KR102052940B1 - Broadband wireless communication frequency aggregation system used in buildings - Google Patents

Abstract

The present invention relates to a broadband wireless communication frequency aggregation system of a building. More particularly, the present invention relates to a broadband wireless communication frequency aggregation system capable of suppressing communication failure and improving communication speed by using different bundles when interference occurs due to overlapping frequencies. According to the present invention, the broadband wireless communication frequency aggregation system comprises: a first terminal performing communication using a first frequency block; a second terminal performing communication using a second frequency block; and a transmission server which communicates with the first and second terminals, and when interference occurs because at least some of frequencies in the first frequency block overlap at least some of frequencies in the second frequency block, allocates one or more third frequency blocks to the first terminal so that the one or more third frequency blocks can be bundled with the first frequency block for use.

Description

BROADBAND WIRELESS COMMUNICATION FREQUENCY AGGREGATION SYSTEM USED IN BUILDINGS}

The present invention relates to a broadband wireless communication frequency aggregation system of a building. More specifically, when interference occurs due to overlapping frequencies, a bundle of different frequencies can be used to suppress communication failures and improve communication speed. The present invention relates to a wideband wireless communication frequency-specific aggregation system.

Recently, due to the development of wireless communication technology, wireless communication is actively used in buildings and buildings.

Wireless communication is a communication technology that transmits information to a remote site without a wire connection by using radio waves, such as mobile communication technology. Radio waves are generally defined as electromagnetic waves having a frequency of 3000 GHz or less. When the frequency exceeds 3000 GHz, it enters the far-infrared region, which is out of the range of radio waves. Propagation is essentially a displacement current flowing between two conductors when they are connected to two opposing conductors. When these conductors are placed together with the antenna, they travel through the air as radio waves.

As wireless communication rapidly develops, wireless communication is widely used in buildings, buildings, and the like, and thus radio interference occurs.

Conventional technology (Patent No. 10-0290924) is to reduce radio interference in such a high-rise building, and more specifically, amplification of noise generated by amplifying a transmission signal by not amplifying a transmission signal of a terminal. Problems such as this do not occur. In other words, when a repeater using a bidirectional amplification repeater is used on the upper floor of a high-rise building, there is an effect of eliminating the problem of noise signal amplification on the surrounding base stations.

However, the prior art has a limitation in that it does not include a configuration for solving the problem of communication failure caused by overlapping frequency.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a broadband wireless communication frequency aggregation system of a building that can reduce the communication disturbance caused by overlapping frequency (block) in the building.

In addition, the present invention provides a broadband wireless communication frequency aggregation system of a building that can be used in combination with the frequency blocks in the non-contiguous frequency blocks or other frequency bands as well as adjacent frequency blocks in the engineer's frequency block. For the purpose of

The present invention for the purpose of solving the above problems has the following configuration and features.

The broadband wireless communication frequency-specific aggregation system of a building communicates with a first terminal for communicating using a first frequency block, a second terminal for communicating using a second frequency block, the first and second terminals, and the first terminal. If at least some of the frequencies in the frequency block overlap with at least some of the frequencies in the second frequency block, the at least one third frequency block is allocated to the first terminal to be bundled with the first frequency block. It includes a transmission server.

The transmission server may further include a contiguous frequency block in the frequency band including the first frequency block, a non-contiguous frequency block in the frequency band including the first frequency block, and the first frequency block. A frequency band aggregation system according to claim 1, wherein at least one of other band frequency blocks included in one or more frequency bands not including a frequency block is designated as a third frequency block.

The present invention having the above-described configuration and features has the effect of reducing the communication disturbance caused by the overlap between frequencies (blocks) in a building by using a frequency block in use with another frequency block.

In addition, the present invention can be used in combination with frequency blocks in the other frequency bands that do not include the frequency block that is continuous with the engineer's frequency block, as well as the frequency block that is not continuous with the driver's frequency block, and the frequency block that is for the operator's frequency. For example, if a frequency block in use interferes with another frequency block and a communication failure occurs, it can be flexibly bundled with other frequency blocks (contiguous frequency blocks, non-contiguous frequency blocks, and other band frequency blocks).

