JP3107554B2 - Wireless communication system, wireless communication method, and exchange - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Purpose of the Invention] (Industrial application field) The present invention relates to an exchange used for a packet radio network that handles voice and data in an integrated manner.

(Prior Art) In recent years, a private wireless network and a small-zone wireless network that can cope with the movement of a terminal on a premises have been studied.

In these networks, the effective use of frequency networks and the flexibility with which signals can be transmitted (multimedia support) High reliability The size of the service area and the flexibility for its fluctuations are essential items.

By the way, conventionally, wireless services in the premises have been performed slightly. For example, a low-speed data transmission of about 4.8 Kbps performed between points called a wireless modem, a cordless phone that transmits analog voice by FM, and a message pager that transmits a message in one direction at an ultra-low speed.

However, for low-speed data transmission using a wireless modem, it can only be used point-to-point.

When used for communication between computer terminals and the like, the line remains connected regardless of the presence or absence of communication, so that the line use efficiency and frequency use efficiency are poor.

Since only low-speed data is used, it cannot be applied to workstations and engineering workstations that use a lot of image information and graphic information.

Even if an attempt is made to increase the speed, the effect of fading and shadowing is large and it is impossible to obtain high reliability as it is conventionally.

Cannot handle voice, images, data, etc. in a unified manner.

There are problems such as.

Also, cordless phones, including those for business use, cannot be applied to data transmission as they are because they are analog transmission and line-controlled.

Since radio waves are used, frequency-directed utilization technology is the most important, and line switching using cordless phones is unsuitable.

Current cordless phones do not take any countermeasures against shadowing, so there are many blind spots such as shadows of on-premises fixtures.

There are problems such as.

Further, the message pager has many similar drawbacks, and cannot satisfy the essential items described first.

Considering the above points, a wireless network that satisfies at least the essential items described at least first is a two-way wireless packet network that can packetize any media and can handle it collectively and at high speed. Such a network does not exist. Further, the above-described conventional wireless service cannot satisfy not only the essential items described at the beginning but also the following items.

By the way, improvement of the reliability of the radio unit in a small zone radio network or the like (this is an essential item described first).
In addition, it is well known that macroscopic diversity is effective (BERNHARDT, RC: “Rf performance of M
acroscopic Diversity in Universal Portable Communi
cation: Signal Strength Consideration "IEEE, Proc.GCO
M '87 32-7, BERNHARDT, RC: “Rf performance of M
acroscopic Diversity in Universal Portable Communi
cation: Frequency Reuse Consideration "IEEE, Proc.GCO
M'87 48-1).

In addition, based on these documents and a paper by the present inventors (Sakakibara, Serizawa) (IEICE Technical Report RCS89-12 “Slotted Aloha Wireless Communication System with Multiple Base Stations”), macroscopic diversity and multiple base stations are discussed. It is stated that the conversion is very effective for the frequency utilization efficiency. In particular, the IEICE Technical Report RCS89-12 indicates that high throughput (high frequency use efficiency) can be obtained in wireless packet communication. However, the article does not describe at all how to select a desired one packet from a plurality of packets, and does not disclose anything.

On the other hand, as a packet selection method for macroscopic diversity, “A Radio Access Scheme”
For CSMA / CD LAN.Proc.ICC '89, 15,4 ", a method using bus contention is shown, but this method is originally intended for CSMA / CD LAN which is a small LAN,
It is not suitable for large-scale networks covering large areas.

As another conventional macroscopic diversity configuration method, for example, as shown in FIG. 8, a diversity selection circuit 3 is provided between a port 1 and an exchange 2 to switch between predetermined diversity branches 4 and 4.・ Some perform synthesis. However, such a macroscopic diversity configuration method does not provide flexibility in changing the size of a zone, adding wireless ports, and the like. In other words, in the system shown in FIG. 10, the correspondence between the zone configuration and the diversity selection branch is strictly determined. Therefore, when the zone is reduced, enlarged, or dispersed, the diversity selection circuit 3 is re-started from the fundamental point. You have to build it.

(Problems to be Solved by the Invention) With the conventional network configuration method as described above, it was not possible to construct a small-zone wireless system or a private wireless network that satisfies the conditions of the indispensable items 1 to described above. .

