CN105528467A

CN105528467A - Method and apparatus for generating system diagram of indoor antenna distribution system

Info

Publication number: CN105528467A
Application number: CN201410507915.1A
Authority: CN
Inventors: 吴兴耀
Original assignee: China Mobile Group Design Institute Co Ltd
Current assignee: China Mobile Group Design Institute Co Ltd
Priority date: 2014-09-28
Filing date: 2014-09-28
Publication date: 2016-04-27
Anticipated expiration: 2034-09-28
Also published as: CN105528467B

Abstract

The invention provides a method and apparatus for generating a system diagram of an indoor antenna distribution system. The method comprises following steps: acquiring a plane graph of the indoor antenna distribution system; acquiring information of devices in the plane graph; processing the information of the devices and acquiring processing results; and generating the system diagram of the indoor antenna distribution system, wherein the system diagram is suitable for communication systems of multiple generations. The system diagram generated through the technical scheme provided in the invention is suitable for the communication systems of multiple generations, so that a problem that a conventional system diagram is only suitable for the communication system of first generation is solved.

Description

A kind of domestic aerial compartment system system map generalization method and device

Technical field

The present invention relates to the indoor distribution technical field of the communications industry, particularly relate to a kind of domestic aerial compartment system system map generalization method and device.

Background technology

At present, in indoor distribution (dividing hereinafter referred to as room) design, software (often design software is divided in the room of being called) usually can be used to assist planimetric map (also known as distribution plan) and the system diagram of drafting room point design proposal.Planimetric map, as its name suggests, react indoor distributed system (hereinafter referred to as room subsystem) the multinomial details in buildings plane, the device that the route of passing through as the kind of antenna, the distributed points position of antenna in buildings plane, feeder line from the information source (or virtual information source) of flat bed to antenna and the room subsystem that may use in flat bed can use, as power splitter, coupling mechanism etc. and present position thereof.And system diagram key reaction to be made up of the topological connection relation of room subsystem above-mentioned various components and parts.

Consider the factor such as construction cost, electromagnetic radiation safety requirements as a whole, operator can divide the radiation power of each antenna opening in construction scheme to have unified requirement to room usually, is namely limited within the scope around a certain desired value.

Room divides design software many based on software platforms such as computer aided design software CAD or Visio VISIO, belongs to secondary development software (or plug-in unit).This type of software of part has the function from planimetric map automatic creation system figure, but current all software is only supported to be optimized a certain specific system, in other words, the system diagram that software generates automatically can be only optimum or close optimum system topological annexation for a certain system (2G, 3G, 4G), and is not that optimum does not even meet operator for the requirement of room subsystem about antenna radiated power usually for another kind of system.

Summary of the invention

The object of this invention is to provide a kind of domestic aerial compartment system system map generalization method and device, can solve at present based on the design software of domestic aerial compartment system, designed domestic aerial compartment system system diagram can only meet the problem of generation communication system (second generation communication system 2G, third generation communication system 3G or forth generation communication system 4G etc.).

In order to solve the problems of the technologies described above, this embodiment bright greatly provides a kind of domestic aerial compartment system system map generalization method, wherein, comprising:

Obtain the planimetric map of a domestic aerial compartment system;

Obtain the device information in described planimetric map;

Described device information is processed, obtains result;

According to described result, generate and adapt to many system diagrams for the domestic aerial compartment system of communication system.

Wherein, the step of the device information in the described planimetric map of described acquisition comprises:

Obtain the antenna node quantity information that at least comprises in described planimetric map and each antenna node the first device information at the loss value of different system; And/or

Obtain the second device information being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism grouping information by virtual information source in the antenna node grouping information that at least comprises in described planimetric map and described planimetric map.

Wherein, describedly to process described device information, the step obtaining result comprises:

Packet transaction is carried out to the antenna node in described first device information, obtains and adapt to many group result for the antenna node of communication system.

Wherein, described packet transaction is carried out to the antenna node in described first device information, obtains and adapt to many steps for the group result of the antenna node of communication system and comprise:

Step a, according to the loss value information of each antenna node in described first device information in different system, obtains the loss value of each antenna node at current system;

Step b, according to the loss value of each antenna node at current system, sorts the antenna node in described planimetric map at current system according to loss value order from small to large or from large to small, and what obtain current system works as prime sequence node; Wherein, described when prime sequence node be antenna node sequence;

Step c, divides into groups according to the order of sequence to the node of working as in prime sequence node of current system, obtains when the node in prime sequence node is in the packet conditions information of current system; Wherein, described packet conditions information at least comprises: the nodal information of the described node when in prime sequence node in the grouping group number information of current system and current system are respectively divided into groups; Described nodal information at least comprises number of nodes information; And each grouping internal loss value is the node of maximal value and loss value is that the loss difference of the node of minimum value is less than loss difference threshold value;

Steps d, according to the packet conditions information of the node in antenna node sequence in each system, node in described antenna node sequence is divided into groups according to the order of sequence again, obtain the many new packet conditions information for communication system of adaptation of antenna node sequence interior joint, and using described new grouping information as current group condition information; Wherein, described current group condition information at least comprises: the nodal information in grouping group number information and each grouping; The new current group condition information of the antenna node sequence of each system is consistent; The loss difference of to be the node of maximal value and loss value the be node of minimum value of the loss value in each grouping is less than described loss difference threshold value.

Wherein, in described step c, the node of working as in prime sequence node of described current system is divided into groups according to the order of sequence, obtains when the node in prime sequence node comprises in the step of the packet conditions information of current system:

Step e, using current system when first node in prime sequence node is as start node, what obtain described start node and current system works as the first loss difference of the present node in prime sequence node at current system;

Step f, loss difference threshold value described in described first loss difference, and described start node and the next current system adjacent with described present node when the second loss difference of the node in prime sequence node is greater than described loss difference threshold value, it is one group by described start node to whole node division of described present node, and obtain the residue sequence node of current system, and described residue sequence node is worked as prime sequence node as the new of current system;

Step g, the node repeated in step e to step f to described antenna node sequence is complete in current system grouping, obtains the packet conditions information of the node in described antenna node sequence at current system.