FIG. 1 is a schematic diagram illustrating communication with a transmission server using a first frequency block using a first frequency block and a second frequency block at least partially overlapping with a first terminal.
FIG. 2 is a schematic diagram illustrating a first frequency block, a second frequency block, a third frequency block, and a frequency band.
FIG. 3 is a schematic diagram of an aggregation system for broadband wireless communication frequencies in a building according to an embodiment of the present invention.
FIG. 4 is a schematic diagram illustrating a first terminal communicating with a transmission server using a third frequency block when the communication speed of the first terminal is less than a preset reference speed in FIG. 1.
5 is a view for explaining a protective film of the transmission server housing.

Since the present invention may be modified in various ways and have various forms, embodiments (or embodiments) will be described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

The terminology used herein is for the purpose of describing particular embodiments (suns, aspects, and embodiments) (or embodiments) only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms “comprises” or “consists” are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described on the specification, but one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

In the present specification, the first to the second and the second and the like are only referred to to distinguish between the different components, and are not limited to the order of manufacture, and their names are used in the description and the claims. It may not match.

Throughout this specification, when a part is "connected" to another part, it is not only "directly connected" but also "electrically connected" or "indirectly connected" with another element in between. "Includes the case.

Hereinafter, for convenience of description, an aggregation system for each frequency band wireless communication of a building according to an embodiment of the present application will be referred to as a 'main aggregation system'.

FIG. 1A is a schematic diagram for schematically describing communication with a transmission server using a first frequency block using a first frequency block and a second frequency block at least partially overlapping with a first terminal. 2 is a schematic diagram illustrating a first frequency block, a second frequency block, a third frequency block, and a frequency band.

1 and 2, the present aggregation system is a broadband wireless communication technology and system in a building, and includes a first terminal 1, a second terminal 2, and a transmission server 3.

The first terminal 1 can communicate with the transmission server 3 to be described later using the first frequency block 11, and the second terminal 2 uses the second frequency block 21 to transmit later. It can communicate with the server 3.

Herein, the terminal (the first terminal 1 and the second terminal 2) is used to communicate with the transmission server 3 to be described later using a specific frequency block, and includes various things such as mobile phones, smartphones, microphones, and TVs. Of course you can. In addition, the frequency blocks (the first frequency block 11, the second frequency block 21, and the third frequency block th (to be described in detail in the following description)) are each described by the transmission server 3 described later. As allocated to the terminal (the first terminal 1, the second terminal 2), it may mean a small region in the frequency band. In addition, the frequency block may mean a specific frequency (eg, 930 MHz).

Referring to FIG. 2 by way of example, the frequency first terminal 1 receives the first frequency block 11 having a width of 930 MHz to 950 MHz and communicates with the transmission server 3 (as described above, the frequency block is a specific frequency). It may mean only (in another example, the first frequency block 11 may mean 930 MHz). In addition, the second terminal 2 receives the second frequency block 21 having a width of 945MHz ~ 970MHz and communicates with the transmission server (3). The first frequency block 11 and the second frequency block 21 are included in the frequency band of 900MHz.

3 is a schematic diagram of an aggregation system for each frequency band wireless communication of a building according to an embodiment of the present invention.

1 to 3, the transmission server 3 of the present aggregation system communicates with the first terminal 1 and the second terminal 2, respectively, and at least a part of the frequencies in the first frequency block 11 In the case where interference occurs by overlapping at least a portion of frequencies in the second frequency block 21, one or more third frequency blocks th may be added to the first terminal 1 to be bundled with the first frequency block 11. Assign.

2 and 3, the first terminal 1 may be a communication device (smartphone) assigned with the first frequency block 11 having a width of 930 MHz to 950 MHz, and the second terminal ( 2) may be a microphone allocated with the second frequency block 21 having a width of 945 MHz to 950 MHz. As described above, when at least a portion of each of the first frequency block 11 and the second frequency block 21 is overlapped with each other and interference occurs, the communication speed between the first terminal 1 and the transmission server 3 may decrease. Therefore, the transmission server 3 allocates the third frequency block th to the first terminal 1 so that the first frequency block 11 can be bundled with the first frequency block 11 so that the first terminal 1 and the transmission server 3 can be used. Can improve the communication speed.

