JP2014183592A - Device discovery method and apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a probability of mistakes about discovery of users.SOLUTION: The invention discloses a device discovery method and apparatus. The device discovery method uses a first mobile communication terminal in a mobile communication network. The device discovery method includes: obtaining a current actual geographic position; determining a first grid corresponding to the actual geographic position, on the basis of a first correspondence relation between a geographic position and a grid; determining a first transmission resource aggregation corresponding to the first grid on the basis of a second correspondence relation between the grid and a transmission resource aggregation; by transmitting a discovery signal by use of a resource block in the first transmission resource aggregation, a second mobile communication terminal, after receiving the discovery signal, discovering the first mobile communication terminal on the basis of terminal information recorded in the discovery signal, and determining the first grid where the first mobile communication terminal is situated on the basis of the transmission resource aggregation in which the resource block used for the discovery signal is situated and the second correspondence relation.

Description

  The present invention relates to the field of mobile communication technology, and more particularly to a device discovery method and apparatus.

  Mobile Internet applications are emerging rapidly and present new challenges to conventional mobile communication technologies, such as higher user rates and more flexible communication methods.

  In order to satisfy such a request, a new type of wireless technology such as D2D (Device to Device) communication technology or eLA (enhanced Local Access) technology has been proposed.

  Unlike the conventional method in which communication is performed only through the link between the user and the base station in the mobile communication network, in D2D communication, communication is attempted through a direct wireless link between the user and the user. In eLA, communication is performed using a radio link between a user and a local access node by installing a local access node with relatively low power. Generally speaking, because the transmission distance between users or local radio links is relatively short, the link quality is relatively high, and it is possible to provide a relatively high frequency multiplexing gain, the frequency of the macro cell (Macro Cell) Useful for mitigation from remote areas where there is not enough room for spectrum resources and the user rate is relatively low.

  To achieve communication between users or between a user and a local access node, at least one user or other local user must first be discovered in the local access node, and then the discovered user It becomes possible to establish a connection with and communicate. Unlike base stations in conventional mobile communications, users or local access nodes do not do synchronization and periodic transmission of reference signals to help users identify cell IDs. Therefore, it is necessary to design a strategy to realize mutual discovery between users or neighboring user discovery by a local access node.

  A conventional mobile communication terminal discovery method is realized by installing a specific physical layer channel. The specific physical layer channel occupies certain time frequency resources and is dedicated to the identification of neighboring mobile communication terminals. The physical layer channel may include a plurality of resources (such as time / frequency / code / space) used for transmission of discovery signals by the mobile communication terminal, but different mobile communication terminals may use one or more resources. Can be selected to transmit its own discovery signal, and other resources are monitored for discovery signals transmitted from other mobile communication terminals. For example, one mobile communication terminal uses the specific physical layer channel to broadcast a signal including its ID information, while other neighboring mobile communication terminals monitor the specific physical layer channel, When the discovery signal is received and the mobile communication terminal ID included therein is restored, the mobile communication terminal that transmits the broadcast signal is discovered.

  However, the above method has at least the following drawbacks. 1. The location information of the found mobile communication terminal cannot be specified. 2. There is a large probability of discovery failure.

  The second drawback will be described as follows. Since all users select using the same resource set, there are multiple users (for example, user B and user C) in the vicinity of user A, and it is possible to select the use of the same resource and transmit a discovery signal There is sex. In this case, from the viewpoint of the user A, when the user A monitors the resource, the plurality of users may transmit a discovery signal using the same resource, thereby causing mutual interference between the signals. This results in a discovery failure for users (eg, user B and user C).

  An object of an embodiment of the present invention is to provide a device discovery method and apparatus, improve the success rate of mobile communication terminal discovery, and provide rough location information of discovered mobile communication terminals.

  In order to realize the above object, in an embodiment of the present invention, a device discovery method used for a first mobile communication terminal of a mobile communication network is provided. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block. In the device discovery method, the current real geolocation is acquired, the first grid corresponding to the real geolocation is identified based on the first correspondence between the geolocation and the grid, and the grid and transmission resource set Based on a second correspondence relationship in which one transmission resource set is associated with each grid and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold, By identifying the first transmission resource set corresponding to the first grid and transmitting the discovery signal using the resource block in the first transmission resource set, the second mobile communication terminal receives the discovery signal, The first mobile communication terminal is discovered based on the terminal information recorded in the discovery signal, and the transmission resource set in which the resource block used for the discovery signal is located and the second correspondence relationship And Zui includes identifying the first grid location of the first mobile communication terminal.

