EP0846642B1 - Downpeak group optimisation system - Google Patents

Abstract

The optimisation system allocates each cabin in the group for the service of a predefined need has the group serving a predetermined number of storeys. The system has an allocation store (11) of cabins (4) which can be allocated to serve the predefined need, whereby the store determines a number of cabins. An allocator (20) initialises a response region for the group, whereby the response region comprises a predetermined number of neighbouring storeys. A sampler (10) queues floor calls and determines the specific storeys which demand lift service and that the allocator is authorised to group the specific storeys demanding service into a series from the highest to the lowest. It forms non-overlapping groups with a size smaller than the response region.

Description

1. Technical field

The present invention relates to a System for optimizing the allocation of elevator down-peak traffic in an elevator group.

2. State of the art

The evening rush hours are stronger Elevator traffic, where are the elevator cabins generally fill the upper floors and transfer them to the Drive past the lower floors. The waiting times for Downstairs floor calls are therefore extended in the lower floors dramatically.

To the service between the upper and lower Balancing floors will be the case with some Elevator control systems are computer controlled Handling strategy for assigning elevator traffic applied according to a time-oriented algorithm. On Example of such a strategy with time-based Algorithm is described in U.S. Patent No. 4,492,288 all of which are expressly referred to here becomes. In patent 4,492,288 there are down hall calls combined to form groups based on a rough chronological order of entered hall calls based. The down hall calls are in time Order stored in a RAM. The oldest call becomes an elevator cabin with the highest priority assigned, and the next oldest call is based on the specific circumstance either the elevator car with the highest priority or a cabin with second priority allocated.

Another system for assigning down hall calls is disclosed in U.S. Patent No. 5,480,006. During a down-peak traffic time this gives Downstream traffic priority service system and reserves at least one elevator cabin for Up service. All floors, the downstairs service however, will require equal access to the system issued, regardless of the floor location with regard to the Building. The system divides the building into a number of Sectors that are the same as for downward peak traffic available number of cabins is. All other floors are redistributed to the lower one. A specific sector becomes a cabin depending on the age of the sector assigned. After assigning the sector, the cabin parks on top of the sector until a down hall call is made and serves the down hall calls from highest to highest lowest.

Another example of a group orientation system is in document EP-A-0 452 225.

Even when using the above However, strategies are still high average Waiting times due to the corresponding bad Distribution of elevators in the building.

SUMMARY OF THE INVENTION

It is an object of the present invention Group optimization system for downward peak traffic to provide that is not among those mentioned above Disadvantages of the prior art suffers.

The present invention may accordingly to a group optimization system for use with a Multi-cabin elevator group for the allocation of each cabin in the elevator group to operate a predefined one Within a predetermined number of times Group serving floors. The Group optimization system can provide a device for specifying of assignable cabins to operate the predefined Contain the need for a device for determining a specified number of cabins and a device for Initialization of a response area for the Elevator group contains. The response area can be a include predetermined number of adjacent floors. The group optimization system can also be a device for Storage of landing call requests, one device to scan the storage means to determine more specific Floors requesting elevator service and one Device for grouping the operator requesting specific floors in an order of one top floor to bottom floor included. The grouping device can not overlap groups with a size smaller than or equal to the response range. The system can also include a device for comparing a Number of those not formed by the grouping means overlapping groups with the specified number of assignable Cabins and a device for allocation of a one-time of the non-overlapping groups to each of the assignable Cabins included.

According to another feature of the present Invention can equal the number of non-overlapping groups the number of cabins that can be allocated. As Alternatively, the number of non-overlapping groups be greater than the number of assignable cabins specified.