Therefore, an object of the present invention is to provide a radio communication system capable of constructing a network that satisfies the effective use of frequency networks and flexibility for transmittable signals (multimedia support), high reliability, and a wide service area and flexibility against fluctuations. A wireless communication method and an exchange are provided.

[Configuration of the Invention] (Means for Solving the Problems) A wireless communication system of the present invention exchanges at least a packet-like signal in a predetermined wireless communication format with a wireless terminal existing in a wireless communication service area formed by each. A plurality of wireless communication ports, connected to the plurality of wireless communication ports, each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, the same by the detection, the same An exchange for selecting the best one from among a plurality of packet-like signals and transmitting the same to a corresponding destination, wherein the exchange comprises:
The response to the wireless terminal is performed through a communication path using at least a wireless communication port that has received the selected one packet-like signal.

(Operation) In the present invention, when a plurality of identical packets are transmitted to the exchange, only one packet is transmitted to the exchange corresponding to the destination, so that a plurality of wireless ports exist in the same service area. be able to. Therefore, effective use of frequency and improvement in reliability can be achieved by the macroscopic effect.

In addition, since a plurality of wireless ports can exist in the same service area, even if the wireless zone arrangement is changed or a macroscopic diversity branch is added,
Macroscopic diversity can be realized without changing the exchange and its peripheral circuits. That is,
Extremely flexible for changing wireless zones, expanding or reducing service areas, etc.

Further, by performing aggressive macroscopic diversity using such an exchange, even when a diversity having four or more branches having an extremely large number of branches is used for use under extremely poor conditions or high traffic conditions, there is no problem. Can be used without change.

Therefore, it is possible to construct a network that satisfies the effective use of frequency networks and the flexibility of signals that can be transmitted (for multimedia).

(Example) Hereinafter, details of an example of the present invention will be described based on the drawings.

FIG. 1 is a diagram showing an embodiment in which the exchange according to the present invention is applied to a wireless communication system.

In the figure, reference numeral 11 denotes an exchange according to the present invention. Each of the exchanges 11 is connected to each other, and each of the exchanges 11 is connected to a wireless port 12, and a packet-like signal (hereinafter, referred to as a packet-like signal).
Simply called a packet. ) Is exchanged. The wireless port 12 has a wireless communication function, and various wireless communication terminals 13
A wireless line is formed between the router and the router to exchange packets.
Specifically, between the wireless communication terminal 13 and the wireless port 12, all information such as voice, image and data is divided into packets of a standardized size,
Transmission and reception of packets are performed by the CSMA method or the like.

FIG. 2 is a diagram schematically showing the configuration of the above-mentioned exchange 11, which employs a common buffer system.

In FIG. 1, reference numeral 14 denotes a multiplexer for arranging packets transmitted from each wireless port 12 on one signal line. The packets arranged on this signal line are sequentially input to the buffer 15. Then, the packet output from the buffer 15 passes through the switch 17 and passes through the demultiplexer 18.
Sent to The demultiplexer 18 selects one output line from a plurality of output lines connected to another switch according to the destination of the packet, and sends out the packet to the output line. Here, the same packet detection device 16 that detects the same packet from the packets latched in the buffer 15 is connected to the buffer 15. Then, when detecting the same packet, the same packet detecting device 16 controls the switching of the switch 17 so that only one of the packets is sent to the demultiplexer 18.

Next, the operation of the communication system configured as described above will be described.

It is assumed that a plurality of wireless ports 12 exist in the same service area indicated by a broken line in FIG. Then, when a packet is transmitted from the wireless communication terminal 13 in this service area, all the wireless ports 12 existing in this service area receive the packet, and a plurality of identical packets are transmitted to the exchange 11. You.

In the switch 11, these packets are demultiplexed by the demultiplexer 18.
And is latched in the buffer 15. At this time, since the same packet exists in the packets latched in the buffer 15, this is detected by the same packet detecting device 16. Accordingly, only one packet of these identical packets output from the buffer 15 is sent to the demultiplexer 18 by switching of the switch 17. And
This packet is sent out by the demultiplexer 18 to the exchange corresponding to the destination of the packet.

