JP2012120039A - Wireless communication system and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the throughput without increase in total communication time which is caused by increase of time slots.SOLUTION: Each communication source wireless communication device 2 notifies a coordinator 3 of wireless communication information designating at least a communication destination wireless communication device 2. The coordinator 3 discriminates two or more wireless communications among which no communication interference is generated in a network 10 mutually from wireless communications performed between the communication source and the communication destination wireless communication devices 2 based on each piece of wireless communication information notified from each wireless communication device 2, and allocates the time slots so that the discriminated two or more wireless communications are overlapped with each other on a temporal axis.

Description

  The present invention relates to a wireless communication system and method for performing ad-hoc time-division wireless communication in a network, as represented by WPAN (Wireless Personal Area Network) and the like, and particularly suitable for improving throughput. And a method.

  In recent years, research on practical application of WPAN has progressed. The WPAN is a wireless network that covers a short distance of 10 to 20 m, and is assumed to be used for ad hoc wireless communication between electronic devices such as a PC (personal computer) (for example, , See Patent Document 1).

  In such an ad hoc wireless communication system such as WPAN, it is important to first reduce the first path loss in order to realize a throughput of Gbps level in particular. In the 60 GHz band, a path loss of 2 m is supposed to lead to attenuation of about 74 dB. This means that when a signal transmission of 10 dBm is attempted, a path loss of 3 m occurs.

  In the 60 GHz band ad hoc wireless communication system, another major problem is the existence of a communication barrier. When a person or a stationary object is present in a linear distance (LOS Line of Sight) connecting a transmitter and a receiver in wireless communication, the radio wave in the 60 GHz band may not be able to pass due to an obstacle. If the LOS path is blocked by a metal object such as a PC display, a path loss of about 40 dBm or more is expected to occur.

  Although the recent beam forming technology has made it possible to increase the gain of the antenna, it has not been able to solve the problem of such signal attenuation. There has also been proposed a phase shifter that artificially creates a continuous change of a signal wave using the interference of two waves whose phases are changed from each other, but when this is operated in the 60 GHz band, a loss of 4 dB is proposed. It will also produce. After all, using such a phase shifter is nothing but consuming gain.

  Also, beamforming techniques can cause problems with other neighboring wireless communication devices. Depending on the type of antenna, the wireless communication device may require a step to identify the direction of the wireless communication device with which it is communicating, and the presence of that step may cause a loss of the entire communication time. As a result, the throughput is also reduced. In particular, as the number of other neighboring devices increases, the loss of the total communication time becomes larger.

  Incidentally, a relay type ad hoc wireless communication system 7 as shown in FIG. 5, for example, has been proposed in order to prevent a decrease in throughput due to an obstacle present in the LOS path. This relay type communication method is useful in that it can be a cheap and simple system and can cover a wide range of communication. In this ad hoc wireless communication system 7, a plurality of wireless communication devices 71 that perform ad hoc wireless communication in a time division within a network 70, and a coordinator 72 that assigns and controls ad hoc wireless communication performed in the network to a time division time slot. And.

  For example, when performing wireless communication from the communication source wireless communication device 71a to the communication destination wireless communication device 71c, the wireless communication system 7 is used when there is an obstacle in the LOS path or when the communication source wireless communication is performed. When the distance between the device 71a and the wireless communication device 71c as the communication destination is long, wireless communication is performed by a relay method by relaying the wireless communication device 71b in the middle. That is, data is transmitted from the wireless communication device 71a to the wireless communication device 71c that is the communication destination via the wireless communication device 71b. As a result, data can be transmitted while avoiding obstacles, or data can be transmitted to a communication destination that is far from the communication source.

  By the way, such ad-hoc wireless communication by the relay method is adopted in, for example, IEEE 802.16j, third generation (3G) portable terminals, and the like. However, the ad hoc wireless communication based on such a relay system is not directly applied to WPAN wireless communication using millimeter waves. The reason is that WPAN adopts a so-called half-duplex communication method, and cannot transmit or receive data from both sides at the same time, and can only transmit from one direction at a time interval. This is because.