According to yet another characteristic of the present Invention, the comparison device can be a device to increase the response range by one floor if the Number of non-overlapping groups larger than the number specified assignable cabins is included. Can too the system is a device for regrouping the specific operation requesting floors in one Order from top to bottom Floor included. The regrouping device can non-overlapping regrouped groups with one size less than or equal to the increased response range. Also can the system provide a device for comparing a Number of non-overlapping regrouped groups with the Number of specified assignable cabins included, and the Allocation device can also be any of the allocable Cabins a unique one of the non-overlapping regrouped Allocate groups if the number does not overlap Groups less than or equal to the number of assignable specified Cabins is.

According to another feature of the present Invention, the comparison device can be a device to increase the response range by one floor if the Number of non-overlapping regrouped groups greater than the number of specified assignable cabins is included, and the system can rearrange the steps specific operation requesting floors, comparing the number of regrouped groups and increasing the Repeat the response range until the number of not overlapping regrouped groups less than or equal to Number of allocable cabins specified.

According to yet another characteristic of the present The system can be invented by initiating a Downward peak hours can be activated.

According to another feature of the present Invention can the scanner to a specified Time after allocation of the allocable cabins Recapture storage device to specific To determine service-demanding floors.

According to another feature of the present Invention groups the grouping device specific operation requesting floors in one - Order from top to bottom Floor, the grouping means not overlapping Groups with a size equal to the response area for each Group above a lowest formed group and with a size less than or equal to the response range for the lowest educated group forms.

The present invention can relate to Process for optimizing elevator car allocation in a multi-cabin elevator group refer to each cabin in the elevator group operating a predefined Allocate as needed. The elevator group can one Operate predetermined number of floors. The Group optimization procedures can specify assignable Cabins for serving the predefined needs and for Determination of a number of specified cabins and the Initialization of a response area for the Include elevator group, the response area a includes a predetermined number of adjacent floors. The method can also scan for pending Landing calls to determine specific Elevator operation requesting floors that Grouping of specific service requests Floors in an order from a top floor to a bottom floor and not making overlapping groups with a size smaller than that Response range and comparing a number of through the grouping means formed do not overlap Groups with the specified number of assignable cabins include. The procedure can also be the allocation of a unique of the non-overlapping groups to each of the assignable cabins included.

According to another feature of the present Invention can equal the number of non-overlapping groups the number of cabins that can be allocated.

According to yet another characteristic of the present Invention can increase the number of non-overlapping groups than the number of assignable cabins specified.

According to another feature of the present Invention can increase the method Response area by one floor if the number is not overlapping groups larger than the number of specified assignable cabins is included.

According to another feature of the present Invention can rearrange the method specific operation requesting floors in one Order from top to bottom Floor and forming non-overlapping regrouped Groups with a size equal to the increased response range and with a size less than or equal to the increased Response area for a lowest educated group and Compare a number of non-overlapping regrouped groups with the number of given assignable Cabins included. The procedure can also allocate a unique one of the non-overlapping regrouped ones Groups to each of the assignable cabins if the number non-overlapping groups less than or equal to the number specified assignable cabins is included.

According to yet another characteristic of the present Invention can increase the method Response area by one floor if the number is not overlapping regrouped groups greater than the number specified assignable cabins is included. Can too the procedure repeating the regrouping steps floors requiring specific operation, Compare the number of regrouped groups and increase of the response range until the number does not overlap regrouped groups less than or equal to the number of specified assignable cabins is included.

According to yet another characteristic of the present Invention, the method by initiating a Peak traffic time can be activated.

According to another feature of the present Invention can postpone the process at a specified time Allocation of the allocable cabins the repeated scanning of the upcoming hall calls to determine Elevator operation requesting specific floors contain.

According to another feature of the present Invention, the method can be grouping specific Operation requesting floors in an order of a top floor to a bottom floor and Form non-overlapping groups with one size equal to the response area for each group above one lowest educated group and with a size smaller equal to the response area for the lowest educated Group included.

The above-mentioned tasks and characteristics of present invention are described below with reference to the accompanying Drawing figures and specific examples in more detail discussed.