  In the device discovery method, transmitting a discovery signal using a resource block in the first transmission resource set detects first signal strengths of signals on all resource blocks in the first transmission resource set, and When a first resource block having a corresponding signal strength smaller than a first predetermined signal strength threshold exists in the first transmission resource set, one resource block is selected from the first resource block, and the selected resource block is used to select the resource block. Including transmitting a discovery signal.

  In the above device discovery method, when the signal strength corresponding to any one resource block in the first transmission resource set is greater than or equal to the first predetermined signal strength threshold, the resource block in the transmission resource set other than the first transmission resource set Detecting a second signal strength of the signal, selecting one resource block whose corresponding second signal strength is smaller than a second predetermined signal strength threshold, and transmitting the discovery signal using the selected resource block; Including.

  In order to achieve the above object, in an embodiment of the present invention, a device discovery method used for a second mobile communication terminal of a mobile communication network is further provided. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block. In the device discovery method, the discovery signal is detected in the transmission resource, the terminal information of the first mobile communication terminal recorded in the detected discovery signal is specified, the first mobile communication terminal is discovered, and the detected discovery The first transmission resource set in which the resource block used for the signal is located is specified, one transmission resource set is associated with each grid between the grid and the transmission resource set, and corresponds to the same transmission resource set One of the first grids in which the grid where the first mobile communication terminal is located corresponds to the first transmission resource set based on a second correspondence relationship in which the actual physical distance between any two grids exceeds a predetermined distance threshold. Including the identification.

  In the device discovery method, the area where the first mobile communication terminal is located is one of the actual geographical areas corresponding to the first grid, based on the first correspondence between the geographical position and the grid. It further includes specifying that there is.

  In order to achieve the above object, an embodiment of the present invention further provides a device discovery apparatus used for a first mobile communication terminal of a mobile communication network. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block. In the device discovery apparatus, the first positioning module for acquiring the current actual geolocation and the first grid corresponding to the actual geolocation are identified based on the first correspondence between the geolocation and the grid A real grid distance between any two grids corresponding to the same transmission resource set, wherein one transmission resource set is associated with each grid between the grid and the transmission resource set. Using a first resource identification module for identifying a first transmission resource set corresponding to the first grid based on a second correspondence relationship that exceeds a predetermined distance threshold, and resource blocks in the first transmission resource set. By transmitting the discovery signal, the second mobile communication terminal receives the discovery signal and then receives the discovery signal based on the terminal information recorded in the discovery signal. A mobile communication terminal is discovered, and one of the first grids where the first mobile communication terminal is located is identified based on the transmission resource set where the resource block used for the discovery signal is located and the second correspondence relationship A first transmission module.

  In the device discovery apparatus, the first transmission module includes a first detection unit for detecting first signal strengths of signals on all resource blocks in the first transmission resource set, and a corresponding signal strength is first. When a first resource block smaller than a predetermined signal strength threshold exists in the first transmission resource set, one resource block is selected from the first resource block, and the discovery signal is transmitted using the selected resource block A first transmission unit.

  In the above-described device discovery apparatus, when the signal strength corresponding to any one resource block in the first transmission resource set is equal to or greater than the first predetermined signal strength threshold, on the resource block in the transmission resource set other than the first transmission resource set A second monitoring unit for detecting a second signal strength of the signal and a corresponding one of the resource blocks whose second signal strength is smaller than a second predetermined signal strength threshold, and using the selected resource block A second transmission unit for transmitting the signal.

  In order to realize the above object, in an embodiment of the present invention, a device discovery apparatus used for a second mobile communication terminal of a mobile communication network is further provided. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block. In the device discovery apparatus, a discovery signal detection module for detecting a discovery signal in the transmission resource, and terminal information of the first mobile communication terminal recorded in the detected discovery signal is specified, and the first mobile communication terminal For each grid between the grid and the transmission resource set, a discovery module for finding the first transmission resource set for identifying the first transmission resource set in which the resource block used for the detected discovery signal is located The location of the first mobile communication terminal is based on a second correspondence relationship in which one transmission resource set is associated with and the actual physical distance of any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold. And a second grid specifying module for specifying that the grid to be processed is the first grid corresponding to the first transmission resource set.

  In the device discovery apparatus, the area where the first mobile communication terminal is located is one of the actual geographic areas corresponding to the first grid based on the first correspondence relationship between the geographical position and the grid. It further includes a second positioning module for identifying the presence.