Therefore, in WPAN, for example, when data is transmitted from the wireless communication device 71a to the wireless communication device 71c that is the communication destination via the wireless communication device 71b, the wireless communication device is used in the first time slot as shown in FIG. Communication of communication path d _ab from 71a to wireless communication device 71b is assigned. Then, in the next second time slot, communication on the communication path d _bc from the wireless communication device 71b to the wireless communication device 71c is assigned. As a result, when transmitting data having the same data size, this relay method requires twice the communication time as compared to the case where data is directly transmitted from the wireless communication device 71a to the wireless communication device 71c. As a result, the throughput per unit time is also halved.

FIG. 7 also shows that data is transmitted directly from the wireless communication device 71a to the wireless communication device 71c and data is transmitted from the other wireless communication devices 71d and 71e to the wireless communication device 71f at substantially the same time. An example is shown. In such a case, in a WPAN that performs wireless communication in a time-sharing manner, for example, as shown in FIG. 8 (a), communication in the communication path d _ac from the wireless communication device 71a to the wireless communication device 71c is performed in the first time slot. allocation, a communication of the communication path d _df from the wireless communication device 71d to the wireless communication device 71f in the second time slot, further communication path d _ef from the wireless communication device 71e to the wireless communication device 71f in the third time slot Communication will be assigned.

However, when the conventional relay method is applied to this WPAN, for example, as shown in FIG. 7, when data is transmitted from the wireless communication device 71a to the communication destination wireless communication device 71c via the wireless communication device 71b. As shown in FIG. 8 (b), it is necessary to assign the communication of the communication path d _ab to the first time slot, and further provide the fourth time slot to assign the communication of the communication path _dbc . As a result, when this relay system is used, the communication time becomes longer by the increment t ′ of the fourth time slot than the total communication time T when the relay system is not used. This also causes a decrease in throughput.

JP 2005-323375 A

  Therefore, the present invention has been devised in view of the above-described problems, and the object of the present invention is wireless communication that performs ad hoc time-division wireless communication in a network as represented by WPAN and the like. An object of the present invention is to provide a radio communication system and method capable of improving throughput without increasing the total communication time due to an increase in time slots.

  In order to solve the above-described problem, a wireless communication system according to the present invention performs time-sharing between a plurality of wireless communication devices that perform ad-hoc wireless communication in a network in a time division manner and ad hoc wireless communication that is performed in the network. In a wireless communication system having a coordinator that is assigned and controlled to a time slot, each wireless communication device that is a communication source notifies the coordinator of wireless communication information that specifies at least a wireless communication device that is a communication destination, and the coordinator Of each wireless communication performed between a communication source and a communication destination wireless communication device based on respective wireless communication information notified from each wireless communication device, two or more wirelesss that do not cause communication interference in the network The communication is determined, and the two or more determined wireless communications are on the time axis. And allocating time slots to multiple.

  In order to solve the above-described problems, a wireless communication method according to the present invention performs time-sharing between a plurality of wireless communication devices that perform ad-hoc wireless communication in a network in a time division manner and ad hoc wireless communication that is performed in the network. In a wireless communication method using a wireless communication system having a coordinator that is assigned and controlled to a time slot, each wireless communication device of the communication source notifies the coordinator of wireless communication information that specifies at least the wireless communication device of the communication destination, and Based on the respective wireless communication information notified from each wireless communication device by the coordinator, communication interference does not occur in the network among the wireless communications performed between the communication source and the communication destination wireless communication devices. Detect 2 or more wireless communications, 2 or more Wherein the wireless communication is allocated time slots so as to overlap on the time axis.

  According to the wireless communication system to which the present invention is applied, the wireless communication information specifying at least the wireless communication device of the communication destination is notified to the coordinator by each wireless communication device of the communication source, and notified from each wireless communication device by the coordinator. Based on the respective wireless communication information, two or more wireless communications that do not cause communication interference in the network among the wireless communications performed between the communication source and the communication destination wireless communication devices are determined and determined 2 Time slots are allocated so that the above wireless communication overlaps on the time axis.