BRIEF DESCRIPTION OF THE DRAWINGS

Figur 1 eine schematische Darstellung des Gruppensteuersystems zur Verwendung mit der vorliegenden Erfindung ist;

Figur 2 ein Flußdiagramm eines beispielhaften Abwärtsspitzenverkehrs-Optimierungssystems nach der vorliegenden Erfindung darstellt;

Figur 3 ein Beispiel eines RAM1 zur Stockwerk/Fluraufrufspeicherung darstellt;

Figur 4 ein Beispiel einer Zuteilungsspeicherung darstellt;

Figur 5 ein Beispiel einer Anfangsgruppierung von Aufrufen des Gruppenoptimierungssystems für Abwärtsspitzenverkehr der vorliegenden Erfindung darstellt; und

Figur 6 ein Beispiel einer erhöhten Gruppierung von Aufrufen durch das Gruppenoptimierungssystem für Abwärtsspitzenverkehr der vorliegenden Erfindung darstellt.

The present invention will be further described in the following detailed description with reference to the aforementioned plurality of drawings by means of non-limiting examples of preferred embodiments of the present invention, like reference numerals representing like parts in all of the several views of the drawings, and wherein:

Figure 1 is a schematic representation of the group control system for use with the present invention;

Figure 2 illustrates a flow diagram of an exemplary down peak traffic optimization system in accordance with the present invention;

Figure 3 illustrates an example of a RAM1 for floor / hall call storage;

Figure 4 illustrates an example of allocation storage;

Figure 5 illustrates an example of an initial grouping of calls to the down peak group optimization system of the present invention; and

Figure 6 illustrates an example of increased grouping of calls by the down peak traffic group optimization system of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The details listed here are only exemplary and serve to illustrate the preferred embodiments of the present invention and are to represent the most suitable and most understandable deemed description of the principles and Conceptual aspects of the invention cited. In this regard no attempt is made to identify the structural details of the To illustrate the invention in more detail than for basic understanding of the invention is necessary the description together with the drawings Expert clarifies how the different forms of Invention can be carried out in practice.

An elevator control system to optimize the Downward peak traffic according to the present invention shown generally in Figure 1 and similar to that in US Pat. 4,492,288 disclosed system on the Revelation in its entirety expressly reference here is taken. An elevator shaft 1 for an elevator A For example, an elevator group contains three Elevators shown as A, B and C. A Elevator cabin 4 is guided in elevator shaft 1 and by any suitable lifting or driving machine 2 by a lifting cable 3 or another similar Lifting device driven. In the illustrated in Figure 1 The building can be an exemplary elevator system for example fifteen floors E1-E15 to be operated contain. The lifting or driving machine 2 can by a Drive control such as that shown in U.S. Patent No. 4 337 847, are controlled, on the disclosure of which in all of which are incorporated herein by reference. The Drive control can be a microcomputer system 5 for Implementation of reference value generation, the automatic Regulation and control functions and the initiation of stopping contain and can furthermore measuring and setting elements 6 contain such a drive control, which has a first interface IF1 with the microcomputer system 5 are connected. The microcomputer systems 5 of each Elevators A, B and C have a comparator 7 and one second interface IF2 and over Common line transmission system 8 and a third Interface IF3 interconnected. In this way the microcomputer system 5 forms a group control, such as for example, those described in U.S. Patent No. 4,335,705 the disclosure of which in its entirety is detailed herein Reference is made. Via group control Elevators A, B and C can be optimally assigned to on a floor / hall call storage RAM1 stored To address floor or hall calls. The Microcomputer system 5 may also include a scanner 10 included, which RAM1 scans to identify which ones There are pending floor / hall calls, and stores the corridors in an allocation memory 11. The Scanning device 10 can with one in one programmable read-only memory, e.g. an EPROM, stored software function are implemented, and the Allocation memory 11 can be any conventional storage device, including for example a random access memory (RAM - random access memory).