Wherein, according to the packet conditions information of the node in antenna node sequence in each system in described steps d, node in described antenna node sequence is divided into groups according to the order of sequence again, obtain the new grouping information of the adaptation multisystem of antenna node sequence interior joint, and the step of described new grouping information as current group condition information comprised:

Step h, according to the packet conditions information of the node in antenna node sequence in each system, obtains the nodal information in the first grouping under different system of node in described antenna node sequence;

Step I, retrieves respectively the node of described antenna node sequence interior joint in the first grouping of each system, obtains the maximum common subset of the first grouping interior nodes, and be one group by the node division in described maximum common subset, form new first grouping;

Step j, obtains when prime newly remains sequence node, and using described new residue sequence node as one newly when prime sequence node;

Step k, the node repeated in step e to step f to described new residue sequence node is complete in current system grouping, obtains the grouping group number of node under different system in described new residue sequence node;

Step l, when the value of described grouping group number is positive integer, obtains the nodal information in the first grouping under different system of node in described new residue sequence node;

Step m, retrieve the node in first grouping of described new residue sequence node interior joint under each system, obtaining the maximum common subset of the first grouping interior nodes, and is one group by the node division in described maximum common subset, forms new first grouping;

Step n, repeats step j to step m to the new grouping information of adaptation multisystem getting antenna node sequence interior joint, and using described new grouping information as current group condition information.

Wherein, described according to described result, generate the many steps for the system diagram of the domestic aerial compartment system of communication system of adaptation and comprise:

According to the group result of the many antenna nodes for communication system of described adaptation, generate and adapt to many domestic aerial compartment system device hubbed mode system diagrams for communication system.

Wherein, the described group result according to the many antenna nodes for communication system of described adaptation, generates the many steps for the domestic aerial compartment system device hubbed mode system diagram of communication system of adaptation and comprises:

Step o, according to the number of nodes information in each grouping in current group condition information, for each grouping correspondence distributes power splitter or coupling mechanism, and forms next stage sequence node, and described next stage sequence node is worked as prime sequence node as new; Wherein, the quantity of described next stage sequence node interior joint is consistent with the grouping group number in current group condition information;

Step p, obtains the loss value of described next stage sequence node interior joint;

Step q, according to the loss value of described next stage sequence node interior joint, node in described next stage sequence node is arranged according to the order that loss value is descending or ascending, and perform step c, obtain the packet conditions information of described next stage sequence node interior joint, and using the packet conditions information of described next stage sequence node interior joint as new current group condition information;

Step r, repeats step o to step q, is 1 to the new quantity when prime sequence node interior joint formed.

Wherein, according to the number of nodes information in each grouping in current group condition information in described step o, for the corresponding step of distributing power splitter or coupling mechanism of each grouping comprises:

When number of nodes within dividing into groups when prime one is 1, using described node within prime one is divided into groups as the node in next stage sequence node; And/or

When number of nodes within dividing into groups when prime one is for being greater than 1, according to described number of nodes within prime one is divided into groups, dividing into groups corresponding to distribute power splitter or coupling mechanism when prime one for described, and forming next stage sequence node; Wherein, described number of nodes is positive integer; Described next stage sequence node comprises power splitter node and/or coupler nodes.

To in described second device information be connected to by virtual information source power splitter that antenna node respectively divides into groups and/or coupling mechanism is replaced, or parameter adjustment is carried out to described power splitter and/or coupling mechanism, obtain and adapt to many be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system.

Be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system according to the adaptation of described acquisition is many, generate and adapt to many domestic aerial compartment system device discrete pattern system diagrams for communication system.

Wherein, the many steps being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism distributed intelligence by virtual information source for communication system of the adaptation of described acquisition comprise:

Step s, obtains and to be in each grouping of prime each node at the loss value of current system; Wherein, described node is antenna node or coupler nodes or power splitter node;

Step t, obtains the loss difference of node at current system that node that described loss value within prime is respectively divided into groups is maximal value and loss value are minimum value;

Step u, obtain described when respectively the divide into groups average loss of interior joint of prime poor; Wherein, the average loss difference of each grouping interior joint is that the node of the minimum value loss difference sum under different system is divided by 2 for loss value in same grouping is the node of maximal value and loss value;

Step v, poor according to described average loss, obtain and the power splitter respectively dividing into groups to match when prime or coupling mechanism, or adjust and each corresponding power splitter or parameter information of coupling mechanism of dividing into groups.

In order to solve the problems of the technologies described above, embodiments of the invention also provide a kind of generating apparatus of domestic aerial compartment system system diagram, wherein, comprising:

First acquisition module, for obtaining the planimetric map of a domestic aerial compartment system;

Second acquisition module, for obtaining the device information in described planimetric map;

3rd acquisition module, for processing described device information, obtains result;

Generation module, for according to described result, generates and adapts to many system diagrams for the domestic aerial compartment system of communication system.

Wherein, described second acquisition module comprises:

First obtains submodule, at least comprises antenna node quantity information in described planimetric map and each antenna node the first device information at the loss value of different system for obtaining; And/or

Second obtains submodule, for obtaining the second device information being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism grouping information by virtual information source at least comprised in antenna node grouping information in described planimetric map and described planimetric map.

Wherein, described 3rd acquisition module comprises:

3rd obtains submodule, for carrying out packet transaction to the antenna node in described first device information, obtaining and adapting to many group result for the antenna node of communication system.

Wherein, described 3rd acquisition submodule comprises:

First acquiring unit, for according to the loss value information of each antenna node in described first device information in different system, obtains the loss value of each antenna node at current system;

Second acquisition unit, for according to the loss value of each antenna node at current system, sorts the antenna node in described planimetric map at current system according to loss value order from small to large or from large to small, and what obtain current system works as prime sequence node; Wherein, described when prime sequence node be antenna node sequence;

3rd acquiring unit, for dividing into groups according to the order of sequence to the node of working as in prime sequence node of current system, obtains when the node in prime sequence node is in the packet conditions information of current system; Wherein, described packet conditions information at least comprises: the nodal information of the described node when in prime sequence node in the grouping group number information of current system and current system are respectively divided into groups; Described nodal information at least comprises number of nodes information; And each grouping internal loss value is the node of maximal value and loss value is that the loss difference of the node of minimum value is less than loss difference threshold value;

4th acquiring unit, for according to the packet conditions information of the node in antenna node sequence in each system, node in described antenna node sequence is divided into groups according to the order of sequence again, obtain the many new packet conditions information for communication system of adaptation of antenna node sequence interior joint, and using described new grouping information as current group condition information; Wherein, described current group condition information at least comprises: the nodal information in grouping group number information and each grouping; The new current group condition information of the antenna node sequence of each system is consistent; The loss difference of to be the node of maximal value and loss value the be node of minimum value of the loss value in each grouping is less than described loss difference threshold value.