  Specific embodiments of the invention have at least one of the following effects.

  In a specific embodiment of the present invention, since one transmission resource set is associated with each grid, and the actual physical distance of any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold, different movements are performed. The probability of discovery failure caused by the communication terminal using the same resource to transmit a discovery signal can be reduced, that is, the probability of user discovery mistake has been reduced.

  In a specific embodiment of the present invention, when a discovery signal is transmitted, a terminal preferentially selects a resource that is not yet used by another terminal in its own grid, and a terminal having a short distance uses the same resource. Thus, the possibility of transmitting a discovery signal has further decreased, and the probability of a user discovery error has further decreased.

  In a specific embodiment of the present invention, the terminal can identify the approximate location of the terminal that transmits the discovery signal from the resources used for the received discovery signal, and can identify the location without increasing transmission overhead. To do.

  In a specific embodiment of the present invention, when resources corresponding to the own grid are used up, resources that are not yet used in other grids are preferentially transmitted to transmit discovery signals, and different terminals have the same resources. The possibility of transmitting discovery signals using is further reduced, and the probability of user discovery mistakes is further reduced.

It is drawing which shows the flow of the device discovery method of the Example of this invention. It is drawing which shows the flow of another device discovery method of the Example of this invention. It is drawing which shows the structure of the device discovery apparatus of the Example of this invention. It is drawing which shows the structure of another device discovery apparatus of the Example of this invention. It is drawing which shows the grid division of the Example of this invention.

  In the device discovery method and apparatus according to the embodiment of the present invention, mobile communication terminals in different areas that may interfere with each other are used by dividing transmission resources for mobile communication terminal discovery based on geographical location. Since there are relatively few mobile communication terminals in the same area, monitoring avoids selection of resources that are selected and occupied by other mobile communication terminals in the same area. Since it is not often the case that a plurality of terminals simultaneously select and transmit using the same resource block in a finite area, the user's use of the same resource block is reduced, that is, the probability of a user discovery error Fell further.

  The device discovery method of the embodiment of the present invention is used for the first mobile communication terminal of the mobile communication network. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block. As shown in FIG. 1, the device discovery method includes the following steps.

  In step 101, the current actual geographic location is obtained.

  In step 102, a first grid corresponding to the actual geographic location is identified based on a first correspondence between the geographic location and the grid.

  In step 103, the first transmission resource set corresponding to the first grid is specified based on the second correspondence relationship between the grid and the transmission resource set. In the second correspondence relationship, one transmission resource set is associated with each grid, and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold.

  In step 104, the second mobile communication terminal transmits the discovery signal using the resource block in the first transmission resource set, so that the second mobile communication terminal receives the discovery signal and based on the terminal information recorded in the discovery signal. The first mobile communication terminal is discovered, and the first grid where the first mobile communication terminal is located is specified based on the transmission resource set where the resource block used for the discovery signal is located and the second correspondence relationship .

  In a specific embodiment of the present invention, since one transmission resource set is associated with each grid, and the actual physical distance of any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold, different movements are performed. The probability of discovery failure caused by the communication terminal using the same resource and transmitting the discovery signal can be reduced, that is, the probability of user discovery mistake has been reduced. This will be described as follows with an example.

  First, since the actual physical distance of any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold, for a certain grid A using the transmission resource set C, another grid (grid using the transmission resource set C) B) to the grid A is at least a predetermined distance threshold.

  In an embodiment of the present invention, an appropriate predetermined distance threshold can be determined by a plurality of methods. For example, the predetermined distance threshold can be determined in consideration of the target discovery distance of the mobile communication terminal, the discovery signal detection threshold, and the discovery signal propagation attenuation state. If the target discovery distance of the mobile communication terminal is X (that is, other mobile communication terminals whose distance is smaller than X should discover the mobile terminal), and the signal interference ratio of the discovery signal is greater than Z, the detection can be successful, and The signal strength of the discovery signal whose distance is Y or more is smaller than 1 / (Z × T) of the discovery signal whose distance is X (where T is a constant related to the shape of the grid). Then, by setting the predetermined distance threshold to X + Y, it can be ensured that the discovery signal can be successfully detected by the mobile communication terminal within the target discovery distance range.