  As a result, the present invention can perform communication without increasing the total communication time due to an increase in time slots, especially when performing ad hoc time-division wireless communication in a network, as represented by WPAN and the like. It becomes. As a result, it is possible to improve the throughput even when the number of wireless communication devices existing in the network increases, and in particular, it is possible to realize a throughput of Gbps level in an ad hoc wireless communication system such as WPAN. It becomes.

It is a block diagram of the radio | wireless communications system to which this invention is applied. It is a figure for demonstrating the structure of the data frame transmitted in the radio | wireless communications system to which this invention is applied. It is a flowchart of the radio | wireless communication method to which this invention is applied. It is a figure which shows the example of the time slot allocated in the radio | wireless communications system to which this invention is applied. It is a figure which shows a relay type ad hoc radio | wireless communications system. It is a figure which shows the example of the time slot allocated in the conventional ad hoc radio | wireless communications system. It is another figure which shows a relay type ad hoc radio | wireless communications system. It is another figure which shows the example of the time slot allocated in the conventional ad hoc radio | wireless communications system.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a configuration example of a wireless communication system 1 to which the present invention is applied. The wireless communication system 1 includes a plurality of wireless communication devices 2 and a coordinator 3 that controls the entire network 10. The wireless communication system 1 is based on standards such as IEEE802.15.3c and IEEE802.11ad, for example, and is based on communication standards such as WPAN (Wireless Personal Area Network) and WLAN (Wireless Local Area Network). Perform wireless communication. The wireless communication system 1 is not limited to the star type as shown in FIG. 1, and any network 10 form such as a tree type or a mesh type may be applied.

  The wireless communication device 2 includes, for example, a personal computer (notebook PC), various portable information terminals such as a mobile phone and the like. The wireless communication device 2 performs ad hoc wireless communication in a time division manner within the network 10 based on at least a standard such as WPAN or WLAN. When the wireless communication device 2 performs wireless communication from the communication source wireless communication device 2 to the communication destination wireless communication device 2, there is an obstacle in the LOS path, or the communication source wireless communication device 2 When the distance between the wireless communication device 2 and the communication destination wireless communication device 2 is long, the wireless communication is performed by the relay method by relaying another wireless communication device 2 on the way. In addition, the wireless communication device 2 can perform wireless communication with the coordinator 3 as necessary, and can also perform wireless communication with the wireless communication device 2 via the coordinator 3. Become.

  Similarly, the coordinator 3 may have the same configuration as the portable information terminal described above. The coordinator 3 plays a role as a central control unit. In other words, the coordinator 3 controls ad hoc wireless communication performed in the network 10 by assigning it to time-division time slots.

  The radio communication system 1 to which the present invention is applied uses a so-called superframe structure using a beacon 21 as shown in FIG. The superframe has a CAP (Contention Access Period) 22 and a CFP (Contention Free Period) 23 after the beacon 21. The time between the two beacons 21 is divided into a predetermined number of slots regardless of the period of the superframe. Incidentally, in this superframe structure, the number of slots constituting the CFP 23 is variable, and the number of slots constituting the CAP 22 is fixed. The CAP 22 is a period in which all the devices 2 can be accessed, and the CFP 23 is a period in which a specific wireless communication device 2 is exclusively accessible.

Next, the operation of the wireless communication system to which the present invention is applied will be described. FIG. 3 is a flowchart for realizing ad hoc wireless communication by a wireless communication system to which the present invention is applied. In the following description, as shown in FIG. 1, data is transmitted from the wireless communication device 2a to the wireless communication device 2c via the other wireless communication device 2b and wirelessly transmitted from the other wireless communication devices 2d and 2e, respectively. A case will be described as an example where data is transmitted to the communication device 2f almost simultaneously. That is, in this example, the communication path d _ab from the wireless communication device 2a to the wireless communication device 2b, the communication path d _bc from the wireless communication device 2b to the wireless communication device 2c, and the wireless communication device 2d to the wireless communication device communication path d _df of up to 2f, performed by time division four communication communication path d _ef from the wireless communication device 2e through to the wireless communication device 2f.