In this case, the first terminal 1 includes a first frequency block 11 and a third frequency block th to be used together to communicate with the transmission server 3. Corresponding to th) may have the same or more maximum communication speed. For example, the communication speed between the first terminal 1 and the transmission server 3 is 150 Mbps using the first frequency block 11, and the first terminal 1 is transmitted with the first terminal 1 using the third frequency block th. When the server 3 communicates, when the communication speed is 50 Mbps, the first terminal 1 may have a maximum communication speed of 150 Mbps or more, and the first frequency block 11 and the third frequency block th are used together. If the first terminal 1 can communicate with the transmission server 3 at a communication speed of about 150Mbps, and thus occurs due to duplication (interference) between the second frequency block 21 and the first frequency block 11 Reduced communication speed can be suppressed.

Here, the transmission server 3 is a frequency block (the first frequency block 11, the second frequency block 21, the third frequency block) to each of the first terminal 1 and the second terminal 2 at the base station and the relay station. and at least one of th) and communicating with the first terminal 1 and the second terminal 2 through the frequency block.

The transmission server 3 is a contiguous frequency block th1 in the frequency band including the first frequency block 11 and a non-contiguous in the frequency band including the first frequency block 11. ) At least one of another band frequency block th3 included in one or more frequency bands not including the frequency block th2 and the first frequency block 11 may be designated as the third frequency block th.

For example, referring to FIGS. 2 and 3, the first frequency block 11 may be a frequency block having a width of 930 MHz to 950 MHz in a 900 MHz frequency band. In this case, the continuous frequency block th1 may be a frequency block having a width of 950 MHz to 970 MHz in the 900 MHz frequency band, and the non-continuous frequency block th2 may be a frequency block having a width of 980 MHz to 990 MHz. The other band frequency block th3 is a frequency block having a width of 1850 MHz to 1860 MHz in the 1800 MHz frequency band, a frequency block having a width of 2110 MHz to 2120 MHz in the 2100 MHz frequency band, and a frequency block having a width of 2620 MHz to 2640 MHz in the 2600 MHz frequency band. It may be at least one of.

As described above, the third frequency block th is one (one of consecutive frequency blocks th1, non-contiguous frequency blocks th2, or a plurality of different band frequency blocks th3) or a plurality of first terminals (th). 1) uses a bundle of one or a plurality of third frequency blocks th and the first frequency block 11 to communicate with the transmission server 3 through an improved communication speed.

In this way, when the transmission server 3 cannot utilize the frequency block (continuous frequency block th1) adjacent to the first frequency block 11 (the operator having the transmission server 3 is the first frequency block 11). In the case of not having a frequency block adjacent to the frequency block 11 in the frequency band including the), the frequency block th2 that is not continuous in the frequency band including the first frequency block 11 By designating th), there is an advantage that the first frequency block 11 can be allocated to the first terminal 1 so as to be bundled with the first frequency block 11.

In addition, when the transmission server 3 cannot utilize the continuous frequency block th1 and the non-contiguous frequency block th2 in the frequency band including the first frequency block 11 (having the transmission server 3) If the operator does not have a frequency block that can be utilized in the frequency band including the first frequency block 11), by designating at least one of the other band frequency block (th3) as a third frequency block (th), Advantageously, the first frequency block 11 can be allocated to the first terminal 1 so as to be bundled with the first frequency block 11.

In addition, as described above, a plurality of frequency blocks are designated as a third frequency block th in a continuous frequency block th1, a non-contiguous frequency block th2, and a plurality of different band frequency blocks th3, and thus, the first frequency block th. By assigning to the first terminal 1 so that the bundle can be used with the (11), the first terminal 1 further interferes with the second terminal 2 using the second frequency block 21 to decrease the communication speed. The advantage is that it can be effectively improved.

FIG. 4 is a schematic diagram illustrating a first terminal communicating with a transmission server using a third frequency block when the communication speed of the first terminal is less than a preset reference speed in FIG. 1.

1, 2 and 4, when the communication speed between the first terminal 1 and the transmission server 3 is less than the preset reference speed, the first terminal 1 selects the first frequency block 11. Alternatively, the second frequency block 21 (in FIG. 4, for convenience, the first terminal 1 replaces the first frequency block 11 and uses the third frequency block th to communicate with the transmission server 3. Although not shown, it is possible to communicate with the transmission server 3 through the second frequency block 21 in place of the first frequency block 11) or the transmission using the third frequency block th. Can communicate with the server.