  Alternatively, let X be the effective transmission distance of the discovery signal transmitted from the mobile communication terminal. If the predetermined distance threshold is greater than 2X, the grids A, B, and C are in a straight line or form a triangle for grids other than the grids A and B (referred to as grid C). When the distance between the grid C and one of A, B is smaller than X, the distance between the grid C and the other of A, B is always greater than X. Therefore, the terminal in the grid C can receive only the discovery signal transmitted from the terminal in the grid A or B at most. Therefore, the probability of discovery failure caused by different mobile communication terminals transmitting discovery signals using the same resource is reduced, that is, the probability of user discovery mistakes is reduced.

  Here, it should be understood that the above-mentioned predetermined distance threshold value X + Y or 2X is two preferred methods of the present invention, and if the predetermined distance threshold value is smaller than X + Y or 2X, the probability of a user discovery error is similarly reduced. it can.

  At the same time, in the specific embodiment of the present invention, since one transmission resource set is associated with each grid, the terminal A performs the same transmission resource in one of the grids during the discovery of other terminals. Only a terminal can be found. Therefore, the terminal A can position the grid where the discovered terminal is located. Compared with the measures of the prior art, the method of the embodiment of the present invention can acquire the location information of the discovered terminal without increasing the transmission overhead, and improves the resource utilization rate of discovery.

  It should be understood that one object of embodiments of the present invention is to reduce the probability of discovery failure caused by different terminals transmitting discovery signals using the same resources, such as It doesn't mean that it doesn't happen completely. This will be described as follows.

  Although the actual physical distance of any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold, since terminals in the same grid share the same transmission resource set, between grid C and grid B for grid C Is smaller than the effective transmission distance X of the discovery signal, the terminal in the grid C can receive only the discovery signal transmitted by the terminal in the grid B. For a terminal in grid C, when two terminals in grid B receive a discovery signal transmitted using the same transmission resource, and a discovery signal transmitted by two terminals in grid C using the same transmission resource is received. If so, there will still be a discovery failure.

  In order to further reduce the probability of discovery failure caused by different mobile communication terminals transmitting discovery signals using the same resource, in a specific embodiment of the present invention, in the same grid, Although the same transmission resource set is used for the terminal, the terminal preferentially selects a resource that is not yet used, rather than randomly selecting a resource block in the transmission resource set.

  In the case of such a scheme, in the embodiment of the present invention, transmitting the discovery signal using the resource block in the first transmission resource set is the first of the signals on all the resource blocks in the first transmission resource set. 1 signal strength is detected, and when a first resource block whose corresponding signal strength is smaller than the first predetermined signal strength threshold exists in the first transmission resource set, one resource block is selected from the first resource block, Transmitting the discovery signal using a resource block.

  According to the above scheme, the probability of discovery failure caused by different mobile communication terminals transmitting discovery signals using the same resource can be further reduced. This will be described as follows.

  After the terminal A identifies the grid in which it is located, the terminal A can identify the corresponding usable transmission resource set. The transmission resource set includes a plurality of resource blocks X1, X2,..., Xn used for transmission of discovery signals. In this case, in the embodiment of the present invention, the terminal A detects the resource blocks X1, X2,..., Xn and specifies the signal strength of the signal on the resource block.

  When the signal strength on a certain resource block (Xm) is equal to or greater than a predetermined threshold, this indicates that the resource block is already occupied by another terminal. When the signal strength is smaller than the predetermined threshold, it indicates that the resource block is in an empty state. At this time, the terminal selects one of the first resource blocks whose corresponding signal strength is smaller than the first predetermined signal strength threshold and transmits the discovery signal.

  According to the above method, when a terminal tries to transmit a discovery signal, a resource block that is not yet used is preferentially selected, so that different mobile communication terminals in the same grid transmit the discovery signal using the same resource. The possibility decreases, i.e. the probability of user discovery mistakes has decreased.

  Of course, the terminal can select one resource block from the first resource block having a corresponding signal strength smaller than the first predetermined signal strength threshold by a plurality of types of methods. For example, after arranging in order of increasing signal strength, a resource block having the lowest signal strength is selected. The corresponding signal strength is randomly selected from the first resource blocks that are smaller than the first predetermined signal strength threshold.

  It should be understood that the probability of a discovery error based on the above-described method of dividing the grid and assigning different transmission resources to different grids and ensuring that the transmission resources assigned to the grids within a given distance are different. However, the terminal resource block selection method in the same grid described above is to further reduce the probability of user discovery mistakes based on the above method, and is not an essential means for reducing the probability of user discovery mistakes.