  First, in step S <b> 11, a communication start request is transmitted from the communication source wireless communication device 2 to the coordinator 3. Here, the communication source wireless communication device 2 is a device that attempts to transmit data to the communication destination wireless communication device 2, and in the above-described example, the wireless communication device 2a, the wireless communication devices 2d, and 2e are three. is there. A communication start request is transmitted from these wireless communication devices 2a, 2d, and 2e to the coordinator 3.

In step S12, the coordinator 3 receives the communication start request and sets an initial time slot for performing ad hoc communication in a time division manner. This initial time slot is set for each wireless communication device 2, and in particular, no adjustment is made between the wireless communication of each communication path (d _ab , d _bc , d _df , and d _ef ). That is, the coordinator 3 may simply set this initial time slot dedicated to each wireless communication device 2, and these may overlap in time.

  In step S13, the coordinator 3 notifies each wireless communication device 2 of the initial time slot set for each.

  Next, at the stage of proceeding to step S <b> 14, each wireless communication device 2 is in a state of receiving each initial time slot from the coordinator 3. In this state, each wireless communication device 2 transmits a radio wave to another unspecified wireless communication device 2 in the network 10 based on the notified initial time slot. That is, in this step S14, each wireless communication device 2 experimentally broadcasts radio waves along the originally set initial time slot.

  Next, the process proceeds to step S15, and the wireless communication device 2 creates wireless communication information. The wireless communication information is created mainly based on radio waves transmitted from another wireless communication device 2. That is, at the same time as broadcasting the radio wave from one wireless communication device 2 in step S14, the other radio communication device 2 broadcasts the radio wave in the same manner, so that one radio communication device 2 includes another radio communication device. Radio waves from 2 are sent. Each wireless communication device 2 receives the radio wave transmitted from the other wireless communication device 2 and includes it in the wireless communication information to be created. The communication source wireless communication device 2 designates the communication destination wireless communication device 2 in this wireless communication information. After completing the creation of the wireless communication information, the process proceeds to step S16.

  When the process proceeds to step S <b> 16, the wireless communication device 2 transmits the created wireless communication information to the coordinator 3.

In step S17, the coordinator 3 reads the wireless communication information received from each wireless communication device 2 and creates a time slot. First, the coordinator 3 can identify the communication destination wireless communication device 2 to which the communication source wireless communication device 2 intends to transmit data from the wireless communication information received from each wireless communication device 2. As a result, the coordinator 3 can identify that wireless communication is going to be performed in each communication path (d _ab , d _bc , d _df , and _{de ef} ).

Next, the coordinator 3 determines two or more wireless communications that do not cause communication interference in the network 10 among the wireless communications in the respective communication paths (d _ab , d _bc , d _df , and d _ef ). The determination as to whether or not the communication interference occurs may be performed by any method, for example, from the position information of each wireless communication device 2 included in the wireless communication information.

  In step S17, the coordinator 3 determines the radio wave intensity between the communication source and the communication destination wireless communication device 2 and the wireless communication device 2 other than the communication destination to the communication source wireless communication device 2 based on the wireless communication information. It is also possible to determine whether or not communication interference occurs by comparing the radio field intensity. For example, radio waves from the other wireless communication terminals 2c to 2f cause communication interference when performing communication between the communication source wireless communication device 2a and the communication destination wireless communication device 2b. For this reason, radio waves from other radio communication terminals 2c to 2f are compared with radio wave intensity between the radio communication device 2a as the communication source and the radio communication device 2b as the communication destination, and the ratio is equal to or higher than a preset threshold value. Alternatively, if it is less, it may be determined whether or not communication interference occurs.

As a result, for example, it is assumed that wireless communication on the communication path d _bc and wireless communication on the communication path d _df are determined to cause no communication interference even if they are performed simultaneously. In such a case, for example, as shown in FIG. 4, time slots are assigned so that wireless communication on the communication path _{dbc and} communication on the communication path _ddf that do not cause communication interference with each other overlap on the time axis. In other words, in the example of FIG. 4, the wireless communication of the communication path d _{bc and} the wireless communication of the communication path d _df do not cause communication interference even if they are performed simultaneously, but the wireless communication of the communication path d _ab and the communication path d The wireless communication of _ef is a point where communication interference with other wireless communication is determined. Therefore, the wireless communication of the communication path d _ab is assigned to the first time slot, the wireless communication of the communication path d _{bc and} the wireless communication of the communication path d _df are overlapped on the time axis to the second time slot, The wireless communication of the communication path _def is assigned to the third time slot.