In detail, when the first terminal 1 has a low communication speed for various reasons (at least a part of the first frequency block 11 and the second frequency block 21 overlap each other and interference occurs), When the first terminal 1 bundles the first frequency block 11 and the third frequency block th allocated from the transmission server 3, the power consumption of the battery or the like is increased and the cost is high. May occur. Therefore, the transmission server 3 allows the first terminal 1 to substitute and use the second frequency block 21 or the third frequency block th by substituting the first frequency block 11 for the operator. It is possible to cope with a decrease in communication speed between the first terminal 1 and the transmission server 3 without incurring a large cost.

In addition, the communication speed of the first terminal 1 using the third frequency block th instead of the first frequency block 11 may be the first frequency block 11 (or the second frequency block 21). When compared with the communication speed at the time, the third frequency block th can be replaced again so that the first frequency block 11 (or the second frequency block 21) can be used to communicate with the transmission server 3. That is, the transmission server 3 allocates not only the first frequency block 11 but also the third frequency block th (or the second frequency block 21) to the first terminal 1, and the first terminal 1. (1) may select and use a frequency block having a high communication speed among the first frequency block 11 and the third frequency block th (or the second frequency block 21).

That is, less than the predetermined reference speed means the speed between the first terminal 1 and the transmission server 3 through the frequency block is replaced by the frequency block being used for the driver.

5 is a view for explaining a protective film of the transmission server housing.

Referring to FIG. 5, in the housing, a metal material or the like may be used to provide an appropriate level of rigidity. Since the housing is always exposed to the external environment due to its characteristics, breakage, warpage, corrosion, etc. may occur due to impacts, scratches, invasion, and the like. As described above, the transmission server 3 is connected to a terminal (first terminal 1, etc.). It needs to be properly protected as it includes precision electronic communication equipment for allocating frequency blocks, allocating other frequency blocks by using or replacing frequency blocks, and the like.

Therefore, the present invention introduced a protective film provided on the outer surface of the housing as a protective means for the housing of the transmission server (3). Specifically, referring to FIG. 5, the present invention provides a porous layer G1 provided on the outer surface of the housing at predetermined intervals, a heating layer G2 and a porous layer G1 provided on the porous layer G1, and heat generation. The protective film G may further include a protective layer G3 including the layer G2 and covering the outer surface of the housing.

Specifically, the porous layer (G1) is configured to add a buffer to the protective film (G), compared to 100 parts by weight of expanded polystyrene, 5 parts by weight of antimony trioxide (Sb2O3), 7 parts by weight of melamine polyphosphate and expanded graphite 10 It includes parts by weight.

For each composition, expanded polystyrene (Expanded Polystyrene) has a disadvantage in that it is vulnerable to flame retardancy, but was used because of the excellent thermal insulation performance and low manufacturing cost. Each composition of the porous layer (G1) is determined based on 100 parts by weight of the foamed styrene.

In addition, antimony trioxide (Sb 2 O 3) is a metal oxide obtained from the earpiece, and has been used for the advantage of having excellent flame retardancy compared to other flame retardants. Such antimony trioxide is preferably included 5 parts by weight, based on 100 parts by weight of expanded styrene, when used in excess of the radical compounds generated during combustion may be harmful to the human body, and because of the relatively expensive economical Degrades.

Melamine polyphosphate (Melamine Polyphosphate) is a kind of polyphosphorylated water, which is added to form a glass coating to block oxygen access. As a result of the repeated experiments, the optimum amount of glass for forming the proper thickness is 7 parts by weight based on 100 parts by weight of expanded styrene.

And expanded graphite (Expanded Graphite) is added as a graphite compound that adds a flame retardant function by generating a carbide during combustion, the preferred amount is 10 parts by weight, the repeated experiments as a result of the weight ratio of the melamine polyphosphate of 0.7: It was concluded that when used as 1, the flame retardant effect was maximally expressed, and it was desirable to include 10 parts by weight.