  Of course, in some special cases, for example, when a relatively large number of users simultaneously use the user discovery function in a grid, any transmission block in the transmission resource set allocated to the grid may be occupied. At this time, if a user who uses a new user discovery function also uses a transmission resource set corresponding to the grid, a plurality of terminals that always transmit discovery signals using the same transmission resource within a small range (within the grid range). May exist, and discovery of other terminals may fail.

  In the above case, in the device discovery method according to the embodiment of the present invention, when the signal strength corresponding to any one resource block in the first transmission resource set is greater than or equal to the first predetermined signal strength threshold, The second signal strength of the signal on the resource block in the transmission resource set is detected, and one resource block whose corresponding second signal strength is smaller than the second predetermined signal strength threshold is selected, and the selected resource block is used to It further includes transmitting a discovery signal.

  With the above method, the probability of user discovery mistakes further decreased. This will be described as follows.

  After the terminal A identifies the grid in which it is located, the terminal A can identify the corresponding usable transmission resource set. The transmission resource set includes a plurality of resource blocks X1, X2,..., Xn used for transmission of discovery signals. In this case, in the embodiment of the present invention, the terminal A detects the resource blocks X1, X2,..., Xn and specifies the signal strength of the signal on the resource block.

  If the signal strength on all resource blocks is greater than or equal to a predetermined threshold, terminal A detects the signal strength on other resource blocks and selects one of the resource blocks whose signal strength is less than the second predetermined signal strength threshold Then, the discovery signal is transmitted.

  If the signal strength on the other resource block is smaller than the predetermined threshold, it indicates that the resources allocated to the other grid are not used yet. At this time, it is possible to select a resource that is not yet used in another grid and transmit a discovery signal.

  The operation process of the device discovery method according to the embodiment of the present invention has been described from the discovery start side. Hereinafter, the device discovery method of the embodiment of the present invention will be further described from the discovery reception side.

  When viewed from the receiving side of discovery, the device discovery method of the embodiment of the present invention is used for the second mobile communication terminal of the mobile communication network. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block. As shown in FIG. 2, the device discovery method includes the following steps.

  In step 201, a discovery signal is detected in the transmission resource.

  In step 202, the terminal information of the first mobile communication terminal recorded in the detected discovery signal is specified to find the first mobile communication terminal.

  In step 203, the first transmission resource set in which the resource block used for the detected discovery signal is located is specified.

  In step 204, based on the second correspondence between the grid and the transmission resource set, the grid where the first mobile communication terminal is located is one of the first grids corresponding to the first transmission resource set. Identifies it. In the second correspondence relationship, one transmission resource set is associated with each grid, and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold.

  Of course, in the device discovery method according to the embodiment of the present invention, the area where the first mobile communication terminal is found corresponds to the first grid based on the first correspondence between the geographical position and the grid. Identifying one of the real geographic areas to be included.

  The embodiment of the present invention further provides a device discovery apparatus used for a first mobile communication terminal of a mobile communication network. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block.

  As shown in FIG. 3, the device discovery apparatus determines the actual geographic location based on a first positioning module for obtaining a current actual geographic location and a first correspondence between the geographic location and the grid. A first grid specifying module for specifying a corresponding first grid, and an arbitrary one corresponding to the same transmission resource set, wherein one transmission resource set is associated with each grid between the grid and the transmission resource set. A first resource identifying module for identifying a first transmission resource set corresponding to the first grid based on a second correspondence relationship in which an actual physical distance between the two grids exceeds a predetermined distance threshold; and the first transmission resource. By transmitting the discovery signal using the resource block in the set, the second mobile communication terminal can receive the discovery signal based on the terminal information recorded in the discovery signal after receiving the discovery signal. The first mobile communication terminal is discovered, and based on the transmission resource set in which the resource block used for the discovery signal is located and the second correspondence relationship, the first mobile communication terminal of the first grid in which the first mobile communication terminal is located A first transmission module for identifying one.

  In order to ensure that terminals in the same grid use different resource blocks as much as possible, the first transmission module detects a first signal strength of signals on all resource blocks in the first transmission resource set. When one detection unit and a first resource block having a corresponding signal strength smaller than a first predetermined signal strength threshold are present in the first transmission resource set, one resource block is selected from the first resource block, and the selected resource block is selected And a first transmission unit for transmitting the discovery signal using.

  In order to ensure that terminals in the same grid use different resource blocks as much as possible, the device discovery apparatus according to the embodiment of the present invention has a signal strength corresponding to any one resource block in the first transmission resource set having a first predetermined value. A second monitoring unit for detecting a second signal strength of a signal on a resource block in a transmission resource set other than the first transmission resource set and a corresponding second signal strength is a second predetermined value if the signal strength threshold is equal to or greater than the signal strength threshold; And a second transmission unit for selecting one resource block smaller than the signal strength threshold and transmitting the discovery signal using the selected resource block.

  The device discovery apparatus on the receiving side used for user discovery according to the embodiment of the present invention is used for the second mobile communication terminal of the mobile communication network. Transmission resources for finding a mobile communication terminal are allocated to the mobile communication network. The transmission resource is divided into a plurality of transmission resource sets, and each transmission resource set includes at least one resource block.

  As shown in FIG. 4, the device discovery apparatus specifies a discovery signal detection module for detecting a discovery signal in the transmission resource, and terminal information of the first mobile communication terminal recorded in the detected discovery signal. A discovery module for discovering the first mobile communication terminal, a second resource identification module for identifying a first transmission resource set in which a resource block used for the detected discovery signal is located, a grid, and a transmission resource set Based on a second correspondence relationship in which one transmission resource set is associated with each grid and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold, A second grid specifying module for specifying that the grid in which the first mobile communication terminal is located is the first grid corresponding to the first transmission resource set.

  Further, in order to position the terminal, the device discovery apparatus is configured such that an area where the first mobile communication terminal is located corresponds to the first grid based on the first correspondence relationship between the geographical position and the grid. A second positioning module is further included for identifying one of the real geographic areas.

  In the following, the method and apparatus of the embodiments of the present invention will be described in further detail as follows with actual examples.

  First, the entire time frequency resource of the physical layer channel used for device discovery is divided into different time frequency resource sets not included in each other, and the time frequency resource sets and the grids are associated with each other.

  The association between the time frequency resource set and the grid is such that the distance between the mobile communication terminals to which the same time frequency resource set is assigned is greater than the predetermined distance X or smaller than the predetermined distance Y (X> Y).

  An example will be described as follows. As shown in FIG. 5, the entire area is divided into a plurality of large tetragonal lattices (areas surrounded by thick solid lines in FIG. 5), and the inside of each large tetragonal lattice is divided into a plurality of small tetragonal lattices. Assume that each large square lattice has N (25 in the drawing) small square lattices.

  At this time, the entire transmission resource used for device discovery is divided into N equal parts, and each equal part is mapped one-to-one on the small tetragonal lattice of each large tetragonal lattice.

  In practice, both large and small square lattices correspond to one corresponding real geographic area (establishing such a correspondence is a common technical means and is often used in technical fields such as electronic maps and navigation. But not detailed here).

  Each mobile communication terminal shall determine which small square lattice it is in from its physical location information and select the corresponding time frequency resource set to make its own high priority level time frequency resource set. Can do.

  Based on the above scheme, when two mobile communication terminals use the same time-frequency resource set when transmitting discovery signals, they belong to the same small tetragonal lattice of different large tetragonal lattices or It belongs to the same small tetragonal lattice. That is, the physical distance becomes larger than the distance X or smaller than the distance Y.

  After establishing the correspondence (geographic location-grid correspondence, grid-transmission resource set correspondence), it is necessary to inform the mobile communication terminal of the correspondence.

  Such a correspondence relationship may be stored in the mobile communication terminal by a pre-stored method, may be notified to the terminal by a broadcast method from the network side, and further, a parameter for calculating the correspondence relationship from the network side may be set. It may be transmitted to the terminal and calculated by the terminal.

  The mobile network notifies the mobile communication terminal of the time frequency resource set in the previous step and the mapping between it and the geographical location. The mobile network can notify parameters such as the distance X and the distance Y through broadcast signaling, for example, but a specific set division method and mapping method can be installed in advance in the mobile communication terminal by default installation. For example, when the set classification method and the mapping method in the previous step are selected, if the values of the distance X and the distance Y are notified, the mobile communication terminal automatically selects the corresponding time frequency resource set of a high priority level from its own position. It can be calculated.

  Hereinafter, it is assumed that the mobile communication terminal calculates a high-priority level time-frequency resource set from its own position, and uses the set partitioning method and the mapping method in the above example.

  If the user is notified via a system broadcast message, the length of the large tetragonal lattice is 1200 meters and the length of the small tetragonal lattice is 80 meters. Then, (1200/80) 2 = 225 small square lattices can be divided into a 1200 meter × 1200 meter square lattice.

  The geographical coordinates of the user are assumed to be 39.984932 north latitude and 116.325248 east longitude. First, the coordinates are converted into coordinates (44221293.87 meters, 1111034.35 meters) in a plane rectangular coordinate system having zeros at north latitude 0 and east longitude 0. Then, the plane rectangular coordinates are modularly calculated with respect to 1200 meters to obtain relative coordinates (493.87, 1033.45) in the large square lattice. From the relative coordinates, it can be specified that the mobile communication terminal is in the seventh small tetragonal lattice from the left in the large tetragonal lattice and the thirteenth small tetragonal lattice from the bottom. The entire time frequency resource of the physical layer channel used for device discovery is equally divided into 225 non-overlapping time frequency resource sets having the same size, and the 225 small square lattices and the 225 time frequency resource sets are associated one-to-one. . Then, a corresponding time frequency resource set can be calculated from the geographical position where the mobile communication terminal itself is located, and it can be selected as a resource set having a relatively high priority level.

  Of course, if the shape of the grid is different (it can be used for hexagons, etc.), the calculation method is also different. It is not described here one by one.

  After the above steps, when the mobile communication terminal attempts to discover neighboring devices, it is possible to specify a transmission resource set that can be further used by first determining which small square lattice (grid) is from its own geographical position.

  Thereafter, in order to avoid using the same resources as the terminals in the same grid, the mobile communication terminal first monitors the transmission resources corresponding to the grid, and the signal strength on these transmission resources is greater than a predetermined value. Determine whether or not.

  The magnitude of the predetermined value is that when another mobile communication terminal transmits a discovery signal using a similar time frequency resource within a predetermined interference range, the mobile communication terminal has a signal strength higher than the predetermined value in the time frequency resource. Can be set such that the detection probability is relatively large.

  When the signal strength on all the high-priority level time frequency resources becomes larger than the predetermined value, it indicates that all transmission resources allocated to the own grid are used. At this time, the user monitors the entire time-frequency resource used for device discovery (can be merged with the first monitoring), and based on the detection result, a predetermined rule (for example, the lowest signal strength principle or the order of smaller energy) It is necessary to select one time frequency resource in accordance with (for example, selecting a 5% time frequency resource which is the lowest energy, and then selecting at random), and transmitting a discovery signal. Otherwise, the user selects a time frequency resource of 5% that is the lowest energy in order of increasing energy from transmission resources allocated to the own grid, and then randomly selects one time frequency resource and finds a discovery signal. Send.

  After receiving the discovery signal, the counterpart mobile communication terminal can first discover the terminal that transmitted the discovery signal from the terminal information recorded in the discovery signal, and at the same time is located from the resources used for the discovery signal. The small tetragonal lattice can be specified, and the approximate position of the detected mobile communication terminal is specified. Of course, in a specific embodiment of the present invention, when positioning is required, if the transmission resource set corresponding to the grid where the mobile communication terminal is located is not selected in order to guarantee the positioning accuracy, the mobile communication terminal A notification field for recording whether or not to select a transmission resource set corresponding to the grid in which the is located can be installed in the discovery signal. Thereby, the other party decides whether or not to locate it from the field.

  The above descriptions are only preferred embodiments of the present invention. For those skilled in the art, some further improvements and modifications can be made without departing from the principle of the present invention. These improvements and modifications should be considered within the protection scope of the present invention.

Claims (10)

In a device discovery method used for a first mobile communication terminal of a mobile communication network, which is divided into a plurality of transmission resource sets each including at least one resource block and assigned transmission resources for discovering mobile communication terminals,
Get the current real geolocation,
Identifying a first grid corresponding to the actual geographic location based on a first correspondence between the geographic location and the grid;
A second correspondence relationship between a grid and a transmission resource set, in which one transmission resource set is associated with each grid, and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold To identify a first transmission resource set corresponding to the first grid,
By transmitting a discovery signal using a resource block in the first transmission resource set, a second mobile communication terminal receives the discovery signal and then receives the first signal based on terminal information recorded in the discovery signal. Including finding a mobile communication terminal and identifying the first grid where the first mobile communication terminal is located based on a transmission resource set where a resource block used for a discovery signal is located and the second correspondence relationship. A device discovery method characterized by: Transmitting a discovery signal using a resource block in the first transmission resource set,
Detecting first signal strengths of signals on all resource blocks in the first transmission resource set;
When a first resource block having a corresponding signal strength smaller than a first predetermined signal strength threshold exists in the first transmission resource set, one resource block is selected from the first resource block, and the selected resource block is used to select the resource block. The device discovery method according to claim 1, further comprising transmitting a discovery signal. If the signal strength corresponding to any one resource block in the first transmission resource set is greater than or equal to the first predetermined signal strength threshold, the second signal strength of the signal on the resource block in the transmission resource set other than the first transmission resource set is Detect
The method of claim 2, further comprising: selecting one resource block having a corresponding second signal strength smaller than a second predetermined signal strength threshold, and transmitting the discovery signal using the selected resource block. The described device discovery method. In a device discovery method used for a second mobile communication terminal of a mobile communication network, which is divided into a plurality of transmission resource sets each including at least one resource block and assigned transmission resources for discovering mobile communication terminals,
Performing discovery signal detection in the transmission resource;
Identifying the first mobile communication terminal by identifying the terminal information of the first mobile communication terminal recorded in the detected discovery signal,
A first transmission resource set in which a resource block used for the detected discovery signal is located;
A second correspondence relationship between a grid and a transmission resource set, in which one transmission resource set is associated with each grid, and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold And identifying that the grid where the first mobile communication terminal is located is one of the first grids corresponding to the first transmission resource set.   Identifying the area where the first mobile communication terminal is located as one of the actual geographic areas corresponding to the first grid based on a first correspondence between a geographic location and a grid; The device discovery method according to claim 4, further comprising: In a device discovery apparatus used for a first mobile communication terminal of a mobile communication network, which is divided into a plurality of transmission resource sets each including at least one resource block and assigned transmission resources for discovering mobile communication terminals,
A first positioning module for obtaining a current real geolocation;
A first grid identifying module for identifying a first grid corresponding to the actual geographic location based on a first correspondence between the geographic location and the grid;
A second correspondence relationship between a grid and a transmission resource set, in which one transmission resource set is associated with each grid, and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold A first resource identification module for identifying a first transmission resource set corresponding to the first grid;
By transmitting a discovery signal using a resource block in the first transmission resource set, a second mobile communication terminal receives the discovery signal and then receives the first signal based on terminal information recorded in the discovery signal. A mobile communication terminal is discovered, and one of the first grids where the first mobile communication terminal is located is identified based on the transmission resource set where the resource block used for the discovery signal is located and the second correspondence relationship And a first transmission module for performing the device discovery. The first transmission module includes:
A first detection unit for detecting a first signal strength of signals on all resource blocks in the first transmission resource set;
When a first resource block having a corresponding signal strength smaller than a first predetermined signal strength threshold exists in the first transmission resource set, one resource block is selected from the first resource block, and the selected resource block is used to select the resource block. The device discovery apparatus according to claim 6, further comprising: a first transmission unit for transmitting a discovery signal. If the signal strength corresponding to any one resource block in the first transmission resource set is greater than or equal to the first predetermined signal strength threshold, the second signal strength of the signal on the resource block in the transmission resource set other than the first transmission resource set is A second monitoring unit for detecting;
And a second transmission unit for selecting one resource block having a corresponding second signal strength smaller than a second predetermined signal strength threshold and transmitting the discovery signal using the selected resource block. The device discovery apparatus according to claim 7, wherein the device discovery apparatus is a device. In a device discovery apparatus used for a second mobile communication terminal of a mobile communication network, which is divided into a plurality of transmission resource sets each including at least one resource block and assigned transmission resources for discovering mobile communication terminals,
A discovery signal detection module for detecting a discovery signal in the transmission resource;
A discovery module for discovering the first mobile communication terminal by identifying terminal information of the first mobile communication terminal recorded in the detected discovery signal;
A second resource identification module for identifying a first transmission resource set in which a resource block used for the detected discovery signal is located;
A second correspondence relationship between a grid and a transmission resource set, in which one transmission resource set is associated with each grid, and the actual physical distance between any two grids corresponding to the same transmission resource set exceeds a predetermined distance threshold And a second grid specifying module for specifying that the grid in which the first mobile communication terminal is located is the first grid corresponding to the first transmission resource set. apparatus.   Based on the first correspondence relationship between the geographical position and the grid, a first location for specifying that the area where the first mobile communication terminal is located is one of the actual geographical areas corresponding to the first grid. The device discovery apparatus according to claim 9, further comprising a two-positioning module.

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