Wherein, described 3rd acquiring unit comprises:

First obtains subelement, for using current system when first node in prime sequence node is as start node, what obtain described start node and current system works as the first loss difference of the present node in prime sequence node at current system;

Second obtains subelement, for being less than described loss difference threshold value in described first loss difference, and described start node and the next current system adjacent with described present node when the second loss difference of the node in prime sequence node is greater than described loss difference threshold value, it is one group by described start node to whole node division of described present node, and obtain the residue sequence node of current system, and described residue sequence node is worked as prime sequence node as the new of current system;

First iteron unit, complete in current system grouping to the described second node of step to described antenna node sequence obtained performed by subelement for repeating the described first step obtained performed by subelement, obtain the packet conditions information of the node in described antenna node sequence at current system.

Wherein, described 4th acquiring unit comprises:

3rd obtains subelement, for according to the packet conditions information of the node in antenna node sequence in each system, obtains the nodal information in the first grouping under different system of node in described antenna node sequence;

4th obtains subelement, for retrieving respectively the node of described antenna node sequence interior joint in the first grouping of each system, obtain the maximum common subset of the first grouping interior nodes, and be one group by the node division in described maximum common subset, form new first grouping;

5th obtains subelement, for obtaining when prime newly remains sequence node, and using described new residue sequence node as one newly when prime sequence node;

Second iteron unit, complete in current system grouping to the described second node of step to described new residue sequence node obtained performed by subelement for repeating the described first step obtained performed by subelement, obtain the grouping group number of node under different system in described new residue sequence node;

6th obtains subelement, for when the value of described grouping group number is positive integer, obtains the nodal information in the first grouping under different system of node in described new residue sequence node;

7th obtains subelement, for to described new residue sequence node interior joint under each system first grouping in node retrieve, obtain the maximum common subset of the first grouping interior nodes, and be one group by the node division in described maximum common subset, form new first grouping;

3rd repeats subelement, obtain step performed by subelement and obtain step performed by subelement to the new grouping information of adaptation multisystem getting antenna node sequence interior joint for repeating the described 5th to the described 7th, and using described new grouping information as current group condition information.

Wherein, described generation module comprises:

First generates submodule, for the group result according to the many antenna nodes for communication system of described adaptation, generates and adapts to many domestic aerial compartment system device hubbed mode system diagrams for communication system.

Wherein, described first generation submodule comprises:

Allocation units, for according to the number of nodes information in each grouping in current group condition information, for each grouping correspondence distributes power splitter or coupling mechanism, and form next stage sequence node, and described next stage sequence node are worked as prime sequence node as new; Wherein, the quantity of described next stage sequence node interior joint is consistent with the grouping group number in current group condition information;

5th acquiring unit, for obtaining the loss value of described next stage sequence node interior joint;

6th acquiring unit, for the loss value according to described next stage sequence node interior joint, node in described next stage sequence node is arranged according to the order that loss value is descending or ascending, and the step performed performed by described 3rd acquiring unit, obtain the packet conditions information of described next stage sequence node interior joint, and using the packet conditions information of described next stage sequence node interior joint as new current group condition information;

Repetitive, for repeating the step of step extremely performed by described 6th acquiring unit performed by described allocation units, is 1 to the new quantity when prime sequence node interior joint formed.

Wherein, described allocation units comprise:

First planning subelement, when being 1 for the number of nodes within dividing into groups when prime one, using described node within prime one is divided into groups as the node in next stage sequence node; And/or

Second planning subelement, during for the number of nodes within dividing into groups when prime one for being greater than 1, according to described number of nodes within prime one is divided into groups, to divide into groups corresponding distribution power splitter or coupling mechanism when prime one for described, and forming next stage sequence node; Wherein, described number of nodes is positive integer; Described next stage sequence node comprises power splitter node and/or coupler nodes.

Wherein, described 3rd acquisition module comprises:

4th obtains submodule, for in described second device information be connected to by virtual information source power splitter that antenna node respectively divides into groups and/or coupling mechanism is replaced, or parameter adjustment is carried out to described power splitter and/or coupling mechanism, obtain and adapt to many be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system.

Wherein, described generation module comprises:

Second generates submodule, for being connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system according to the adaptation of described acquisition is many, generating and adapting to many domestic aerial compartment system device discrete pattern system diagrams for communication system.

Wherein, described second generation submodule comprises:

7th acquiring unit, to be in each grouping of prime each node at the loss value of current system for obtaining; Wherein, described node is antenna node or coupler nodes or power splitter node;

8th acquiring unit, for obtaining the loss difference of node at current system that node that described loss value within prime is respectively divided into groups is maximal value and loss value are minimum value;

9th acquiring unit, for obtain described when respectively the divide into groups average loss of interior joint of prime poor; Wherein, the average loss difference of each grouping interior joint is that the node of the minimum value loss difference sum under different system is divided by 2 for loss value in same grouping is the node of maximal value and loss value;

Tenth acquiring unit, for poor according to described average loss, obtain and the power splitter respectively dividing into groups to match when prime or coupling mechanism, or adjusts and each corresponding power splitter or parameter information of coupling mechanism of dividing into groups.

The invention has the beneficial effects as follows:

To sum up, the system diagram that the solution of the present invention generates, can adapt to many for communication system, avoid the drawback that system diagram is in the past only applicable to generation communication system;

The system diagram that the solution of the present invention generates, comprises device hubbed mode system and device discrete pattern system diagram, and adaptability is stronger, can meet the demand of various engineering practice.

Accompanying drawing explanation

Fig. 1 represents domestic aerial compartment system system map generalization method flow schematic diagram of the present invention;

Fig. 2 represents the hierarchical definition of device hubbed mode system diagram antenna/device;

Fig. 3 represents the hierarchical definition of device discrete pattern system diagram antenna/device;

Fig. 4 represents in domestic aerial compartment system device hubbed mode system map generalization method of the present invention and carries out adapting to many schematic flow sheets for the grouping of communication system to domestic aerial node;

Fig. 5 represents the schematic flow sheet of step c in Fig. 4;

Fig. 6 represents the schematic flow sheet of steps d in Fig. 4;

Fig. 7 represents the product process schematic diagram of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Fig. 8 represents that in specific embodiments of the invention, antenna node carries out the antenna node sequence diagram sorted from small to large according to loss value in 2G system and 3G system;

Fig. 9 represents power splitter composite type schematic diagram;

Figure 10 represents the adaptation generated in specific embodiments of the invention many groupings of the antenna node for communication system schematic diagram;

Figure 11 represent second level node in specific embodiments of the invention sort from small to large according to loss value after schematic diagram;