The scanner 10 can be activated when the elevator system in the down-peak hours, e.g. at 4:30 p.m. The time cannot be internal shown clock can be monitored. To have problems with not Avoiding reasonable waiting times for users leads to An initial scan of RAM1 by and saves the current floor / hall calls in Allocation memory 11. After scanning, RAM1 is cleared and with the next series of floor / hall calls filled. However, the scanner 10 can be on Wait release signal from an allocation device 20, by a periodic timer or another suitable device can be implemented. This means, after allocation of those stored in the allocation memory 11 Floor / hall calls to the available elevator cars for Operation of scanning traffic can Allocation device 20 of the scanning device signal the next number of waiting floors / hall calls pass.

To feed the floor / hall calls to Microcomputer system 5 can be a switching system or Switching arrangement 9 can be used. During the Down-peak traffic time can be an input side Switching system 9 by means of a transmission device 12, which Descent and descent corridor calls in chronological order or time sequence of your input, with Descending or down hall call transmitters 13 connected his. The time input of down hall calls is transmitted to a circuit 14 via the switching system 9. Circuit 14 may be coupled to RAM1 to for a logical "high" or every pending landing call to display a logical "1". As shown, this can RAM1 one entry for each floor of the building, e.g. 15 Entries. The RAM1 can then with a sequence of oil and oil, operation on one Show expected users on the specified floor. For the The example shown in Figure 1 contains RAM1 down hall calls for floors E15, E13 and E5.

The general functioning of the transmission and Storage of down hall calls during the Downward peak hours can be done as follows describe:

After switching to a down-peak traffic time the transmitter 12 gives the floor locations for each Actuation of the descent or down hall call transmitters 13 continued in chronological order. For example, suppose that when operating the downward peak traffic function the Time sequence followed by entry of down hall calls E14 of E13 and then E15. Every downward corridor call is passed on to the circuit 14 via the switching system 9. Circuit 14 outputs each floor location Floor / hall call memory RAM1 continues where it is stored until the scanner 10 is released.

After scanning the floor / hall call memory RAM1 and storage of the upcoming down hall call locations, e.g. E14, E13 and E15 in the allocation memory 11 by the Scanning device can, for example, in the Allocation device 20 stored program for Optimization of the assignable elevator cabins to respond downward peak traffic, i.e. on Downward peak traffic optimization system, for use come.

FIG. 2 shows an exemplary flow diagram of the optimization system according to the invention for Down peak traffic. The flow chart begins with the Initiation of downward peak hours. As noted above the down-peak rush hour is generally an evening one Rush hour and can start, for example, at 4:30 p.m. The Time of day can be indicated by an internal clock or not shown similar device can be monitored.

In step 201, the optimization system for Down-peak traffic a group size for that Initialize the elevator group. The group size can be one predetermined number of floors to which one address any specific elevator group properly can. Assume the group size is on five floors then each down-peak traffic group can only respond to three hall calls per cycle.

The group size can be determined by looking at the number be determined by cabins that respond to the Downward peak traffic and the number of floors in the Buildings can be allocated. Take for example indicate that the present invention in a fifteen-story Building is used and that the system to respond to Downward peak traffic then used three elevator cars the group size can be divided by dividing the total number of Floors through the assignable elevator cabins determine. In this particular example, the Group size five. So the largest group is that can be allocated to a single elevator car, one Group with five floors.

As soon as the group size is set, the Step 202 a floor separation (response area) value First specification of floor separation (or area) between the first and last assignable to each group Call initialized. In other words, if the Floor separation value initially specified as "1" is the Range of calls between the first and last assigned call "1" floor or two neighboring Floors. One can imagine that the range of values of calls for the elevator group a top floor with down hall calls and a number of floors below the first call corridor equal to the specific one Floor separation value included. So if the Floor separation value, for example, initiated as "1" each group is no larger than two neighboring ones Floors. If, for example, a highest floor / hall call comes from floor E10, then that is the first group of assignable range of calls Floors E10 and E9. All floor / hall calls that have their origin under floor E9, one group created below.

