so on. A method for configuring a resource distribution network according to claim 6, characterized in that the clustering step comprises: assigning a currently last client point (fj) in the group node list (610) as a first element in a client cluster (C1) and removing the client point (f1 ) from the group node list (610), assigning a later element in the client cluster (C1) as a client point (fz) which is located geographically closest to the client point (fj) corresponding to the first element, which 15 15 20 25 30 35 521 572 35 later elements is added provided that at least one boundary condition is met, otherwise the client cluster (C1) is defined as filled and the latter element is instead a first element in a new client cluster (CZ) and continued assignment of elements to client cluster (C1-C5) until all client points (f1-f11) in the group node list (610) have been assigned a client cluster (C1-C5). A method for configuring a resource distribution network according to claim 7, characterized in that the at least one boundary condition means that a distance between two client points (f1, f2) which are connected to each other must be less than the boundary distance (Dm). A method for configuring a resource distribution network according to any one of claims 7 or 8, characterized in that the at least one boundary condition causes a distance between a candidate client point (f3) to be added to a cluster (G1) and a temporary balance point (CBTm). ) taking into account the geographical positions and the estimated average amount of resources output at the client points (f1, f2) in the cluster (G1) and the candidate client point (f3) must be less than the boundary distance (Dm). A method for configuring a resource distribution network according to any one of claims 7-9, characterized in that the at least one boundary condition means that the sum of the estimated average amount of resources output at the client points within a certain client cluster must be less than a limit amount. A method of configuring a resource distribution network according to claim 10, characterized by calculating the sum of the estimated average amount of resources output at the client points with respect to a non-linear resource addition function. 10 15 20 25 30 35 521 572 36 A method of configuring a resource distribution network according to any one of claims 7-11, characterized in that the connection step comprises: positioning the network station (NS1-NS5) at a geographical position corresponding to a balance point with respect to the geographical positions and the estimated average amount of resources output at the client points (fi-fn) within the client cohort (C1, G2, C3, C4; G5) and allocation of a capacity to the network station (NS1-NS5) that is sufficient with respect to the sum of the estimated average amount of resources output at these client points (f1, f2, f3; f9, f10if7_f8; f4, f11; f5, fö). A method for configuring a resource distribution network according to claim 12, characterized by allocating capacity to the network station (NS1-NS5) with respect to a non-linear resource summation function. A method for configuring a resource distribution network according to any one of claims 12 or 13, characterized by placing an integer number of network stations (NC1-NS5) at the balance point, which integer number is at least equal to the sum of the estimated average amount of resources output at the client points (f1, f2, f3; fg, fw; f7, fs; f4, f11; f5, fs) within the client shore (01, G2, G3, C4; G5) divided by a maximum allowed capacity of a single network station. A method of configuring a resource distribution network according to any one of claims 12-14, characterized in that the connection of client points (fa-fk) to the network stations (NS) comprises: connection of a first client point (fa) located closest to the network station (NS) and interconnecting the client points (fb-fk) located further away from the network station (NS) than the first client point (fa) in an order of increasing radius from the network station (NS) so that each client point (fb-fk) is connected either to an already connected client point (fa-fj) or to the network station (NS), whichever is geographically closest to the client point (fb-fk). A method for configuring a resource distribution network according to any one of the preceding claims, characterized in that the connection of network stations to the at least one input point (F1-F4) comprises: associating a special network station (NC1-NS5) to the input point (F4) as serves the station area (SA4) within which the client points are located, which are connected to the network station (NSj-NSs), creating, for each input point (F1-F4), a network station node list of network stations associated with the input point, which network station node lists for each network station : a radial distance to the input point and an angular measure reflecting an angular coordinate between the network station and a network station located at an immediately larger and / or a smaller angle relative to the input point, which network station node list is arranged in an order of increasing radius so that a first p cheese corresponds to the network station located at the smallest radial distance from the feed point, a second record corresponds to a network station located at the next smallest radial distance from the feed point and so on, connecting a currently top network station in the network station node list to the feed point, or via another network station depending on which is located geographically closest to the not yet connected network station, removal of any connected network stations from the network station node list and continued connection of network stations the network station node list is empty. until 10 15 20 25 521 572 38 A method of configuring a resource distribution network according to any one of the preceding claims, characterized in that the processing comprises: calculating a density measure corresponding to an average investment per client point (f) required to build a physical network according to the general network configuration (150). ). A method for configuring a resource distribution network according to claim 17, characterized in that the density measure expresses a necessary connection length per client point (f). A method of configuring a resource distribution network according to claim 18, characterized by modifying the required connection length per client point so that the required connection length per client point (f) increases with an increasing density measure. A computer program directly downloadable in the internal memory of a digital computer comprising software for performing the steps of any of claims 1-19, when said program is run on a computer. A computer readable medium having a program written thereon, the program causing a computer to perform the steps of any of claims 1-19.