Figure 12 represents the domestic aerial compartment system device hubbed mode system diagram intention in specific embodiments of the invention;

Figure 13 represents the many schematic flow sheets being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism distributed intelligence by virtual information source for communication system of the adaptation obtained in specific embodiments of the invention;

Figure 14 represent domestic aerial compartment system in specific embodiments of the invention be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence schematic diagram one that antenna node respectively divides into groups;

Figure 15 represent domestic aerial compartment system in specific embodiments of the invention be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence schematic diagram two that antenna node respectively divides into groups;

Figure 16 represent domestic aerial compartment system in specific embodiments of the invention be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence schematic diagram three that antenna node respectively divides into groups;

Figure 17 represents the generating apparatus structural representation of domestic aerial compartment system system diagram of the present invention;

Figure 18 represents the generating apparatus structural representation one of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Figure 19 represents the generating apparatus structural representation two of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Figure 20 represents the generating apparatus structural representation three of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Figure 21 represents the generating apparatus structural representation four of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Figure 22 represents the generating apparatus structural representation five of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Figure 23 represents the generating apparatus structural representation six of domestic aerial compartment system device hubbed mode system diagram of the present invention;

Figure 24 represents the generating apparatus structural representation one of domestic aerial compartment system device discrete pattern system diagram of the present invention;

Figure 25 represents the generating apparatus structural representation two of domestic aerial compartment system device discrete pattern system diagram of the present invention;

Figure 26 represents the generating apparatus structural representation three of domestic aerial compartment system device discrete pattern system diagram of the present invention.

Embodiment

For making the object, technical solutions and advantages of the present invention clearly, describe the present invention below in conjunction with the accompanying drawings and the specific embodiments.

As shown in Figure 1, embodiments of the invention provide a kind of domestic aerial compartment system system map generalization method, and wherein, the method comprises the steps:

Step 11, obtains the planimetric map of a domestic aerial compartment system;

Step 12, obtains the device information in described planimetric map;

Step 13, processes described device information, obtains result;

Step 14, according to described result, generates and adapts to many system diagrams for the domestic aerial compartment system of communication system.

Wherein, in engineering practice, differently with the attention rate of the cost Discussing Convenience of later maintenance cause two kinds of different domestic aerial compartment system mentalities of designing for dropping into preliminary engineering: according to planimetric map generating device hubbed mode system diagram and the device discrete pattern system diagram of domestic aerial compartment system.Wherein, planimetric map, as its name suggests, react domestic aerial compartment system (hereinafter referred to as room subsystem) the multinomial details in buildings plane, as the kind of antenna, the distributed points position of antenna in buildings plane, route from the information source (or virtual information source) of flat bed to the feeder line conduct of antenna, and the device that the room subsystem that may use in flat bed can use, as power splitter, coupling mechanism etc. and present position thereof.

Planimetric map cloth on the map basis of reaction buildings planar structure is placed with the feeder line etc. of information source (virtual information source), antenna and other device, interface unit.

Wherein, device hubbed mode: refer in buildings flat bed, all devices except antenna are placed between light current or certain/place, a few place.There is independent feeder line to be connected from buildings flat bed information source to each antenna.Wherein, in device hubbed mode system diagram, the hierarchical definition of antenna and device (power splitter and/or coupling mechanism), as shown in Figure 2.

Device discrete pattern: refer to out only have a feeder line to be connected with a certain device from buildings flat bed information source, signal is connected multiple device or antenna through feeder line by multiple output terminal by this device, the subsequent device by that analogy extremely final device connected is antenna.Wherein, in device discrete pattern system diagram, the hierarchical definition of antenna and device (power splitter and/or coupling mechanism), as shown in Figure 3.

Below in conjunction with accompanying drawing and specific embodiment, the hubbed mode system map generalization of domestic aerial compartment system device and the map generalization of device discrete pattern system are described in detail respectively.

First by reference to the accompanying drawings and specific embodiment the map generalization of domestic aerial compartment system device hubbed mode system is described in detail.

The first step, obtains the planimetric map of a domestic aerial compartment system;

Second step, obtains the antenna node quantity information that at least comprises in described planimetric map and each antenna node the first device information at the loss value of different system;

3rd step, carries out packet transaction to the antenna node in described first device information, obtains and adapts to many group result for the antenna node of communication system.

4th step, according to the group result of the many antenna nodes for communication system of described adaptation, generates and adapts to many domestic aerial compartment system device hubbed mode system diagrams for communication system.

Wherein, the step of the 3rd step as shown in Figure 4, comprising:

Wherein, as shown in Figure 5, this step c comprises the steps:

Step f, described loss difference threshold value is less than in described first loss difference, and described start node and the next current system adjacent with described present node when the second loss difference of the node in prime sequence node is greater than described loss difference threshold value, it is one group by described start node to whole node division of described present node, and obtain the residue sequence node of current system, and described residue sequence node is worked as prime sequence node as the new of current system;

Wherein, this steps d, as shown in Figure 6, also comprises the steps:

Wherein, as shown in Figure 7, the 4th step, according to the group result of the many antenna nodes for communication system of described adaptation, generates the many steps for the domestic aerial compartment system device hubbed mode system diagram of communication system of adaptation and comprises:

Wherein, according to the number of nodes information in each grouping in current group condition information in this step o, for the corresponding step of distributing power splitter or coupling mechanism of each grouping comprises:

Below in conjunction with accompanying drawing and specific embodiment, the above-mentioned first step is described in detail to the 4th step:

(1) planimetric map of a domestic aerial compartment system, is first obtained;

(2), according in Fig. 2 to the hierarchical definition of antenna/device in device hubbed mode system diagram, obtain the antenna node quantity information being positioned at the first order that at least comprises in this planimetric map and each antenna node the first device information at the loss value of different system (for 2 systems and 3G system), in a particular embodiment of the present invention, if the quantity getting the antenna node being positioned at the first order is 8, be respectively antenna node a1, antenna node a2, antenna node a3, antenna node a4, antenna node a5, antenna node a6, antenna node a7, antenna node a8, in engineering practice, consider coverage effect as a whole, economic benefit, and the electromagnetic radiation factor such as safely, can there be certain requirement in operator to the radiation power of antenna each in domestic aerial subsystem usually, each antenna opening power answers [8dBm, 12dBm] scope in, if if each antenna node is different respectively at the loss value of 2G system, be respectively 4.2dB, 6.1dB, 2.3dB, 2.9dB, 7.2dB, 5.6dB, 8.0dB, 3.6dB, each antenna node is also different respectively at the loss value of 3G system, is respectively 5.3dB, 7.9dB, 3.2dB, 3.9dB, 9.3dB, 7.2dB, 10.5dB, 4.7dB.