After initializing the floor separation value pending the building in step 203 Down floor / hall calls can be queried. As above discussed, this scanning by a Scanning device 10 are performed, which the in chronological order in the floor / hall call memory RAM1 samples entered values. The samples can then be stored in an allocation memory 11. Unlike the prior art systems, this requires present system, however, no storage of Floor / hall calls in chronological order; the Allocation memory 11 contains a "snapshot" of the sampled storey / corridor call memory RAM1. So shows the allocation memory 11 indicates whether from a particular one Floor a down call has been issued and which Floors downward peak traffic allocation by the Require optimization system for downward peak traffic.

Assume that, as shown in Figure 3, before the Query the building downstairs / hall calls from following floors in the order of e.g. E14, E13, E15, E10, E8, E12, E9, E11 and E7 were made. Figure 3 provides an example of the floor / hall call memory RAM1 where the calls are in chronological order are saved. Figure 4 shows an example of the Allocation memory 11 after scanning the floor / hall call memory RAM1 by scanner 10. The allocation memory 11 shows by a logical "1" at which floors pending down calls and / or which floors the address by an assignable down-peak traffic elevator cabin require. As shown in Figure 4, the Allocation memory 11 simply indicate which floors have requested downward operation, i.e. Floors E15, E14, E13, E11, E10, E9 and E7.

After sampling and storing the outstanding Downstairs / hall calls determine that Optimization system for downward peak traffic in step 204 a number of groups that are used to operate the Downward peak traffic loads are necessary. So are like in Figure 4 shows down hall calls from each of the Floors E15-E13, E11-E9 and E7 have been issued (i.e. Downward operation is requested from these floors was). According to the grouping procedure of In the present invention, the system can count the number of Groups starting with, for example, the top one Floor / hall call floor E15 to determine the To start grouping. Figure 5 shows an example of a first grouping by the optimization system for Down peak traffic. Group g1 can initially call from top down hall call, e.g. E15, and a specified Number of neighboring floors below the top Calling up the floor separation or the Response range, e.g. the initialized value "1" contain. Accordingly, group g1 may initially be E15 and E14 included. The group g2 can be the next in Floor / hall call memory stored down floor / hall call included that is not in group g1 is included, e.g. E13. Group g2 can only E13 included as the only other floor that is for inclusion to group g2 as determined by the initial Floor separation value of "1" is available, only E12 would include. According to the building query, however no downward operation by calling up the floor / corridor E12 requested and group G2 contains only one Down call Member. Group g3 can the next stored floor / corridor call, e.g. E11 and also E10, contain. Group g4 can contain E9. The group g5 can contain E7.

It should be noted that each group has at least one Floor / corridor call must contain. It should also be noted that it is not necessary that every floor in the Grouping scheme is included. The grouping should but does not contain overlapping group members, i.e. each group is not formed overlapping.

After the groups have been created for the first time in step 205 the number of specified groups with the total number of available to service the downward peak traffic load Elevator cabins are compared. Suppose the system is with three to service the downward peak traffic load available elevator cabins, then the three Elevators five in the initial grouping of the down hall calls formed groups not in an adequate way work off.

If the system initially had a number of groups specifies which is greater than the total number to be used of the groups available elevator cabins, then that can Optimization system for downward peak traffic in step 207 increase the floor separation value by a value of "+1", so that the floor separation value can now be "2". So For example, each group can now have three neighboring groups Floors included. The flow chart returns to step 204 back to groups according to the new floor separation or to form the new response value range. So it shows Figure 6 shows an example of after increasing the response range by the optimization system according to the invention for the Downward peak traffic grouping. from top down floor / hall call to bottom Downstairs floor / corridor call can group the im Allocation memory 11 stored calls can be as follows: Group g1 can contain E15, E14 and E13; Group g2 can E11, E10 and E9 included; and group g3 can contain E7. In step 205, the optimization system for the Downward peak traffic count that three groups are formed have been. At step 206, the system can now determine whether the number of designated groups is equal to that Number of available elevator cabins is. So the system can in step 208 the floor locations now correspond to the corresponding ones Allocate elevator cabins to reduce the downward traffic load serve.