The porous layer G1 is prepared through a predetermined curing operation after dispersing the above components using water as a solvent. Herein, matters concerning the curing of the porous layer G1 are outside the scope of the present invention and shall be based on the publicly known techniques and common knowledge of those skilled in the art.

Next, the heating layer (G2) is provided on the porous layer (G1), self-heating by receiving sunlight can be achieved by the fusion and kneading between the porous layer (G1) and the protective layer (G3) itself. Since the kneading time is longer than 24 hours at room temperature, it is configured to provide a temperature condition of about 40 ~ 60 ℃ to shorten the kneading time within 30 minutes. The heat generating layer G2 includes 5 parts by weight of manganese dioxide and 3 parts by weight of silica gel, relative to 100 parts by weight of tetrachlorogold (III) acid.

For each composition, tetrachlorogold (III) acid (HAuCl4) is a pale yellow crystal obtained by dissolving gold in aqua regia or by dissolving gold (III) chloride in hydrochloric acid. It is preferable that a particle diameter of 15-30 nm is used. The following composition which comprises the heat generating layer (G2) is determined based on 100 weight part of tetrachloro gold (III) acids.

Manganese dioxide (MnO2) is a compound in which manganese and an oxide combine, and is added to facilitate the dispersion of the heating layer (G2) and to optimize the utilization range of the solar wavelength, and transition of four cycles such as titanium, chromium, nickel, and copper. The radiation rate and the energy efficiency in the far-infrared region of the metal are good. Such manganese dioxide is prepared by sintering at about 1000 ° C. in the presence of oxygen, and the smaller the particle size is, the more the induction heating effect is increased, so that an average particle diameter of 10 to 100 nm is preferably used. It is preferable that it is 5 weight part shown.

In addition, silica gel was added to maintain the exothermic effect of the exothermic layer (G2) and shorten the exothermic saturation time. As a result of repeated experiments, it was confirmed that the exothermic efficiency was shown when 3 parts by weight were included.

The exothermic layer (G2) was heated for 10 minutes at an aqueous tetrachlorogold (III) acid solution at about 100 ° C., and then added with a small amount of citric acid to form an aqueous solution, followed by mixing and dispersing manganese dioxide and silica gel in the blending ratio. Then, it is manufactured through a predetermined drying process. Here, specific details of the drying process is to follow the common knowledge of the known techniques and those skilled in the art.

Next, the protective layer G3 is a basic structure of the protective film G and covers and protects the whole protective part including the above-mentioned porous layer G1 and the heat generating layer G2. The protective layer (G3) is 10 parts by weight of pozzolane, 3 parts by weight of surfactant, bentonite, relative to 100 parts by weight of silica bonding water containing 5% by weight of tetraethoxysilane, 5% by weight of methyltriethoxysilane and the balance of water. 1 part by weight, hydroxyethyl acrylate 40 parts by weight and ethylenediaminetetraacetate 3 parts by weight.

For each component, silica-bonded water is added for the geopolymer reaction of pozzolanic, preferably containing a large amount of silica (SiO). Such silica-bonded water includes 5% by weight of tetraethoxysilane (TEOS), 5% by weight of methyltriethoxysilane (MTES) and the balance of water relative to the total weight of the bond water. Forming a network structure, methyltriethoxysilane increases the flexibility of the network. If the tetraethoxysilane is added below the composition ratio, the hardness of the protective layer (G3) decreases, and when it is added above the composition ratio, the silica precursor content is high, which may cause cracks during drying. In addition, when the methyl triethoxysilane is used below the composition ratio, the flexibility is lowered, and when used in excess of the composition ratio, the hardness of the protective layer (G3) is lowered. The following composition which comprises protective layer G3 is based on 100 weight part of silica bonding water.

And pozzolanic is a main binder of the geopolymer reaction, and any of natural pozzolanic such as volcanic ash, fine slag powder, fly ash, silica fume and the like may be selected. It is preferable that 10 parts by weight of pozzolanic is used, and the composition ratio may be exceeded on the premise that it is not excessive. However, when the pozzolane is less than the composition ratio, it is difficult to develop strength.