(3), by these 8 antenna nodes in 2G system and 3G system, the order ascending according to loss value arranges, and obtains the antenna node sequence A=(A1 of antenna node respectively under 2G system and 3G system as shown in Figure 8, A2, A3, A4, A5, A6, A7, A8); Wherein, A1, A2, A3, A4, A5, A6, A7, A8 and a3, a4, a8, a1, a6, a2, a5, a7 are corresponding respectively.

(4), carry out first time grouping to this sequence A in 2G system, rule of classification is that concrete grouping step is as follows: suppose that loss difference threshold value is 2dB according to loss difference threshold value,

1), using the antenna node A1 in A as start node, obtaining the loss difference of this antenna node A1 and antenna node A2, is 0.6dB, is less than loss difference threshold value;

2), obtain the loss difference of antenna node A1 and antenna node A3, be 1.3dB, be less than loss difference threshold value;

3), obtain the loss difference of antenna node A1 and antenna node A4, be 1.9dB, be less than loss difference threshold value;

4), obtaining the loss difference of antenna node A1 and antenna node A5, is 3.3dB, be greater than loss difference threshold value, then by antenna node A1, antenna node A2, antenna node A3, antenna node A4 is divided into one group, forms the first child node sequence (the first grouping) B1=(A1, A2, A3, A4), residue antenna node A5, antenna node A6, antenna node A7, antenna node A8; By antenna node A5, antenna node A6, antenna node A7, antenna node A8 form new antenna node sequence;

5), using this antenna node A5 as the new start node in new antenna node sequence, obtain antenna node A5 and antenna node A6 loss difference, be 0.5dB, be less than loss difference threshold value;

6), obtain the loss difference of antenna node A5 and antenna node A7, be 1.6dB, be less than loss difference threshold value;

7), obtaining the loss difference of antenna node A5 and antenna node A8, is 2.4dB, be greater than loss difference threshold value, then by antenna node A5, A6, A7 is divided into one group, forms the second child node sequence (the second grouping) B2=(A5, A6, A7), residue antenna node A8, is divided into separately one group by antenna node 8, form the 3rd child node sequence (the 3rd grouping) B3, wherein, antenna node sequence A=(B1, B2, B3).This sequence A is divided into groups complete in 2G system first time.

(5), in 3G system, first time grouping is carried out to this sequence A, rule of classification is also according to loss difference threshold value (2dB), concrete grouping step rule is identical with the rule that this sequence A carries out dividing into groups for the first time in 2G system, be not described in detail at this, suppose that this antenna node sequence A is divided into 4 groups of child node sequences under 3G system, be respectively the first grouping C1=(A1, A2, A3), second grouping C2=(A4, A5), 3rd grouping C3=(A6, A7), 4th grouping C4=(A8), wherein, antenna node sequence A=(C1, C2, C3, C4).

(6), node in first grouping of antenna node in acquisition antenna node sequence A respectively under 2G system and 3G system, obtain the maximum common subset (A1 of the first grouping interior nodes, A2, A3), and be one group by the node division in this maximum common subset, form the first grouping D1=(A1 adapting to this 2G system and this 3G system, A2, A3).

(7), obtain except this antenna node A1, A2, new remaining antenna node A4 outside A3, A5, A6, A7, A8, and according in (four) and (five), antenna node sequence being carried out to the grouping step of first time grouping, to this new remaining antenna node A4, A5, A6, A7, A8 divides into groups again in 2G system and 3G, obtain this new remaining antenna node A4, A5, A6, A7, the grouping of A8 under 2G system and 3G system: this new remaining antenna node A4, A5, A6, A7, A8 being grouped under 2G system: new first grouping (A4, A5, A6), new second grouping (A7, A8), this new remaining antenna node A4, A5, A6, A7, A8 being grouped under 3G system: new first grouping (A4, A5), new second grouping (A6, A7), new 3rd grouping (A8).

(8), obtain the maximum common subset (A4, A5) of new first grouping interior nodes, form the second grouping D2=(A4, A5) adapting to this 2G system and this 3G system.

(9), according to above-mentioned rule, to getting the grouping information adapting to this 2G system and this 3G system: the first grouping D1=(A1, A2, A3), the second grouping D2=(A4, A5), the 3rd grouping D3=(A6, A7), the 4th grouping D4=(A8).

(10), be above-mentioned each grouping D1, D2, D3, D4, according to the power splitter composite type suggested design in Fig. 9, corresponding distribution power splitter, allocation rule is as follows:

Adapt in antenna node grouping D1, D2, D3, D4 of 2G system and 3G system, if element number is greater than 1 in grouping, then according to grouping in element number by Fig. 9 (this rule do not limit grouping interior element number, during more than 20, can simply augment according to Fig. 9) (power splitter generally used at present is that two merits are divided, three merits are divided, four merits are divided to choose suitable power splitter, as WeiLai Technology, device allows to use the more power splitter of port, as five merits divide, six merits divide.)。Wherein, in this Fig. 9, the combination of power splitter only represents model combination, does not represent the order that power splitter uses, such as: 4+3 only represents four merits and divides and add three merits and divide, and does not represent and first uses 4 merits to divide, re-use three merits and divide.

(11), according to as above allocation rule and Fig. 9, are that grouping D1, D2, D3, D4 correspondence distributes suitable power splitter.As shown in Figure 10, for grouping D1 distributes one or three power splitters, one or two power splitters are distributed for grouping D2 and grouping D3 is corresponding respectively, owing to only having an element in grouping D4, therefore not for this grouping distributes power splitter, these three power splitter nodes and this elements A 8 are formed second level node and is respectively E1, E2, E3, E4 (corresponding to A8).