After assignment of the elevator cabins to respond that can affect the downward peak traffic needs Optimization system for downward peak traffic to step 202 return to the floor separation or the Initialize response range to "1" and steps 203 - Repeat 208. The procedure can Downward peak traffic needs the available Flowchart steps assigning elevator cabins cyclically up to a predefined one Down-peak traffic termination time, e.g. 8:00 p.m., to repeat.

According to the present invention, the building once queried and a "snapshot" of the present pending downstairs floor / hall calls are saved and used for the steps grouping-increasing-grouping. As soon as the downstairs / hallway calls the available Elevator cabins are allocated, the "snapshot" deleted and the system repeats itself from the Initialization of the response area. Furthermore is too notice that the system when the number of educated Groups smaller than the number of available for allocation Cabins is the cab with the most advantageous response path the corresponding one-time groups of down calls will allocate.

As can be seen from the example above, optimizes the downward peak traffic system according to the invention the use of the available elevator cars to the Total number of elevator cabins available reduce worn floors. Furthermore, the present invention not by the total number of Floors or the available elevator cabins. The present invention eliminates each of these factors as a variable before determining the optimal one Downward peak traffic allocation from downstairs / hall calls to the available elevator cabins considered.

An additional advantage of the present invention is that the present system in Elevator zone systems, i.e. where specified cabins Zones or floors of a building are assigned, can be used. So can the routine discussed above optionally in each predefined building zone zone-wise optimization of downward peak traffic is used become.

It should be noted that the above examples are unique and have been presented for illustrative purposes only and in no way as the present invention are to be interpreted restrictively. Although the invention under Described with reference to a preferred embodiment has been understood that the words used here have been description and representation words and not are restrictive words. As part of the enclosed Claims in their current form and Modifications can be made, without departing from the scope and concept of the invention deviate from their aspects. Although the invention is here under Reference to certain means, materials and Embodiments has not been described intends the invention to be as disclosed herein Details is limited; instead, the Invention on all functionally equivalent structures, Processes and uses insofar as they are within the protection area of the attached claims.

Claims (10)

1. Group optimization system for use in a multiple car elevator group (A, B, C) to allocate each car (4) in the elevator group (A, B, C) to serve a predefined demand, wherein an elevator group (A, B, C) serves a predetermined number of floors and the group optimization system comprises:

   an allocation storage memory (11) of allocable cars (4) for serving the predefined demand, wherein the allocation storage memory (11) determines a number of cars (4);

   an allocation device (20) for initializing a response range for the elevator group (A, B, C) wherein the response range includes a predetermined number of adjacent floors;

   a scanning device (10) for pending hall calls to determine specific floors requesting elevator service;

   and that the allocation device (20) is responsible for grouping the specific floors, which request service, in an order from an uppermost floor to a lowermost floor, wherein the allocation device (20) forms non-overlapping groups (g1, g2, ..., g5) of a size less than or equal to the response range, for comparing a number of non-overlapping groups (g1, g2, ..., g5) formed by the allocation device (20) with the specified number of allocable cars (4), and for allocating a unique one of the non-overlapping groups (g1, g2, ..., g5) to each of the allocable cars (4).
2. Group optimization system according to claim 1, wherein the number of non-overlapping groups (g1, g2, ..., g5) is equal or greater than the number of specified allocable cars (4).
3. Group optimization system according to claim 1, wherein the allocation device (20) increases the response range by one floor when the number of non-overlapping groups (g1, g2, ..., g5) is greater than the number of specified allocable cars (4).
4. Group optimization system according to claim 3, further comprising:

   the allocation device (20) for regrouping the specific floors, which request service, in an order from an uppermost floor to a lowermost floor, wherein the allocation device (20) forms non-overlapping regrouped groups (g1, g2, ..., g5) of a size equal to the increased response range and of a size less than or equal to the increased response range for a lowest formed group (g1, g2, ..., g5), and compares the number of non-overlapping regrouped groups (g1, g2, ..., g5) with the number of specified allocable cars (4);

      wherein the allocation device (20) further allocates a unique one of the non-overlapping regrouped groups (g1, g2, ..., g5) to each of the allocable cars (4) when the number of non-overlapping groups (g1, g2, ..., g5) is less than or equal to the number of specified allocable cars (4).
5. Group optimization system according to claim 4, wherein the allocation device (20) increases the response range by one floor when the number of non-overlapping regrouped groups (g1, g2, ..., g5) is greater than the number of specified allocable cars (4); and
      the optimization system repeats the steps of regrouping the specific floors requesting service, comparing the number of regrouped groups (g1, g2, ..., g5) and increasing the response range until the number of non-overlapping regrouped groups (g1, g2, ..., g5) is equal to or less than the number of specified allocable cars (4).
6. Method for optimizing elevator car allocation in a multiple car elevator group (A, B, C) to allocate each car (4) in the elevator group (A, B, C) to serve a predefined demand, wherein an elevator group (A, B, C) serves a predetermined number of floors and wherein the group optimization method comprises as follows:

   specifying allocable cars (4) for serving the predefined demand and for determining a number of cars (4) specified;

   initializing a response range (202) for the elevator group (A, B, C), wherein the response range (202) includes a predetermined number of adjacent floors;

   scanning for pending hall calls (203) to determine specific floors requesting elevator service;

   grouping the specific floors, which request service (204), in an order from an uppermost floor to a lowermost floor and forming non-overlapping groups (g1, g2, ..., g5) of a size less than or equal to the response range;

   comparing a number (206) of the non-overlapping groups (g1, g2, ..., g5) formed by the grouping means with the specified number of allocable cars (4); and

   allocating (208) a unique one of the non-overlapping groups (g1, g2, ..., g5) to each of the allocable cars (4).
7. Group optimization method according to claim 6, wherein the number of non-overlapping groups (g1, g2, ..., g5) is equal to or greater than the number of specified allocable cars (4).
8. Group optimization method according to claim 6, with increasing of the response range by one floor (207) when the number of non-overlapping groups (g1, g2, ..., g5) is greater than the number of specified allocable cars (4).
9. Group optimization method according to claim 8, further comprising the following:

   regrouping (204) the specific floors, which request service, in order from an uppermost floor to a lowermost floor and forming non-overlapping regrouped groups (g1, g2, ..., g5) of a size equal to the increased response range and of a size less than or equal to the increased response range for a lowest formed group (g1, g2, ..., g5);

   comparing (206) a number of the non-overlapping regrouped groups (g1, g2, ..., g5) with the number of specified allocable cars (4); and

   allocating (208) a unique one of the non-overlapping regrouped groups (g1, g2, ..., g5) to each of the allocable cars (4) when the number of non-overlapping groups (g1, g2, ..., g5) is equal to or less than the number of specified allocable cars (4).
10. Group optimization method according to claim 9, with increasing of the response range (207) by one floor when the number of non-overlapping regrouped groups (g1, g2, ..., g5) is greater than the number of specified allocable cars (4); and
       wherein the method repeats the steps of regrouping (204) the specific floors requesting service, comparing (206) the number of regrouped groups (g1, g2, ..., g5) and increasing the response range (207) until the number of the non-overlapping regrouped groups is equal to or less than the number of specified allocable cars (4).

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