  Next, the process proceeds to step S18, where the coordinator 3 notifies each wireless communication device 2 of the assigned time-division time slots, and controls these communications.

  Each of the communication source wireless communication devices 2a, 2d, 2b, and 2e transmits data to the communication destination wireless communication device 2 based on the notified time slot.

  As described above, according to the wireless communication system 1 to which the present invention is applied, the wireless communication information specifying at least the wireless communication device of the communication destination is notified to the coordinator 3 by each wireless communication device of the communication source, and the coordinator 3 Two or more of the wireless communication performed between the communication source and the communication destination wireless communication device 2 based on the wireless communication information notified from each wireless communication device 2 so that no communication interference occurs in the network 10. Are determined, and time slots are allocated so that two or more of the determined wireless communications overlap on the time axis.

  As a result, the present invention can perform communication without increasing the total communication time due to an increase in time slots when performing ad hoc time-division wireless communication in the network 10 as represented by WPAN and the like. It becomes possible. As a result, it is possible to improve the throughput even when the number of the wireless communication devices 2 existing in the network 10 increases. In particular, in the ad hoc wireless communication system such as WPAN, a throughput of Gbps level can be realized. Is possible.

  In the present invention, at least two or more wireless communications that do not cause communication interference in the network 10 may be determined, and the determination step of two or more wireless communications that cause communication interference may be omitted.

  In step S17 described above, the coordinator 3 compares the radio field intensity between the communication source and the communication destination wireless communication device 2 with the radio field intensity from the wireless communication device 2 other than the communication destination to the communication source wireless communication device. By doing so, it may be determined whether or not communication interference occurs. For example, in the case of the wireless communication device 2a that is the communication source, the radio wave intensity between the wireless communication device 2b that is the communication destination and the radio wave intensity between the wireless communication devices 2c to 2f other than the communication destination are compared. You may make it perform by. In such a case, for example, as shown in the following formula (1), the radio wave intensity between the communication source and the communication destination wireless communication device 2 is S, and the radio wave from the wireless communication device 2 other than the communication destination to the communication source wireless communication device If the intensity is I and the noise is N, the determination may be made based on whether S / (I + N) exceeds a preset threshold value.

  Hereinafter, embodiments of the wireless communication system 1 to which the present invention is applied will be described in detail.

Here, a data rate from the communication source wireless communication device 2s to the communication destination wireless communication device 2z is defined as R ^ti _{s, z} . The effective throughput R in each data stream is expressed as in equation (1).

R = R ^ti _{s, z} × t _i / T (1)

  This equation (1) corresponds to the example shown in FIG. Here, T is the length of the time frame. Further, t is the length of each time slot, and is represented by 1 ≦ i ≦ 3 in the case of 3 data streams. T is represented by the following formula (2).

^{_{T = Σ K i = 1 t}} i + T beacon + T cap ··········· (2)

Here, K is a number supported by CTA (Channel Time Allocation). In this example, K is 3. Here, since each data stream uses a divided CTA, it is assumed that there is no communication interference between channels that induces a decrease in throughput. Further, T _beacon is the time of the beacon 21 and T _cap is the time of the CAP 22.

In the example of FIG. 8B, the communication path d _bc is allocated in the newly allocated fourth time slot, but the throughput R ^E can be described by the following equation (3).

R ^E = R ^ti _{s, r} × t _i / (T + t _i ′) (3)

Here, the communication from the communication source wireless communication device 2s to the relay point wireless communication device 2r is referred to as a first hop, and the connection from the relay point wireless communication device 2r to the communication destination wireless communication device 2z is referred to as a second hop. R ^ti _{s, r} is the data rate in this first hop.

The data transmission period in the first hop is adjusted to be the same as the data transmission period in the second hop. t _i is the time slot time to which the first hop is assigned.