(12), obtain this three second level node E1, E2, E3, the loss value of E4 (corresponding to A8) respectively under 2G system and 3G system, wherein, the computing method of the loss value of three power splitter nodes are: the power of power splitter delivery outlet (being (in grouping in antenna minimal losses+grouping antenna maximum loss)/2 in a particular embodiment of the present invention)+device loss, wherein this device loss is power division loss and insertion loss sum, because this insertion loss is far smaller than power division loss, therefore this insertion loss can be ignored, so device loss is power division loss, wherein, the computing method of this device loss are: for power splitter, to N number of output terminal power input average mark, therefore the power of each output terminal only has the 1/N of input end, this power division loss is 10lg (N) dB, therefore the device loss for two power splitters is 3.0dB, three power splitters are 5.0dB, four power splitters are 6.0dB.Therefore, the loss value of node E1 is under 2G system: loss value (5.0dB)=(the 2.3dB+3.6dB)/2+5.0dB=8.0dB of (loss value of the loss value+antenna node A3 of antenna node A1)/2+ tri-power splitter part; The loss value of node E1 is under 3G system: (loss value of the loss value+antenna node A3 of antenna node A1)/2+ (loss values (5.0dB) of three power splitter parts)=(3.2dB+4.7dB)/2+5.0dB=9.0dB; According to the loss value of above-mentioned node E1 in the computing method of 2G system and 3G system, computing node E2, E3 respectively) loss value respectively under 2G system and 3G system, get the loss value of E2 under 2G system and 3G system and be respectively 7.9dB and 9.3dB; The loss value of E3 under 2G system and 3G system is respectively 9.7dB and 11.6dB; Wherein, the loss value of E4 (corresponding to A8) under 2G system and 3G system is still respectively 8.0dB and 10.5dB.

(12), by node E1, E2, E3, E4 according to the loss value under 2G system or the loss value under 3G system, rearrange according to loss value order from small to large, get rearranged result as shown in figure 11.Order is followed successively by E1, E2, E4, E3.

(13), according to the rule that (four) or (five) divide into groups to antenna node, to this second level node E1, E2, E4, E3 carries out packet transaction (rule of classification and the first time rule of classification of antenna node under 2G system or 3G system similar), because these four nodes loss difference between any two is all less than loss difference threshold value, therefore, can by four of this second level node E1, E2, E4, E3 is divided into one group, as shown in figure 12, for this component joins one or four power splitters (using this four power splitter as third level node), form a P tie point (flat bed information source/virtual information source).

Certainly, if there is fourth stage node and level V node etc. by that analogy backward, then must calculate the loss value of third level node, the loss value of each third level node=(in grouping in the minimal losses+grouping of the second level node second level node maximum loss)/2+ corresponding third level node power splitter loss, similar with the loss value computing method of power splitter node in the node of the second level, the loss value of power splitter node at different levels by that analogy backward.

Certainly, due to the power splitter port used at present maximum be that four merits are divided, therefore, no matter be the grouping of antenna node or the grouping of power splitter at different levels, if grouping interior joint quantity is more than 4, then be divided into one group by first four, then remaining node divided into groups again, do not repeat them here the grouping flow process of the concrete grouping flow process of antenna node and power splitter at different levels.

To sum up to adapting to many detailed descriptions for the domestic aerial compartment system device hubbed mode system map generalization of communication system, being described in detail the map generalization of domestic aerial compartment system device discrete pattern system below in conjunction with accompanying drawing and specific embodiment.

5th step, obtains the planimetric map of a domestic aerial compartment system;

6th step, obtains the second device information being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism grouping information by virtual information source in the antenna node grouping information that at least comprises in described planimetric map and described planimetric map;

7th step, to in described second device information be connected to by virtual information source power splitter that antenna node respectively divides into groups and/or coupling mechanism is replaced, or parameter adjustment is carried out to described power splitter and/or coupling mechanism, obtain and adapt to many be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system;

8th step, is connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system according to the adaptation of described acquisition is many, generates and adapt to many domestic aerial compartment system device discrete pattern system diagrams for communication system.

Wherein, the many steps being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism distributed intelligence by virtual information source for communication system of the adaptation obtained in the 7th step or the 8th step, as shown in figure 13, comprising:

Below in conjunction with accompanying drawing and specific embodiment, above-mentioned 4th step is described in detail to the 8th step:

1, first obtain the planimetric map of a domestic aerial compartment system;

2, according in Fig. 3 to the hierarchical definition of antenna/device in device discrete pattern system diagram, obtain and be connected to by the virtual information source being positioned at the first order power splitter at different levels and/or coupling mechanism grouping information that the antenna node that is positioned at afterbody respectively divides into groups;

In a particular embodiment of the present invention, as shown in figure 14, if the quantity being positioned at the antenna node of the third level (afterbody) is 4, b1 is respectively, b2, b3, b4; Being grouped into of antenna: b1, b2 are divided into the first grouping, b3, b4 are divided into the second grouping.First to divide into groups one or two power splitters for being positioned at the second level that are connected with this, with this second divide into groups to be connected also for being positioned at one or two power splitters of the second level; These two two power splitters are divided into one group, and connect through one or two power splitters being positioned at the first order, form P tie point (flat bed information source/virtual information source).

3, obtain the antenna node b1 of the first grouping being positioned at the third level, the antenna node b3 in b2 and second grouping, the loss value of b4 under different system (for 2G system and 3G system);

If get antenna node b1, b2 loss value under 2G system to be respectively 5.6dB and 7.2dB, antenna node b3, b4 loss value under 2G system is respectively 8.0dB and 8.2dB; This antenna node b1, b2 loss value under 3G system is respectively 6.8dB and 9.3dB, antenna node b3, b4 loss value under 3G system 11.0dB and 11.5dB respectively;

4, to obtain the antenna node loss value being arranged in each grouping of the third level be maximum node and loss value is the minimum node loss difference at current system;

In a particular embodiment of the present invention, in the antenna node in this first grouping, loss value be maximum node is b2, and loss value is minimum node be b1, b1 and the b2 loss difference under 2G system is 1.6dB, and the loss difference under 3G system is 2.5dB; In antenna node in this second grouping, loss value be maximum node is b4, and loss value is minimum node be b3, b3 and the b4 loss difference under 2G system is 0.2dB, and the loss difference under 3G system is 0.5dB;

5, obtain the average loss being arranged in the antenna node of each grouping of the third level poor;

Wherein, in each grouping, the average loss difference of antenna node is that the node of the minimum value loss difference sum under different system is divided by 2 for loss value in same grouping is the node of maximal value and loss value; In a particular embodiment of the present invention, in this first grouping, the average loss difference of antenna node is: (1.6dB+2.5dB)/2=2.1dB; In this second grouping, the average loss difference of antenna node is: (0.2dB+0.5dB)/2=0.4dB;

6, adjustment and this third level respectively divide into groups the power splitter that is connected;

Because the average loss difference of antenna node is 2.1dB in this first grouping, be greater than 2dB, therefore should select that three-dB coupler replacement is original is positioned at first dividing into groups two power splitters that are connected with this of the second level; In this second grouping, the average loss difference of antenna node is 0.5dB, is less than 2dB, therefore retains originally to be positioned at second dividing into groups two power splitters that are connected with this of the second level;