As described above, in the present embodiment, when a plurality of identical packets are transmitted to the exchange, only one packet is transmitted to the exchange corresponding to the destination, and the remaining packets are discarded. Multiple wireless ports
12 can be present. Therefore, effective use of frequency and improvement in reliability can be achieved by the macroscopic effect.

Also, multiple wireless ports 12 within the same service area
It is possible to realize macroscopic diversity without changing the switch 11 or its peripheral circuits even if there is a change in the wireless zone arrangement or the addition of a macroscopic diversity branch, etc. it can. That is, it is extremely flexible with respect to wireless zones, changes, and expansion and contraction of service areas.

Further, by actively performing macroscopic diversity using such an exchange 11, even in the case of using a diversity having a very large number of branches of 4 or more for use under extremely poor conditions or high traffic conditions, Can be used without any changes.

Therefore, by using the exchange of the present embodiment, the effective use of the frequency, which is an essential item in the private wireless network and the small zone wireless network described in the conventional example, the flexibility for the network and the signals that can be transmitted (multimedia correspondence), high reliability The flexibility of the service area and its fluctuation can be satisfied.

Next, an embodiment in which the present invention is applied to an output buffer type exchange will be described.

FIG. 3 is a diagram schematically showing the configuration of this exchange.

In the exchange shown in the figure, the packets output from the switching element 22 are output to buffers 23 corresponding to the respective destinations. Each buffer 23 has the same packet detection device.
24 are connected. When the same packet detector 24 detects that the same packet exists in the buffer 23, the switch 25 provided on the output side of each buffer 23 detects the same packet as in the first embodiment. Selection and disposal are performed.

Next, an embodiment in which the present invention is applied to an exchange of a distributed buffer system will be described.

FIG. 4 is a diagram schematically showing the configuration of this exchange.

In the exchange shown in the figure, a packet output from each buffer 26 is input to a switching element 27. And
Each switching circuit provided in the switching element 27
The same packet detection / discard circuit 29 is connected to 28, and selects or discards a packet.

The present invention can be applied not only to the above-described switching system but also to various types of switching systems such as a banyan switch, an input buffer system, and a common buffer system. Further, it is also possible to introduce the present invention to a packet switch that performs processing in software. However, particularly in the case of the output buffer system shown in FIG. 2, the same packet is collected in the same buffer, so that the configuration is particularly easy. That is, since all the same packets input from different input terminals are collected in the same output buffer, it is not necessary to compare packets between different buffers.

 Next, another embodiment of the present invention will be described.

In this embodiment, first, the wireless port is configured as shown in FIG.

In the figure, reference numeral 30 denotes an antenna, and this antenna 30
The RF signal received from the local oscillator 31 and the multiplier 32
, Converted to a baseband signal, and demodulated
Entered in 33. The reliability data detection circuit 34 is connected to the demodulator 33. This reliability data detection circuit 34
Is a like-lihood function (like-lihood) obtained together with the reception power at the time of reception and the demodulation (decoding) of the received packet.
function) to detect the reliability data of the packet. Then, the obtained reliability data is added to the corresponding packet in the reliability data adding circuit 35,
It is sent to the exchange.

On the other hand, the exchange is configured as shown in FIG. That is, the buffer 36 includes a FIFO 36a and a delay unit 36b, and determines whether or not each packet in the delay unit 36a is the same by the same packet detection circuit 38 configured by a combination of the comparators 37. . Then, when the same packet is detected, the packet discard control circuit 39 compares the reliability data of these same packets, and sends the packet with the best reliability data to the demultiplexer side.
The switching of the switch 40 is controlled. Thereafter, the packet output from the switch 40 is sent to the demultiplexer through a reliability data removing circuit 41 for removing unnecessary reliability data.

As described above, in the present embodiment, when the same packet exists, the highly reliable packet is left and the unreliable packet is discarded, so that higher reliability can be obtained.

After the only packet with high reliability is sent to the other party, if the other party sends a response packet to the wireless communication terminal that sent this packet, the exchange will send The input line to which only the high packet was transmitted may be selected, and the responding packet may be returned. That is, the input line to which only the highly reliable packet is transmitted has high reliability even in the reverse route.

 Next, another embodiment of the present invention will be described.

First, when receiving a packet, each wireless port delays a highly reliable packet immediately after receiving it, and delays an unreliable packet according to its reliability by a time such that the larger the reliability, the smaller the reliability. Then, the packet is transmitted to the exchange.

In the exchange, as shown in FIG. 7, packets output from the wireless port via the buffer 42 are sequentially input to the delay unit 43, and each packet is compared with each other to determine whether or not each packet in the delay unit 43 is the same. It is determined by the unit 44. Then, the output of each comparator 44 is sent to the switching control side of the switch 46 via the OR circuit 45. Therefore, by switching the switch 46, the earliest packet from a plurality of identical packets is selected.

As described above, in the present embodiment, the probability that the most reliable packet among the plurality of identical packets arrives at the buffer 42 of the exchange first is the highest. However, this probability depends on the traffic.

Therefore, a highly reliable packet can be obtained by configuring the exchange to select the earliest packet from a plurality of identical packets and discard the second and subsequent packets as described above.

Further, since the exchange of the present embodiment does not use the delay device as shown in FIG. 6, the time required for the exchange can be shortened, and it is extremely advantageous for transmission of a signal such as voice that does not allow a large delay. It is.

Although each of the embodiments described above is based on the premise that the exchange according to the present invention is applied to a wireless communication system, the exchange according to the present invention can also be applied to a wired communication system.

For example, the exchange according to the present invention is used in a conventional public network. However, when the exchange in the above-described embodiment sends a plurality of identical packets from the terminal to another exchange, only one packet is sent to the other exchange. However, the exchange in this case is When sending a plurality of identical packets from another exchange to the terminal, only one packet is sent to the terminal.

Then, for example, when an urgent call is generated, the calling exchange receiving the call transmits the packet related to the call to a plurality of routes.

With the function according to the present invention, the destination exchange sends out only the packet related to the first call received to the destination terminal.

Therefore, in this case, it is possible to shorten the packet transmission time as much as possible.

That is, in the conventional public network, a route is selected by estimating a route having the shortest transmission time. For example, when a certain point in the route becomes congested or the like. However, the route was not always the shortest route.

Therefore, by transmitting a packet to a plurality of routes as described above, it is possible to always transmit a packet through the shortest route.

[Effects of the Invention] As described above, according to the wireless communication system, the wireless communication method, and the switch of the present invention, a frequency effective use network and flexibility for a transmittable signal (multimedia correspondence) high reliability A network can be constructed that satisfies the breadth and flexibility of its fluctuation.

[Brief description of the drawings]

FIG. 1 is a diagram showing an embodiment in which the exchange according to the present invention is applied to a radio communication system, FIG. 2 is a diagram schematically showing the configuration of the exchange shown in FIG. 1, FIG. Fig. 4, Fig. 6
FIGS. 7 and 8 show another example of the exchange of the present invention.
FIG. 8 is a diagram showing a configuration of a wireless port according to another embodiment of the present invention, and FIG. 8 is a diagram showing a configuration of a conventional wireless communication system. 11 ... exchanger, 12 ... wireless port, 13 ... wireless communication terminal, 14 ... multiplexer, 15 ... buffer, 16 ... identical packet detector, 17 ... switch, 18 ... demultiplexer.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification code FI H04Q 7/38

Claims (36)

(57) [Claims] 1. A plurality of wireless communication ports for exchanging at least a packet-like signal in a predetermined wireless communication format with a wireless terminal existing in a wireless communication service area formed by each of the plurality of wireless communication ports; Each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, and when a plurality of the same packet-like signals are detected by this detection, one of the best packet-like signals is selected. And a switch for sending the selected packet-like signal to a corresponding destination, wherein the switch responds to the wireless terminal through a communication path using at least a wireless communication port that has received the selected one packet-like signal. A wireless communication system, comprising: 2. A wireless terminal for transmitting and receiving a packet signal, a plurality of wireless communication ports for exchanging at least the packet signal in a predetermined wireless communication format with the wireless terminal, and a plurality of wireless communication means. Connected, each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, and when a plurality of the same packet-like signals are detected by this detection, And an exchange for selecting one of the packet-like signals and transmitting the selected packet-like signal to a corresponding destination. The exchange exchanges a response to the wireless terminal using at least a wireless communication port that has received the selected one packet-like signal. A wireless communication system, characterized in that the communication is performed by: 3. A plurality of wireless communication ports for exchanging at least a packet-like signal in a predetermined wireless communication format with a wireless terminal existing in a wireless communication service area formed by each of the plurality of wireless communication ports; Each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, and when a plurality of the same packet-like signals are detected by this detection, one of the best packet-like signals is selected. And a switch for selecting and transmitting the selected wireless communication port to a corresponding destination, wherein the plurality of wireless communication ports are arranged so as to at least overlap each other's wireless communication service area. 4. A wireless terminal for transmitting and receiving a packet signal, a plurality of wireless communication ports for exchanging at least the packet signal with the wireless terminal in a predetermined wireless communication format, and a plurality of wireless communication means. Connected, each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, and when a plurality of the same packet-like signals are detected by this detection, And an exchange for selecting one of the wireless communication ports and sending the selected wireless communication port to a corresponding destination, wherein the plurality of wireless communication ports are arranged so as to overlap at least the wireless communication service areas of each other. . 5. A plurality of wireless communication ports for exchanging at least a packet-like signal in a predetermined wireless communication format with a wireless terminal existing in a wireless communication service area formed by each of the plurality of wireless communication ports; Each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, and when a plurality of the same packet-like signals are detected by this detection, one of the best packet-like signals is selected. And a switch for transmitting the packet to a corresponding destination. Each of the wireless communication ports includes: a reliability detection unit that detects reliability data of a packet-like signal received from the wireless terminal; Means for sending both the reliability data detected by the means and the packet-like signal to the exchange, wherein the exchange comprises the same When a plurality of packet-like signals are detected, signal selection means for selecting the best one from a plurality of identical packet-like signals based on the reliability data sent together with each of the packet-like signals, Signal transmission means for transmitting one packet-like signal selected by the signal selection means to a corresponding destination. 6. A wireless terminal for transmitting and receiving a packet-like signal, a plurality of wireless communication ports for exchanging at least the packet-like signal with the wireless terminal in a predetermined wireless communication format, and a plurality of wireless communication means. Connected, each of the wireless communication ports detects the same packet-like signal received from the wireless terminal within a predetermined time, and when a plurality of the same packet-like signals are detected by this detection, An exchange for selecting one of the wireless communication terminals and sending the selected wireless communication port to a corresponding destination, wherein each of the wireless communication ports includes: a reliability detecting unit that detects reliability data of a packet-like signal received from the wireless terminal; Means for sending both the reliability data detected by the reliability detection means and the packet-like signal to the exchange, wherein the exchange comprises: Signal selecting means for selecting the best one from a plurality of identical packet-like signals based on the reliability data sent together with each of the packet-like signals when a plurality of such packet-like signals are detected, Signal transmission means for transmitting one packet signal selected by the signal selection means to a corresponding destination. 7. The wireless communication system according to claim 1, wherein, when a plurality of said identical packet-like signals are detected, one of said exchanges is predicted to have the least transmission error. A wireless communication system for selecting a packet signal. 8. The wireless communication system according to claim 1, wherein the switching unit arranges the packet-like signals input from the wireless communication ports in a line, and arranges the packet-like signals in a line. A wireless buffer in which each packet-like signal is sequentially stored, and a same signal detecting means for detecting the same packet-like signal from among the buffers stored in the buffer. Communications system. 9. The wireless communication system according to claim 1, wherein the switching unit switches each packet-like signal input from each of the wireless communication ports for each destination, and the switch unit. A plurality of buffers for respectively storing the packet-like signals distributed by the above, and the same signal detecting means connected to each of the buffers and detecting the same packet-like signal from the stored in each of the buffers. A wireless communication system in the form of an output buffer. 10. The wireless communication system according to claim 1, wherein the predetermined wireless communication format is a format in which information is divided into packets of a standardized size to obtain a packet-like signal. A wireless communication system, comprising: 11. The wireless communication system according to claim 10, wherein said information is voice, image, and data. 12. The wireless communication system according to claim 5, wherein the reliability detecting means of each of the wireless communication ports receives reception power when a packet-like signal is received from the wireless terminal, or receives the reception power. A wireless communication system, wherein reliability data of the packet-like signal is detected from a likelihood function obtained by demodulation of the packet-like signal. 13. The wireless communication system according to claim 5, wherein said plurality of wireless communication ports transmit said packet-like signal in accordance with a level of reliability data detected by said reliability detection means. A wireless communication system, wherein the wireless communication system is of an autonomous decentralized type in which transmission timing to the exchange is varied. 14. The wireless communication system according to claim 5, wherein said switch selects a best one packet-like signal from said selected packet-like signal when said best one packet-like signal is selected by said signal selecting means. A wireless communication system, further comprising reliability data removing means for removing reliability data and transferring the reliability data to the signal transmitting means. 15. A receiving step in which a plurality of wireless communication ports receive at least a packet-like signal in a predetermined wireless communication format from a wireless terminal present in a wireless communication service area formed by each of the plurality of wireless communication ports; The same signal detecting step of detecting the same packet-like signal among the packet-like signals received in the receiving step; and, when a plurality of the same packet-like signals are detected in the same signal detecting step, the best one is selected from them. A signal selecting step; and a signal transmitting step of transmitting the one packet-like signal selected in the signal selecting step to the corresponding wireless terminal of the destination, wherein the transmitting in the signal transmitting step includes the step of: 1
A wireless communication method, which is performed through a communication path using at least a wireless communication port that has received two packet-like signals. 16. A receiving step in which a plurality of wireless communication ports receive at least a packet-like signal in a predetermined wireless communication format from a wireless terminal existing in a wireless communication service area formed by each of the plurality of wireless communication ports; An identical signal detecting step for detecting the same packet-like signal received in the receiving step, and a signal for selecting the best one from the plurality of identical packet-like signals when the same packet-like signal is detected in the same signal detecting step A selecting step; and a signal transmitting step of transmitting one packet-like signal selected in the signal selecting step to the wireless terminal of a corresponding destination, wherein the packet-like signal in the receiving step or the signal transmitting step is Receiving or transmitting arranged so as to at least overlap each other's wireless communication service area Radio communication method characterized in that performed by the serial radio communication port. 17. A receiving step in which a plurality of wireless communication ports receive at least a packet-like signal in a predetermined wireless communication format from a wireless terminal existing in a wireless communication service area formed by each of the plurality of wireless communication ports; A reliability detecting step of detecting reliability data of the detected packet-like signal; a transmitting step of transmitting both the reliability data detected in the reliability detecting step and the packet-like signal to the exchange; within a predetermined time The same signal detection step of detecting the same packet-like signal among the packet-like signals received in the reception step; and, when a plurality of the same packet-like signals are detected in the same signal detection step, transmitting the same together with the respective packet-like signals. A signal that selects the best one from a plurality of identical packet-like signals based on the reliability data obtained A wireless communication method, comprising: a selecting step; and a signal transmitting step of transmitting one packet-like signal selected in the signal selecting step to the corresponding destination wireless terminal. 18. The wireless communication method according to claim 15, wherein the packet-like signal selected in the signal selecting step is:
A wireless communication method, wherein one of the plurality of identical packet-like signals detected in the same signal detection step is predicted to have the least transmission error. 19. The wireless communication method according to claim 15, wherein the same signal detecting step includes: arranging the packet-like signals input from the respective wireless communication ports in a line; A wireless communication method, comprising: sequentially accumulating each packet-like signal obtained in a buffer; and detecting the same packet-like signal from the accumulated in the buffer. 20. The wireless communication method according to claim 15, wherein the same signal detecting step includes: distributing each packet-like signal input from each of the wireless communication ports for each destination; Storing the respective packet-like signals distributed in the switching step in a plurality of buffers; and detecting the same packet-like signal from among the stored in the respective buffers. Wireless communication method. 21. The wireless communication method according to claim 15, wherein the predetermined wireless communication format is a format in which information is divided into packets of a standardized size to obtain a packet-like signal. A wireless communication method, comprising: 22. The wireless communication method according to claim 21, wherein said information is voice, image, and data. 23. The wireless communication method according to claim 17, wherein the detection of the reliability data in the reliability detection step includes: receiving power when each wireless communication port receives a packet signal from the wireless terminal; Alternatively, the wireless communication method is performed based on a likelihood function obtained with demodulation of a received packet-like signal. 24. The wireless communication method according to claim 17, wherein the sending of the packet-like signal to the exchange in the sending step is performed according to a level of reliability data detected in the reliability detecting step. A wireless communication method, wherein the timing is variable. 25. The wireless communication method according to claim 17, further comprising a reliability data removing step of removing reliability data from the packet-like signal selected in the signal selecting step, prior to the signal transmitting step. A wireless communication method comprising: 26. An identical signal detecting means for detecting the same packet-like signal of a predetermined wireless communication format received from a wireless terminal existing in a wireless communication service area within a predetermined time by a plurality of wireless communication ports. When a plurality of identical packet-like signals are detected by the same signal detecting means, a signal selecting means for selecting the best one from the plurality of packet-like signals, and the one packet-like signal selected by the signal selecting means, A signal transmitting means for transmitting to a corresponding destination via a communication path at least using a wireless communication port that has received the selected one packet-like signal. 27. A packet of a predetermined wireless communication format received from a wireless terminal existing in a wireless communication service area within a predetermined time by a plurality of wireless communication ports arranged so as to overlap at least wireless communication service areas of each other. Among the state signals, the same signal detecting means for detecting the same signal, and when a plurality of the same packet-like signals are detected by the same signal detecting means, a signal selecting means for selecting the best one from the same, A signal transmitting means for transmitting one packet-like signal selected by the signal selecting means to a corresponding destination. 28. An exchange for receiving said packet-like signal and said reliability data from a wireless communication port having reliability detection means for detecting reliability data of a received packet-like signal, said plurality of said wireless communication ports Among the packet-like signals of the predetermined wireless communication format received from the wireless terminal existing in the wireless communication service area within a predetermined time, the same signal detecting means for detecting the same signal, and the same signal detecting means When a plurality of packet-like signals are detected, signal selection means for selecting the best one from a plurality of identical packet-like signals based on the reliability data sent together with each of the packet-like signals, Signal transmitting means for transmitting one packet-like signal selected by the signal selecting means to a corresponding destination. Exchange. 29. The exchange according to claim 26, wherein said signal selecting means, when a plurality of said identical packet-like signals are detected, one of said ones which is predicted to have the least transmission error. An exchange for selecting a packet-like signal. 30. The exchange according to claim 26, wherein said identical signal detecting means comprises: means for arranging each packet-like signal input from each of said wireless communication ports in a line; A common buffer comprising: a buffer for sequentially accumulating each packet-like signal, and means for detecting the same packet-like signal from the accumulated in the buffer. 31. The exchange according to claim 26, wherein said identical signal detecting means comprises: switch means for distributing each packet-like signal input from each of said wireless communication ports for each destination; An output comprising: a plurality of buffers for respectively storing the packet-like signals distributed by the means, and means for detecting the same packet-like signal from among the buffers stored in the respective buffers connected to the respective buffers. An exchange in the form of a buffer. 32. The exchange according to claim 26, wherein the predetermined wireless communication format is a format in which information is divided into packets of a standardized size to obtain a packet-like signal. The exchange that features it. 33. The exchange according to claim 32, wherein said information is voice, image, and data. 34. An exchange according to claim 28, wherein said reliability detecting means of each of said wireless communication ports includes a receiving power when a packet-like signal is received from said wireless terminal or a demodulation of the received packet-like signal. An exchange for detecting reliability data of the packet-like signal from a likelihood function obtained by the switching. 35. An exchange according to claim 28, wherein said exchange changes the timing at which said packet-like signal is sent to said exchange in accordance with the level of reliability data detected by said reliability detection means. An exchange for receiving the packet-like signal and the reliability data from a plurality of wireless communication ports in the form of a mobile phone. 36. The exchange according to claim 28, wherein when the best one packet-like signal is selected by said signal selecting means, said signal transmitting means removes reliability data from said selected packet-like signal. An exchange characterized by further comprising a reliability data removing means for transferring the data to the exchange.