And a surfactant is added to improve workability, and bentonite is added as a viscoelastic modifier to prevent falling off to perform the function of thixotropic agent. Such surfactants and bentonite are sufficient to add a commercially available product in the above composition ratio with reference to known techniques and common sense. When the composition ratio is out of the ratio, the flowability may be excessive or less than the reference value.

Hydroxyethylacrylate (Hydroxyethylacrylate) is added as an adhesion promoter, in particular, it has been employed because of the advantage of excellent sclerosis. As a result of repeated experiments, the preferred amount of use is 40 parts by weight, and when used below the composition ratio, the adhesion promoting effect is insignificant, and when used in excess of the composition ratio, the volatilization becomes high and the toxicity becomes strong.

And ethylene diamine tetraacetate (Ehtylenediaminetetracetate) is added as an adsorbent enhancer, and enhances the adsorption power during the initial construction of the protective film (G) to improve the adhesion as a result. As a result of repeated experiments, it was confirmed that the amount of use expressing the optimum adsorption enhancing effect was 3 parts by weight.

The protective layer G3 is prepared by mixing and agitating the above components in a stirrer, followed by a predetermined drying and curing process.

In an embodiment of the construction of the protective film (G), the test block is provided with a porous layer (G1), a heating layer (G2) and a protective layer (G3) in order, and then left for 1 hour under an environment in which sunlight is irradiated. Through a kneading process and cured to form a protective film (G). The protective film G was subjected to a cross-cut test, a scratching test, a combustion test through flame spraying and an internal invasion test through water spraying, and the peel rate was less than 1%. It was less than 5%, no combustion of the porous layer G1 occurred, and no internal invasion was detected.

In addition, the above-described protective film configuration is provided in the antenna for transmitting and receiving communication signals between the terminal (at least one of the first terminal 1 and the second terminal 2) and the transmission server 3, by the protective film configuration provided in the housing The effect to be expressed may be equally expressed to the antenna.

The present invention described with reference to the accompanying drawings may be variously modified and changed by those skilled in the art, and such variations and modifications should be construed as being included in the scope of the present invention.

Terminal 1: 1
1st frequency block: 11
Terminal 2: 2
2nd frequency block: 21
Transport server: 3
Third frequency block: th
Serial frequency block: th1
Non-contiguous frequency block: th2
Other band frequency block: th3

Claims (4)

In the building broadband wireless technology and system,
A first terminal for communicating using the first frequency block;
A second terminal for communicating using the second frequency block; And
When communicating with the first and second terminals and interference occurs because at least a part of frequencies in the first frequency block overlap with at least some of the frequencies in the second frequency block, the first frequency block can be bundled with the first frequency block. A transmission server for allocating at least one third frequency block to the first terminal so as to be allocated;
Including,
The transmission server includes a housing,
The housing includes a protective layer including a porous layer provided on the outer surface at predetermined intervals, a heating layer provided on the porous layer, and a protective layer covering the entire outer surface including the porous layer and the heating layer.
The porous layer includes 5 parts by weight of antimony trioxide (Sb 2 O 3), 7 parts by weight of melamine polyphosphate and 10 parts by weight of expanded graphite, based on 100 parts by weight of expanded polystyrene.
The heating layer includes 5 parts by weight of manganese dioxide and 3 parts by weight of silica gel, relative to 100 parts by weight of tetrachlorogold (III) acid,
The protective layer is 10 parts by weight of pozzolane, 3 parts by weight of surfactant, 1 part by weight of bentonite, relative to 100 parts by weight of silica bonding water containing 5% by weight of tetraethoxysilane, 5% by weight of methyltriethoxysilane and the balance of water. And 40 parts by weight of hydroxyethyl acrylate and 3 parts by weight of ethylenediaminetetraacetate.
The method according to claim 1,
The transmission server may include: a contiguous frequency block in a frequency band including the first frequency block, a non-contiguous frequency block and the first frequency in a frequency band including the first frequency block. A frequency band aggregation system for a building, characterized in that at least one of the other frequency bands included in one or more frequency bands that do not include a block is designated as a third frequency block.
The method according to claim 1,
The first terminal, when the communication speed between the first terminal and the transmission server is less than a predetermined reference rate, the transmission server using the second frequency block or the third frequency block to replace the first frequency block An integrated frequency band wide frequency wireless communication system of a building, characterized in that for communicating with. delete

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