The device being now positioned at the second level upgrades to some extent, and as shown in figure 15, the new node of this second level is respectively a three-dB coupler node and one or two power splitter nodes; This three-dB coupler node and this two power splitter form new grouping;

7, obtain the loss value of node under 2G system and 3G system being arranged in second level grouping;

Obtain this three-dB coupler node and this two power splitters node, the loss value under 2G system and 3G system; This three-dB coupler (straight-through loss is 2dB, and degree of coupling loss the is 3dB) loss value of node under 2G system is: (output power (if being the loss value of b2 under 2G the system)+degree of coupling loss of output power (if being the loss value of b1 under 2G the system)+straight-through loss+coupled end of straight-through end)/2=8.9dB; The loss value of this three-dB coupler node under 3G system is: (output power (if being the loss value of b2 under G the system)+degree of coupling loss of output power (if being the loss value of b1 under 3G the system)+straight-through loss+coupled end of straight-through end)/2=10.6dB; This two power splitter (loss value the is 3dB) loss value of node under 2G system is: (loss value+b4 loss value under 2G system of b3 under 2G system)/2+ bis-power splitter part loss value=11.1dB; The loss value of this two power splitters node under 3G system is: (loss value+b4 loss value under 3G system of b3 under 3G system)/2+ bis-power splitter part loss value=14.3dB;

8, to obtain the node loss value being arranged in the grouping of the second level be maximum node and loss value is the minimum node loss difference at current system;

In a particular embodiment of the present invention, in node in this grouping, loss value is maximum node is two power splitter nodes, loss value is minimum node is this coupler nodes, this two power splitter and the loss difference of this coupling mechanism under 2G system are 2.2dB, and the loss difference under 3G system is 3.7dB;

9, the average loss obtaining the node being arranged in second level grouping is poor;

Wherein, the average loss difference of interior joint of dividing into groups is that the node of the minimum value loss difference sum under different system is divided by 2 for loss value in same grouping is the node of maximal value and loss value; In a particular embodiment of the present invention, in this grouping, the average loss difference of antenna node is: (2.2dB+3.7dB)/2=3.0dB;

10, divide into groups the power splitter be connected for adjustment and this second level;

Because the average loss difference of this second level grouping interior joint is 3.0dB, three-dB coupler therefore should be selected to replace original two power splitters be connected with the grouping of this second level being positioned at the first order.

To sum up 1 to 10 completes domestic aerial compartment system device discrete pattern system diagram, generates and adapts to many device discrete pattern system diagrams for the domestic aerial compartment system of communication system as shown in figure 16.

As shown in figure 17, embodiments of the invention provide a kind of generating apparatus of domestic aerial compartment system system diagram, wherein, comprising:

First acquisition module 170, for obtaining the planimetric map of a domestic aerial compartment system;

Second acquisition module 171, for obtaining the device information in described planimetric map;

3rd acquisition module 172, for processing described device information, obtains result;

Generation module 173, for according to described result, generates and adapts to many system diagrams for the domestic aerial compartment system of communication system.

Wherein, described second acquisition module 171, comprising:

Wherein, described 3rd acquisition module 172, as shown in figure 18, comprising:

3rd obtains submodule 180, for carrying out packet transaction to the antenna node in described first device information, obtaining and adapting to many group result for the antenna node of communication system.

Wherein, the described 3rd obtains submodule 180, as shown in figure 19, comprising:

First acquiring unit 190, for according to the loss value information of each antenna node in described first device information in different system, obtains the loss value of each antenna node at current system;

Second acquisition unit 191, for according to the loss value of each antenna node at current system, sorted at current system according to loss value order from small to large or from large to small by antenna node in described planimetric map, what obtain current system works as prime sequence node; Wherein, described when prime sequence node be antenna node sequence;

3rd acquiring unit 192, for dividing into groups according to the order of sequence to the node of working as in prime sequence node of current system, obtains when the node in prime sequence node is in the packet conditions information of current system; Wherein, described packet conditions information at least comprises: the nodal information of the described node when in prime sequence node in the grouping group number information of current system and current system are respectively divided into groups; Described nodal information at least comprises number of nodes information; And each grouping internal loss value is the node of maximal value and loss value is that the loss difference of the node of minimum value is less than loss difference threshold value;

4th acquiring unit 193, for according to the packet conditions information of the node in antenna node sequence in each system, node in described antenna node sequence is divided into groups according to the order of sequence again, obtain the many new packet conditions information for communication system of adaptation of antenna node sequence interior joint, and using described new grouping information as current group condition information; Wherein, described current group condition information at least comprises: the nodal information in grouping group number information and each grouping; The new current group condition information of the antenna node sequence of each system is consistent; The loss difference of to be the node of maximal value and loss value the be node of minimum value of the loss value in each grouping is less than described loss difference threshold value.

Wherein, described 3rd acquiring unit 192, as shown in figure 20, comprising:

First obtains subelement 200, for using current system when first node in prime sequence node is as start node, what obtain described start node and current system works as the first loss difference of the present node in prime sequence node at current system;

Second obtains subelement 201, for being less than described loss difference threshold value in described first loss difference, and described start node and the next current system adjacent with described present node when the second loss difference of the node in prime sequence node is greater than described loss difference threshold value, it is one group by described start node to whole node division of described present node, and obtain the residue sequence node of current system, and described residue sequence node is worked as prime sequence node as the new of current system;

First iteron unit 202, complete in current system grouping to the described second node of step to described antenna node sequence obtained performed by subelement for repeating the described first step obtained performed by subelement, obtain the packet conditions information of the node in described antenna node sequence at current system.

Wherein, described 4th acquiring unit 193, as shown in figure 21, comprising:

3rd obtains subelement 210, for according to the packet conditions information of the node in antenna node sequence in each system, obtains the nodal information in the first grouping under different system of node in described antenna node sequence;

4th obtains subelement 211, for retrieving respectively the node of described antenna node sequence interior joint in the first grouping of each system, obtain the maximum common subset of the first grouping interior nodes, and be one group by the node division in described maximum common subset, form new first grouping;

5th obtains subelement 212, for obtaining when prime newly remains sequence node, and using described new residue sequence node as one newly when prime sequence node;

Second iteron unit 213, complete in current system grouping to the described second node of step to described new residue sequence node obtained performed by subelement for repeating the described first step obtained performed by subelement, obtain the grouping group number of node under different system in described new residue sequence node;

6th obtains subelement 214, for when the value of described grouping group number is positive integer, obtains the nodal information in the first grouping under different system of node in described new residue sequence node;

7th obtains subelement 215, for to described new residue sequence node interior joint under each system first grouping in node retrieve, obtain the maximum common subset of the first grouping interior nodes, and be one group by the node division in described maximum common subset, form new first grouping;

3rd repeats subelement 216, obtain step performed by subelement and obtain step performed by subelement to the new grouping information of adaptation multisystem getting antenna node sequence interior joint for repeating the described 5th to the described 7th, and using described new grouping information as current group condition information.