R ^ti _{s, r} × t _i = R ^{ti ′} _{r, z} × t _i ′ (4)

Here, R ^{ti ′} _{r, z} is the data rate of the second hop. t _i ′ is the time slot time to which the second hop is assigned.

On the other hand, the present invention is configured by time slot allocation as shown in FIG. Instead of assigning a new time slot in the second hop, wireless communication of communication paths that do not cause communication interference with each other is assigned redundantly in the same time slot. The throughput R ^{E of the} present invention can be expressed by the following equation (5).

R ^E = 1 / T · min [R ^ti _{s, r} · t _i · K _ti , R ^{ti ′} _{r, z} · t _i '· K _ti '} (5)

Here, K _ti and K _ti ′ are throughput loss factors. This includes a case where data is transmitted to another wireless communication device 2 that is not intended for transmission in the first hop.

1 wireless communication system 2 wireless communication device 10 network 3 coordinator 21 beacon 22 CAP
23 CFP

Claims (8)

In a wireless communication system having a plurality of wireless communication devices that perform ad hoc wireless communication in a time division within a network, and a coordinator that assigns and controls ad hoc wireless communication performed in the network to a time division time slot.
Each wireless communication device of the communication source notifies the coordinator of wireless communication information specifying at least the wireless communication device of the communication destination,
The coordinator causes communication interference with each other in the network among the wireless communications performed between the communication source and the communication destination wireless communication devices based on the wireless communication information notified from the wireless communication devices. A wireless communication system, wherein two or more wireless communications are determined and time slots are allocated so that the determined two or more wireless communications overlap on the time axis. The coordinator further discriminates two or more radio communications in which communication interference occurs in the network, and assigns each of the discriminated two or more radio communications to different time slots on a time axis. The wireless communication system according to 1. The coordinator receives a communication start request from each wireless communication device of the communication source, sets an initial time slot for each wireless communication device of the communication source, notifies each wireless communication device of the set initial time slot,
Each of the wireless communication devices transmits a radio wave to an unspecified wireless communication device in the network based on the notified initial time slot, and receives a radio wave transmitted from another wireless communication device, The wireless communication system according to claim 1 or 2, wherein the wireless communication information is created based on a received radio wave. Based on the wireless communication information, the coordinator compares the radio field intensity between the communication source and the communication destination wireless communication device and the radio field intensity from the wireless communication device other than the communication destination to the communication source wireless communication device. The wireless communication system according to claim 3, wherein a determination is made as to whether or not communication interference occurs. A wireless communication method using a wireless communication system, comprising: a plurality of wireless communication devices that perform ad hoc wireless communication in a time division manner in a network; and a coordinator that controls ad hoc wireless communication performed in the network by assigning the time division time slots In
Each of the communication source wireless communication devices notifies the coordinator of wireless communication information specifying at least the communication destination wireless communication device,
Based on the respective wireless communication information notified from each wireless communication device by the coordinator, communication interference occurs in the network among the wireless communication performed between the communication source and the communication destination wireless communication devices. A wireless communication method characterized by discriminating two or more wireless communications that do not exist and assigning time slots so that the two or more wireless communications thus determined overlap on the time axis. The coordinator further discriminates two or more radio communications that cause communication interference with each other in the network, and assigns each of the discriminated two or more radio communications to different time slots on a time axis. 5. The wireless communication method according to 5. The coordinator receives a communication start request from each wireless communication device of the communication source, sets an initial time slot for each wireless communication device of the communication source, notifies each wireless communication device of the set initial time slot,
Each radio communication device transmits radio waves to unspecified radio communication devices in the network based on the notified initial time slot, and receives radio waves transmitted from other radio communication devices, The wireless communication method according to claim 5 or 6, wherein the wireless communication information is created based on a received radio wave. Based on the wireless communication information, the coordinator compares the radio field intensity between the communication source and the communication destination wireless communication device and the radio field intensity from the wireless communication device other than the communication destination to the communication source wireless communication device. The wireless communication method according to claim 7, further comprising: determining whether communication interference occurs.

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