Wherein, described generation module 173, as shown in figure 22, comprising:

First generates submodule 220, for the group result according to the many antenna nodes for communication system of described adaptation, generates and adapts to many domestic aerial compartment system device hubbed mode system diagrams for communication system.

Wherein, described first generates submodule 220, as shown in figure 23, comprising:

Allocation units 230, for according to the number of nodes information in each grouping in current group condition information, for each grouping correspondence distributes power splitter or coupling mechanism, and form next stage sequence node, and described next stage sequence node are worked as prime sequence node as new; Wherein, the quantity of described next stage sequence node interior joint is consistent with the grouping group number in current group condition information;

5th acquiring unit 231, for obtaining the loss value of described next stage sequence node interior joint;

6th acquiring unit 232, for the loss value according to described next stage sequence node interior joint, node in described next stage sequence node is arranged according to the order that loss value is descending or ascending, and the step performed performed by described 3rd acquiring unit, obtain the packet conditions information of described next stage sequence node interior joint, and using the packet conditions information of described next stage sequence node interior joint as new current group condition information;

Repetitive 233, for repeating the step of step extremely performed by described 6th acquiring unit performed by described allocation units, is 1 to the new quantity when prime sequence node interior joint formed.

Wherein, described allocation units 230, comprising:

Wherein, described 3rd acquisition module 172, as shown in figure 24, comprising:

4th obtains submodule 240, for in described second device information be connected to by virtual information source power splitter that antenna node respectively divides into groups and/or coupling mechanism is replaced, or parameter adjustment is carried out to described power splitter and/or coupling mechanism, obtain and adapt to many be connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system.

Wherein, described generation module 173, as shown in figure 25, comprising:

Second generates submodule 250, for being connected to by virtual information source the power splitter and/or coupling mechanism distributed intelligence that antenna node respectively divides into groups for communication system according to the adaptation of described acquisition is many, generating and adapting to many domestic aerial compartment system device discrete pattern system diagrams for communication system.

Wherein, described second generates submodule 250, as shown in figure 26, comprising:

7th acquiring unit 260, to be in each grouping of prime each node at the loss value of current system for obtaining; Wherein, described node is antenna node or coupler nodes or power splitter node;

8th acquiring unit 261, for obtaining the loss difference of node at current system that node that described loss value within prime is respectively divided into groups is maximal value and loss value are minimum value;

9th acquiring unit 262, for obtain described when respectively the divide into groups average loss of interior joint of prime poor; Wherein, the average loss difference of each grouping interior joint is that the node of the minimum value loss difference sum under different system is divided by 2 for loss value in same grouping is the node of maximal value and loss value;

Tenth acquiring unit 263, for poor according to described average loss, obtain and the power splitter respectively dividing into groups to match when prime or coupling mechanism, or adjusts and each corresponding power splitter or parameter information of coupling mechanism of dividing into groups.

It should be noted that, this device is the device comprising said method, and the implementation of the embodiment of said method is applicable in the embodiment of this device, also can reach identical technique effect.

The above is only the preferred embodiment of the present invention; it should be pointed out that for those skilled in the art, under the premise without departing from the principles of the invention; can also make some improvements and modifications, these improvements and modifications also should be considered as protection scope of the present invention.

Claims

1. a domestic aerial compartment system system map generalization method, is characterized in that, comprising:

Obtain the planimetric map of a domestic aerial compartment system;

Obtain the device information in described planimetric map;

Described device information is processed, obtains result;

2. domestic aerial compartment system system map generalization method according to claim 1, it is characterized in that, the step of the device information in the described planimetric map of described acquisition comprises:

3. domestic aerial compartment system system map generalization method according to claim 2, is characterized in that, describedly processes described device information, and the step obtaining result comprises:

4. domestic aerial compartment system system map generalization method according to claim 3, it is characterized in that, described packet transaction is carried out to the antenna node in described first device information, obtains and adapt to many steps for the group result of the antenna node of communication system and comprise:

5. domestic aerial compartment system system map generalization method according to claim 4, it is characterized in that, in described step c, the node of working as in prime sequence node of described current system is divided into groups according to the order of sequence, obtains when the node in prime sequence node comprises in the step of the packet conditions information of current system:

6. domestic aerial compartment system system map generalization method according to claim 4, it is characterized in that, according to the packet conditions information of the node in antenna node sequence in each system in described steps d, node in described antenna node sequence is divided into groups according to the order of sequence again, obtain the new grouping information of the adaptation multisystem of antenna node sequence interior joint, and the step of described new grouping information as current group condition information comprised:

7. domestic aerial compartment system system map generalization method according to claim 4, is characterized in that, described according to described result, generates the many steps for the system diagram of the domestic aerial compartment system of communication system of adaptation and comprises:

8. domestic aerial compartment system system map generalization method according to claim 7, it is characterized in that, the described group result according to the many antenna nodes for communication system of described adaptation, generates the many steps for the domestic aerial compartment system device hubbed mode system diagram of communication system of adaptation and comprises:

9. domestic aerial compartment system system map generalization method according to claim 8, it is characterized in that, according to the number of nodes information in each grouping in current group condition information in described step o, for the corresponding step of distributing power splitter or coupling mechanism of each grouping comprises:

10. domestic aerial compartment system system map generalization method according to claim 2, is characterized in that, describedly processes described device information, and the step obtaining result comprises:

11. domestic aerial compartment system system map generalization methods according to claim 10, is characterized in that, described according to described result, generate the many steps for the system diagram of the domestic aerial compartment system of communication system of adaptation and comprise:

12. domestic aerial compartment system system map generalization methods according to claim 11, it is characterized in that, the many steps being connected to power splitter that antenna node respectively divides into groups and/or coupling mechanism distributed intelligence by virtual information source for communication system of the adaptation of described acquisition comprise:

The generating apparatus of 13. 1 kinds of domestic aerial compartment system system diagrams, is characterized in that, comprising: