WO2017156748A1 - 一种信标发送方法及装置、网络接入方法及装置 - Google Patents
一种信标发送方法及装置、网络接入方法及装置 Download PDFInfo
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- H04B10/00—Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
- H04B10/11—Arrangements specific to free-space transmission, i.e. transmission through air or vacuum
- H04B10/114—Indoor or close-range type systems
- H04B10/116—Visible light communication
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J3/00—Time-division multiplex systems
- H04J3/16—Time-division multiplex systems in which the time allocation to individual channels within a transmission cycle is variable, e.g. to accommodate varying complexity of signals, to vary number of channels transmitted
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- H04B10/07—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems
- H04B10/075—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems using an in-service signal
- H04B10/079—Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems using an in-service signal using measurements of the data signal
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Definitions
- the present application relates to the field of optical communication technologies, and in particular, to a beacon transmission method and apparatus, and a network access method and apparatus.
- VLC Visible Light Communication
- FIG. 1 is a schematic diagram of a visible light communication system.
- the transmitter encodes and modulates the transmitted data signal, and the coded modulated data signal (ie, Mt) is used to modulate the intensity of the LED light source to generate a light intensity modulated signal (ie, Xt); at the receiving end, photodetection is used.
- VPAN Visible Light Communication Personal Area Network
- VPAN Visible Light Communication Personal Area Network
- each VPAN there is a service node called a coordinator that manages the operation of the VPAN. This coordinator may be located on an LED light source.
- Figure 2 shows the topology of a common star (English: star) VPAN. In this network, there is a coordinator that provides network access services for multiple devices (English: devices) in the network.
- the IEEE 802.15.7 standard supports two working modes, beacon-enabled VPAN and Non-Beacon enabled VPAN.
- the coordinator in the Beacon enabled VPAN periodically sends a beacon (English: beacon).
- Beacon transmission time slots (or beacon time slots) periodically occupy each of the superframes Starting position.
- the structure of a superframe is as shown in FIG. 3.
- One superframe includes an active period and an inactive period, and the active period includes a beacon slot for transmitting a beacon, and a contention access period (English: Contention Access Period, abbreviation: CAP).
- contention free period English: Contention Free Period, abbreviation: CFP.
- the starting position of the superframe is a beacon slot for the coordinator to send a beacon, and the beacon carries some common information of the network, such as the number of the network (English: Identification), the length of the superframe, and the like.
- the global coordinator is responsible for the management and coordination of multiple VPANs (as represented by VPAN1, VPAN2, VPAN3, VPAN4, etc.).
- Each VPAN has its own coordinator (as indicated by CCO1, CCO2, CCO3, CCO4, etc.) for the management of its respective VPAN (such as bandwidth allocation, etc.).
- any VPAN When any VPAN is initially established, it is guaranteed by the global coordinator to be aligned with the start and end positions of the periodic superframes of other VPANs. Since the global coordinator may not be aware of the possible interference conditions of each VPAN, interference coordination is not performed when any VPAN is initially established. To avoid waste of bandwidth resources, when the VPAN is initially established, the coordinators of each VPAN occupy the same beacon slot to transmit beacons, and the global coordinator performs beacon slots and after obtaining VPAN interference related information from the coordinators of the respective VPANs. Coordination of resource allocation.
- the device when the device needs to access the network, it first performs channel scanning, listens for the beacon periodically sent by the surrounding coordinator for a period of time, and measures the channel quality according to the received beacon, and selects the measurement.
- the channel quality of the best beacon corresponds to the VPAN for access.
- the coordinators of different VPANs occupy the same beacon slot to transmit the beacon. Therefore, the equipment in the interference region of two mutually interfering VPANs receives the coordination of the two mutually interfered VPANs.
- the beacon is simultaneously transmitted, the two beacons received may not be correctly detected and decoded, so that the network cannot be properly accessed.
- the overlapping area between VPAN1 and VPAN2 as shown in FIG. 4 is an interference area of two VPANs. Since there is no device that has already been accessed in the interference area between the current two VPANs, the global coordinator does not need to Interference coordination is performed on the interference area. If a device in the interference area of two VPANs wants to access the network at this time, the beacon cannot be correctly detected due to interference, and thus cannot be detected. Normal access to the network.
- the present invention provides a beacon transmitting method and device, a network access method and a device, which are used to solve the problem that when at least two VPANs that interfere with each other do not perform interference coordination, devices in the interference area want to enter the network, and the beacon cannot be correctly detected.
- the problem is that the network cannot be accessed normally.
- a beacon transmission method comprising: a coordinator transmitting a beacon, the beacon occupying a first beacon slot of a current superframe; and the coordinator receiving a first beacon request frame,
- the first beacon request frame is configured to indicate that the device is in an interference region between an area of the first network where the coordinator is located and an area of the at least one second network; the coordinator continues to transmit the beacon and satisfies the following Condition: in the N superframes starting from the next superframe, respectively occupying the first beacon slot and the second beacon slot of each of the N superframes, N ⁇ 1, N Is a positive integer.
- the present application is described by taking the first network and the second network as an example, those skilled in the art can understand that the first and second networks can be jointly belong to the same larger network.
- the device when receiving the beacon request frame sent by the device, by transmitting at least two beacons in one super frame, the device can correctly detect the beacon in time, thereby increasing the probability that the device correctly detects the beacon, so that the device Can access the network normally.
- the first beacon slot and the second beacon slot are both located in a beacon slot area in a superframe, and
- the second beacon slot is an idle slot, and the beacon slot region is a time period in which only a beacon is transmitted in a superframe, and the idle slot is not used in the beacon slot region.
- the coordinator in any one of the mutually interfering VPANs transmits the time slot of the beacon; or the first beacon slot is located in a beacon slot area in the superframe, and the second beacon slot is located in the superframe CFP area.
- the coordinator is in a beacon that is sent by using the first beacon slot
- the carried beacon type is an original beacon
- the beacon type carried by the coordinator in the beacon that is sent in the second beacon slot is an additional beacon
- the original beacon is used to indicate the beacon Coordinator week A beacon that is periodically transmitted
- the additional beacon is used to indicate that the beacon is a beacon that is additionally transmitted by the coordinator beyond the original beacon.
- the coordinator occupies the first one of each of the N superframes After the beacon slot and the second beacon slot send the beacon, the method further includes: the coordinator receiving the association request frame sent by the device, and the time occupied by the N super frames does not reach a set threshold And the device is associated with the device; or the coordinator does not receive the association request frame sent by the device, and the time occupied by the N super frames reaches the set threshold, A beacon is transmitted in a first beacon slot in each superframe after N superframes. In this way, when the device cannot detect the beacon through the additional second beacon slot, the resource of the second beacon slot can be released in time to avoid resource waste.
- the association request frame carries a beacon type indication, where the beacon type indication is used to represent the An association request initiated by the device by detecting the original beacon or an association request initiated by the device by detecting the additional beacon; after the coordinator receives the association request frame sent by the device, according to the The beacon type indication carried in the association request frame, if it is determined that the device initiates an association request by detecting the original beacon, the interference coordination is not triggered; if the association request is initiated by detecting the additional beacon, Then trigger interference coordination.
- the device can determine the interference coordination when the interference coordination needs to be performed through the indication information of the device in the association request frame, and ensure the normal network access of other subsequent devices, thereby improving the performance of the network system of multiple VPANs.
- the coordinator uses the interference carried in the association request frame in the process of triggering the interference coordination parameter.
- the method further includes: if the coordinator receives the second beacon request frame sent by the device, and the N If the time occupied by the superframes does not reach the set threshold, the first beacon slot and the third beacon slot in each superframe after the N superframes are respectively occupied to transmit beacons, The third beacon slot is located in the CFP area. The problem of beacon interference occurring again due to the collision of the second beacon slot is solved.
- the first beacon The request frame carries a field characterizing the address of the device; the format of the second beacon request frame is the same as the format of the first beacon request frame.
- the first beacon request frame further carries a field that identifies the cause of the request, and represents a sequence number of the sent beacon request frame. At least one of a field, a field characterizing a retransmission beacon request frame number, and a field characterizing a target access coordinator address.
- a second aspect of the present invention provides a network access method, including: performing a beacon detection before the device accesses the first network; and the device cannot correctly detect the message when the detected time reaches a set first time duration threshold. And transmitting a first beacon request frame, where the first beacon request frame is used to indicate that the device is in an interfered state.
- the interfered state is used to indicate that the device is in a state of an area where different networks interfere with each other.
- the beacon request frame is actively sent to notify the coordinator to perform related processing, thereby increasing the probability that the device is correctly connected to the network.
- the method further includes: the device continues to perform beacon detection; and if the time of continuing to detect does not reach the set second duration threshold, the correct detection is performed. Go to the beacon and determine that the detected beacon is sent by the coordinator in the first network, then send an association request frame to the coordinator in the first network, the association request frame is used to Coordinator in the first network requests association; if the beacon is still not correctly detected when the time of continuing detection reaches the set second duration threshold, then the second is sent to the coordinator in the first network A beacon request frame, the second beacon request frame is used to indicate that the device is still in an interfered state. The disturbed state indicates that the device is still in a state of an area where different networks interfere with each other. In this way, by continuing to send the beacon request frame, the coordinator is informed in time when the beacon is still not correctly detected. Continue to do the corresponding processing to ensure that it can correctly detect the beacon and enter the network normally.
- the device further includes: the device performing the detection of the beacon Parsing, determining a beacon type included in the beacon; the beacon type is an original beacon or an additional beacon; the original beacon is used to indicate that the beacon is a beacon periodically sent by the coordinator; the additional letter The beacon is used to indicate that the beacon is an additional beacon sent by the coordinator beyond the original beacon.
- the device further includes: if the device determines And the beacon type included in the beacon is an original beacon, and the association request frame sent to the coordinator in the first network carries a beacon type used to represent an association request initiated by the device by detecting the original beacon. Instructing, if the device determines that the beacon type included in the beacon is an additional beacon, carrying the association request frame sent to the coordinator in the first network to represent the device by detecting the additional beacon And the beacon type indication of the initiated association request.
- the device performs interference parameter detection in performing the beacon detection process; If it is determined that the beacon type included in the beacon is an additional beacon, the detected interference frame sent to the coordinator in the first network further carries the detected interference parameter.
- the first beacon request frame carries a characterizing the device address a field; the format of the second beacon request frame is the same as the format of the first beacon request frame.
- the first beacon request frame further carries a field that identifies the cause of the request, and identifies a sending beacon request frame sequence number. At least one of a field, a field characterizing a retransmission beacon request frame number, and a field characterizing a target access coordinator address.
- the third aspect provides a network access method, including: performing network detection before the device accesses the first network, where the network detection includes beacon detection and interference parameter detection; and the device reaches the detection time.
- the network detection includes beacon detection and interference parameter detection
- the device reaches the detection time.
- the beacon cannot be correctly detected, and then the first The coordinator in the network sends an interference indication frame, where the interference indication frame carries the detected interference parameters of the first network and the at least one second network.
- the device determines that the beacon cannot be detected correctly, the device sends the interference indication frame in time, so that the coordinator can trigger the interference coordination process in time, so that the device accesses the network as soon as possible after the interference is coordinated, and ensures that other devices can correctly detect the subsequent devices.
- Bypassing the beacon into the network normally improves the performance of multiple VPAN network systems.
- the interference parameter includes the identifier information of the first network and the second network
- the device receives the first network signal, and The quality of the at least one second network signal.
- a fourth aspect provides a network access method, including: a coordinator in a first network receives an interference indication frame sent by a device, where the interference indication frame carries an interference parameter, and the interference parameter indicates at least one second network interference. Interference information of the first network; the coordinator triggers interference coordination according to the interference indication frame.
- the coordinator when the coordinator receives the interference indication frame sent by the device, it can trigger the interference coordination process in time, so that the device accesses the network as soon as possible after the interference is coordinated, and ensures that other devices can correctly detect the beacon entering the network normally, and improve the network.
- the interference parameter includes the identifier information of the first network and the identifier information of the at least one second network, and/or the device Receiving information of the quality of the first network signal and the at least one second network signal.
- the coordinator triggers interference coordination, including: the coordinator manages the coordination
- the global coordinator of the device sends an interference coordination request message, where the interference coordination request message includes the interference parameter; the coordinator receives an interference coordination response message returned by the global coordinator, where the interference coordination response message includes
- the coordinator is configured to send a beacon slot of the beacon; the coordinator transmits a beacon according to the beacon slot indicated by the global coordinator according to the interference coordination response message.
- a beacon transmitting apparatus having the first implementation Aspects and functions of any one of the first to eighth possible implementations of the first aspect.
- the functions may be implemented by hardware or by corresponding software implemented by hardware.
- the hardware or software includes one or more modules corresponding to the functions described above.
- the beacon transmitting device can be a coordinator.
- the structure of the coordinator includes a transceiver, a memory, and a processor, where the memory is used to store a group a program, the transceiver, configured to: transmit a beacon, the beacon occupies a first beacon slot of a current superframe; and, for receiving a first beacon request frame, the first beacon request frame is used to Instructing the device to be in an interference region between an area of the first network where the coordinator is located and an area of the at least one second network; the processor, configured to invoke a program stored by the memory, to perform: in the sending and receiving After receiving the first beacon request frame, determining that the first beacon slot and the first of each of the N superframes occupy the first beacon slot of each of the N superframes from the N superframes starting from the next superframe Transmitting, by the second beacon slot, the beacon; the transceiver is further configured to: under the control of the processor, occupy N each of the N
- the device when receiving the beacon request frame sent by the device, by transmitting at least two beacons in one super frame, the device can correctly detect the beacon in time, thereby increasing the probability that the device correctly detects the beacon, so that the device Can access the network normally.
- the processor is further configured to invoke the program stored in the memory, so that the coordinator performs the foregoing A method as claimed in any one of the first to eighth possible implementations.
- a network access apparatus having a function of implementing any one of the first to sixth possible implementation manners of the second aspect and the second aspect.
- the functions may be implemented by hardware or by corresponding software implemented by hardware.
- the hardware or software includes one or more modules corresponding to the functions described above.
- the network access device may be a device in a network, and the structure of the device in the network includes a transceiver, a memory, and a processor, where The memory is configured to store a set of programs, the processor is configured to invoke the program stored by the memory to perform: performing beacon detection before accessing the first network; and detecting the time reaches a set first duration threshold
- the control transceiver sends a first beacon request frame, the first beacon request frame is used to indicate that the device is in an interfered state; and the transceiver is configured to be in the process
- the first beacon request frame is transmitted under the control of the device.
- the beacon request frame is actively sent to notify the coordinator to perform related processing, thereby increasing the probability that the device is correctly connected to the network.
- the processor is further configured to: invoke the program stored in the memory, so that the device performs the foregoing The method of any one of the first to sixth possible implementations of the second aspect.
- a network access device having the function of implementing the method design in the first possible implementation manner of the third aspect or the third aspect.
- the functions may be implemented by hardware or by corresponding software implemented by hardware.
- the hardware or software includes one or more modules corresponding to the functions described above.
- the network access device may be a device in a network, where the structure of the device in the network includes a transceiver, a memory, and a processor, where The memory is configured to store a set of programs, the processor is configured to invoke the program stored by the memory to perform: performing network detection, including beacon detection, interference parameter detection, before accessing the first network; When the detected time reaches the set first duration threshold and the beacon is still not correctly detected, the transceiver is instructed to send an interference indication frame to the coordinator in the first network, where the interference indication frame is detected in the bearer.
- the interference parameter of the first network and the at least one second network; the transceiver is configured to send the interference indication frame to a coordinator in the first network under the instruction of the processor.
- the processor is further configured to invoke the program stored in the memory to cause the device to perform the method as described in the first possible implementation manner of the foregoing third aspect.
- a network access apparatus having a function of implementing any one of the first to second possible implementation manners of the fourth aspect and the fourth aspect.
- the functions may be implemented by hardware or by corresponding software implemented by hardware.
- the hardware or software includes one or more modules corresponding to the functions described above.
- the network access device may be a coordinator, and the structure of the coordinator includes a transceiver, a memory, and a processor, where the transceiver is used to Receiving, by the receiving device, an interference indication frame, where the interference indication frame carries an interference parameter, where the interference parameter indicates that at least one second network interferes with interference information of the first network; and the memory is used to store a set of programs, where The processor is configured to invoke the program stored by the memory to perform: triggering interference coordination according to the interference indication frame received by the transceiver.
- the processor is further configured to: invoke the program stored in the memory, so that the coordinator performs the foregoing The method of any one of the first to second possible implementations of the fourth aspect.
- the solution provided by the embodiment of the present application may send at least two beacons in a superframe by adding a beacon slot when the device cannot correctly detect the beacon due to beacon interference, so that the device is enabled.
- the beacon can be correctly detected in time, and the network is normally connected to the network, and the indication information in the association request frame can be used to determine the interference coordination when the interference coordination needs to be performed, and the subsequent network access of other devices is ensured, and the network of multiple VPANs is improved. System performance.
- FIG. 1 is a schematic diagram of a visible light communication system in the prior art
- FIG. 2 is a schematic topological diagram of a star VPAN in the prior art
- FIG. 3 is a schematic structural diagram of a superframe in the prior art
- FIG. 5 is a schematic diagram of correspondence between beacon slots in a superframe when each VPAN is initially established according to an embodiment of the present application
- FIG. 6 is a schematic diagram of correspondence between beacon slots after interference coordination between VPANs in the embodiment of the present application.
- Figure 7 is a flowchart of a method provided by an embodiment of the present application.
- FIG. 8 is a schematic diagram of a superframe after adding a second beacon slot according to an embodiment of the present application.
- FIG. 9 is a second schematic diagram of a superframe after adding a second beacon slot according to an embodiment of the present application.
- Figure 10 is a second flowchart of the method provided by the embodiment of the present application.
- 11a and 11b are structural diagrams of a beacon transmitting apparatus according to an embodiment of the present application.
- FIG. 12 is a structural diagram of a network access apparatus according to an embodiment of the present application.
- FIG. 13 is a second structural diagram of a network access device according to an embodiment of the present application.
- FIG. 14 is a third structural diagram of a network access apparatus according to an embodiment of the present application.
- FIG. 15 is a structural diagram of a coordinator according to an embodiment of the present application.
- Figure 16 is a structural diagram of a device according to an embodiment of the present application.
- the embodiment of the present application is applicable to a VLC system, and is preferably, but not limited to, a centralized interference coordination mode.
- the system architecture diagram is shown in FIG. 4, and each VPAN has a coordinator to manage its own network.
- the global coordinator GCCO. responsible for the management and coordination of multiple VPANs.
- VPAN1, VPAN2, VPAN3, and VPAN4 responsible for the management and coordination of multiple VPANs.
- the coordinators in the four VPANs are respectively represented by CCO1, CCO2, CCO3, and CCO4.
- the beacon slot transmits a beacon.
- FIG. 5 shows two consecutive superframes, and the structure of the superframe is exemplified by the structure shown in FIG.
- the black rectangular area in each superframe represents a beacon slot, and the beacon slot is at the beginning of a superframe.
- the beacon slots in the superframes of VPAN1, VPAN2, VPAN3, and VPAN4 are aligned, that is, CCO1, CCO2, CCO3, and CCO4 occupy the same beacon slot to transmit beacons.
- the GCCO will perform interference coordination on the VPANs that interfere with each other. For example, time-division is used for interference coordination. As shown in Figure 6, it is assumed that there is interference between VPAN1 and VPAN3, and there are already connected devices in the interference area. GCCO has already conducted interference coordination on the time division between VPAN1 and VPAN3. After coordination, CCO1 and CCO3 occupy Different beacon slots transmit beacons, CCO3 occupies a beacon after one slot after the original beacon slot, and CCO1 still occupies the original beacon slot to transmit beacons. Of course, the other coordinators that have not been coordinated still occupy the same beacon slot to transmit the beacon. For each VPAN, in a superframe, after interference coordination, the total area of beacon slots occupied by all coordinators that have passed interference coordination may be referred to as a beacon slot area, as indicated in FIG. region.
- the GCCO does not need to perform interference coordination on the VPANs that interfere with each other.
- the device is in an interference region between different VPANs that do not perform interference coordination, beacon detection is performed when the network is to be accessed, and beacon interference may occur, so that the beacon cannot be correctly detected.
- the embodiment of the present application provides a beacon sending method and a network access method. When a device cannot correctly detect a beacon, the beacon request frame is sent to the coordinator, and the coordinator adds a beacon slot to the super The method of sending the beacon twice in the frame increases the probability that the device correctly detects the beacon, enables the device to access the network normally, and can perform interference coordination in time.
- the method of the embodiment of the present application is as follows.
- Step 701 The coordinator uses the first beacon slot of the current superframe to transmit a beacon.
- the first beacon slot may be allocated by the GCCO when the coordinator initially enters the network, or It was adjusted after GCCO interference coordination.
- the VPAN in which the coordinator is located in the following description is referred to as a first network.
- Step 702 The device performs beacon detection before accessing the first network.
- the device when the device wants to access the network, one or more target networks exist, and a target network exists as an example, and the target network is assumed to be the first network where the coordinator is located. After the device is powered on, it scans the channel and performs beacon detection. When the beacon is detected correctly, it will access the network normally.
- Step 703 The device fails to correctly detect the beacon when the detected time reaches the set first duration threshold, and sends a first beacon request frame, where the first beacon request frame is used to indicate the device. In an interfered state.
- the interfered state refers to a state in which the device is in an area where different networks interfere with each other, that is, a state of an interference area between an area of the first network and an area of at least one second network.
- first network and the second network are described by using the first network and the second network as an example, those skilled in the art may understand that the first network and the second network involved in the embodiments of the present application may be common. Belong to the same larger network.
- the device presets a detection duration threshold, which is called a first duration threshold. If the device does not correctly detect the beacon when the detected time reaches the first duration threshold, the device may be considered to be in the area of at least two networks. Interference area, unable to access the network normally. In this case, the device sends a beacon request frame to the coordinator, which is referred to as a first beacon request frame for subsequent convenience.
- the process of the device transmitting the beacon request frame may be: determining, according to the energy detection, the position of the beacon slot in the superframe (the position of the beacon slot determined here, that is, the location of the first beacon slot), and identifying the beacon After the location of the time slot, the CAP after the beacon time slot transmits the beacon request frame as soon as possible, wherein the beacon request frame can be based on carrier sense multiple access/collision avoidance (English: Carrier Sense multiple Access/Collision Avoidance, Abbreviation: CSMA/CA) Competitive transmission.
- carrier sense multiple access/collision avoidance English: Carrier Sense multiple Access/Collision Avoidance, Abbreviation: CSMA/CA
- the beacon request frame is used to report to the coordinator that it is unable to detect the beacon in the interference area.
- the format of the beacon request frame in the embodiment of the present application is not specifically limited, and may be, but is not limited to, the format shown in Table 1 below.
- the beacon request frame carries the address, the reason, the sequence number, the number of retransmissions, and the destination coordinator address.
- the address is mandatory to carry information in the beacon request frame. Others are optional carrying information. Add other carrying information.
- the address field is used to describe the address or identifier of the device that sends the beacon request frame, such as a MAC address, a 64-bit address, etc.; the reason field is used to indicate the reason for sending the beacon request frame, such as the network cannot detect the message.
- the sequence number field is used to represent the sequence number of the beacon request frame. When the beacon request frame is sent for the first time, the sequence number can be set to 0 or 1. After each beacon request frame is sent, the sequence number is incremented by 1, with different sequence numbers.
- the retransmission times field is used to represent that the beacon request frame of the same sequence number is retransmitted a few times, and the same sequence number beacon request frame can be sent to ensure that the transmitted beacon request frame can be reliably received.
- the number of retransmissions on the first transmission is set to 0 or 1, and each retransmission is incremented by one;
- the target coordinator address is used to characterize the address of the coordinator in the target VPAN to which the device is to access.
- Step 704 The coordinator receives the first beacon request frame sent by the device, and respectively occupy the first beacon of each of the N super frames in the N super frames starting from the next super frame.
- the time slot and the second beacon slot transmit a beacon, N ⁇ 1, and N is a positive integer.
- the coordinator parses the beacon request frame, determines that the device is in the interference area, and cannot access the network. Then the coordinator will add a beacon slot to transmit the beacon starting from the next superframe, and the added beacon slot is called the second beacon slot. That is, the beacon is sent twice in one superframe.
- the selection manner of the second beacon slot may be, but not limited to, the following two.
- the first way select a free time slot in the beacon slot area as the second beacon slot.
- a superframe includes a beacon slot area and a non-beacon slot area.
- the non-beacon slot areas are CAP, CFP, and inactive periods.
- the beacon slot area is a time period in which only a beacon is transmitted in a superframe.
- the beacon slot area is a total area of beacon slots occupied by coordinators in all VPANs that have passed interference coordination
- the idle time slot is a time slot in which the coordinator in the VPAN that is not used for any other mutual interference transmits a beacon.
- the beacon slot area after the addition of the second beacon slot includes a second beacon slot area, which is equivalent to enlarging the beacon slot area, and correspondingly, the non-beacon slot area is compressed.
- the beacon slot allocation of each VPAN is as shown in FIG. 6, when the second beacon is added. After the slot, the beacon slot allocation of VPAN1 is as shown in FIG.
- the second way in the CFP area, one time slot is selected as the second beacon slot.
- the first network is VPAN1 shown in FIG. 5, before receiving the beacon request frame, VPAN1 and VPAN3 are subjected to interference coordination, and the beacon slot allocation of each VPAN is as shown in FIG. 6, and the second letter is added. After the time slot is marked, the beacon slot allocation of VPAN1 is as shown in FIG.
- the coordinator carries a beacon type in the beacon sent by the first beacon slot and the second beacon slot, and the beacon type is used to indicate that the beacon is occupied.
- the type of beacon slot including the original beacon and the attached beacon.
- the beacon type carried in the beacon sent in the first beacon slot is the original beacon, indicating that the beacon is sent through the original beacon slot, that is, the beacon periodically sent by the coordinator;
- the type of beacon carried in the beacon transmitted in the second beacon slot is attached A beacon is indicated, indicating that the beacon is an additional beacon sent by the coordinator beyond the original beacon.
- Step 705 The device continues to perform beacon detection after transmitting the first beacon request frame to the coordinator.
- step 706 is performed
- step 706' is performed; or the network access failure is determined.
- Step 706 The device sends an association request frame to the coordinator, where the association request frame is used to request association from the coordinator.
- the association request frame further includes a beacon type indication for indicating an association request initiated by the device by detecting the original beacon or the additional beacon, or detecting the additional beacon by detecting the original beacon.
- a request for association initiated by a beacon since the coordinator adds a beacon type to the beacon sent by the first beacon slot and the second beacon slot, the device can obtain the beacon type by parsing the beacon when detecting the beacon.
- the association request frame further includes an interference parameter, where the interference parameter is obtained by the device in performing beacon detection.
- Step 707 The coordinator receives the association request frame sent by the device, and the time occupied by the N super frames does not reach the set threshold, and is associated with the device.
- the coordinator further determines, according to the beacon type indication included in the association request frame, that the coordinator occupies each superframe after the N superframes when the device initiates an association request by detecting the original beacon.
- the first beacon slot transmits a beacon and uses the second beacon slot for other purposes;
- the coordinator When it is determined that the device is an association request initiated by detecting an additional beacon or by simultaneously detecting the original beacon and the additional beacon, the coordinator triggers interference coordination according to the interference parameter carried in the association request frame.
- Step 706' The device sends a second beacon request frame to the coordinator.
- the second beacon request frame is used to indicate that the device is still in an interfered state, and the interfered state refers to a state in which the device is in an area where different networks interfere with each other.
- the second beacon please The frame is the same as the format of the first beacon request frame, and is distinguished by a different sequence number in the sequence number field.
- the beacon Since the beacon is still not correctly detected when the time when the device continues to detect after the first beacon request frame is sent reaches the set second duration threshold, it may be considered to be sent by the second beacon slot attached by the coordinator. The beacon is still not detected by the device.
- the coordinator adds another beacon slot, which can be respectively The first beacon slot, the second beacon slot, and the fourth beacon slot in each superframe after the N superframes are used to transmit a beacon, that is, three beacons are transmitted in one superframe.
- the coordinator directly ignores the second beacon request frame and does not process it.
- the coordinator performs step 707'.
- Step 707 ′ the coordinator receives the second beacon request frame sent by the device, and the time occupied by the N super frames does not reach the set threshold, and each of the N super frames is occupied respectively.
- a beacon is transmitted by a first beacon slot and a third beacon slot in one superframe, and the third beacon slot is located in the CFP area.
- the coordinator reselects a third beacon slot different from the second beacon slot position in the CFP area to transmit the beacon, which solves the above-mentioned problem of re-beacon interference.
- the threshold is set to transmit the beacon only for the first beacon slot in each superframe after the N superframes.
- a beacon slot is added, and at least two times are sent in one superframe.
- the standard enables the device to correctly detect the beacon in time, and enters the network normally, and can determine the interference coordination in time when the interference coordination is needed through the indication information of the device in the association request frame, so as to ensure the normal network access of other subsequent devices, and improve the number of the beacons.
- the embodiment of the present application further provides a network access method. Referring to FIG. 10, the method is as follows:
- Step 1001 The device performs network detection before accessing the first network, where the network detection includes beacon detection and interference parameter detection.
- the device when the device wants to access the network, there are one or more target networks, and there is a target network as an example, and the target network is assumed to be represented by the first network.
- the device After the device is powered on, it scans the channel and performs network detection, including beacon detection and interference parameter detection. When the beacon is detected correctly, it will normally access the network.
- Step 1002 If the device fails to correctly detect the beacon when the detected time reaches the set first duration threshold, the device sends an interference indication frame to the coordinator in the first network, where the interference indication frame is Carrying the detected interference parameters of the first network and the at least one second network.
- the interference parameter includes the identification information of the first network and the identification information of the at least one second network, and/or the quality of the first network signal and the at least one second network signal received by the device information.
- the device continues to perform beacon detection after transmitting the interference indication frame.
- Step 1003 The coordinator in the first network receives the interference indication frame sent by the device, where the interference indication frame carries an interference parameter, where the interference parameter indicates that the at least one second network interferes with the interference information of the first network.
- the interference indication frame further carries at least one of a field indicating a frame number of the transmission interference indication frame and a field indicating a number of times of retransmission interference indication frame.
- the process of the device transmitting the interference indication frame may be: determining the location of the beacon slot in the superframe based on the energy detection, and after identifying the location of the beacon slot, transmitting the interference indication frame as soon as possible after the CAP of the beacon slot Wherein the interference indication frame may be transmitted based on CSMA/CA contention.
- Step 1004 The coordinator triggers interference coordination according to the interference indication frame.
- the process of interference coordination is as follows:
- the coordinator sends an interference coordination request message to the global coordinator that manages the coordinator, where the interference coordination request message includes the interference parameter;
- the global coordinator After receiving the interference coordination request message, the global coordinator coordinates the mutually interfered network involved in the interference parameter, that is, the first network and the at least one second network are designated to transmit non-interfering beacon slots. Send a beacon.
- the global coordinator transmits an interference coordination response message to the coordinator and the other coordinators in the at least one second network, respectively.
- the interference coordination response message may carry address information of each coordinator, a beacon slot occupied when the beacon is transmitted, and an effective time of the beacon slot allocated this time.
- CCO1 information CCO1 address information Beacon slot number 1 Beacon slot number assigned to CCO1
- CCO2 information CCO2 address information Beacon slot number 2 Beacon slot number assigned to CCO2 Effective time Effective time of this assigned beacon slot
- the coordinator receives an interference coordination response message returned by the global coordinator, where the interference coordination response message includes a beacon slot used by the coordinator to transmit a beacon;
- the coordinator occupies the letter indicated by the global coordinator according to the interference coordination response message
- the beacon is transmitted in the marked time slot.
- the probability that the device correctly detects the beacon is improved, and the device is correctly connected to the network. If the device does not reach the set second duration threshold when the time of the detection continues, the beacon is correctly detected, and Determining that the detected beacon is sent by the coordinator in the first network, sending an association request frame to the coordinator, performing a subsequent association process; if the time of continuing detection reaches the set second duration At the threshold, if the beacon is still not detected correctly, it is determined that the network access failed.
- the device determines that the beacon cannot be detected correctly, the device sends the interference indication frame in time, so that the coordinator can trigger the interference coordination process in time, so that the device accesses the network as soon as possible after the interference is coordinated, and ensures that other devices can correctly detect the subsequent devices.
- Bypassing the beacon into the network normally improves the performance of multiple VPAN network systems.
- a beacon transmitting apparatus 1100 is provided in the embodiment of the present application, including: a sending unit 1101 and a receiving unit 1102.
- a sending unit 1101 configured to send a beacon, where the beacon occupies a first beacon slot of a current superframe
- the receiving unit 1102 is configured to: after the sending unit 1101 sends the beacon, receive a first beacon request frame, where the first beacon request frame is used to indicate that the device is in the first network where the coordinator is located. An interference area between the area and the area of the at least one second network;
- the sending unit 1101 is configured to: after the receiving unit 1102 receives the first beacon request frame, occupy N each of the N superframes from N superframes starting from a next superframe
- the first beacon slot and the second beacon slot of one superframe transmit a beacon, N ⁇ 1, and N is a positive integer.
- the first beacon slot and the second beacon slot are both located in a beacon slot area in a superframe, and the second beacon slot is an idle slot, the letter The marked slot area is a time period in which only a beacon is transmitted in a superframe, and the idle slot is a time when the beacon in the VPAN in the beacon slot area is not used for any other mutual interference to transmit the beacon. Gap; or,
- the first beacon slot is located in a beacon slot area in a superframe
- the second beacon slot is located in a contention free period CFP area in a superframe.
- the sending unit 1101 is configured to:
- the beacon type carried in the beacon that is sent in the first beacon slot is an original beacon
- the beacon type carried in the beacon that is sent in the second beacon slot is an additional beacon
- the original beacon is used to indicate that the beacon is a beacon periodically sent by the sending unit; the additional beacon is used to indicate that the beacon is an additional sent by the sending unit beyond the original beacon. Standard.
- the beacon transmitting apparatus 1100 further includes a processing unit 1105, an example of a connection manner is shown in FIG. 11b, and the sending unit 1101 and the receiving unit 1102 are respectively connected to the processing unit 1105,
- the processing unit 1105 includes an association unit 1103 and a coordination unit 1104, where the association unit 1103 is configured to determine, when the receiving unit 1102 receives the association request frame sent by the device, that the time occupied by the N superframes is not When the set threshold is reached, the device is associated;
- the sending unit 1101 is further configured to: if the receiving unit 1102 does not receive the association request frame sent by the device, and determines that the time occupied by the N super frames reaches the set threshold, only the A beacon is transmitted in a first beacon slot in each superframe after N superframes.
- the association request frame carries a beacon type indication
- the beacon type indication is used to represent an association request initiated by the device by detecting an original beacon, or is used to represent that the device detects the attachment by detecting Association request initiated by the beacon;
- the coordinator 1100 further includes a coordinating unit 1104, configured to: after the receiving unit 1102 receives the association request frame sent by the device, according to the beacon carried in the association request frame received by the receiving unit 1102
- the type indication if it is determined that the device initiates an association request by detecting the original beacon, does not trigger interference coordination; if it determines that the device initiates an association request by detecting the additional beacon, the interference coordination is triggered.
- the coordinating unit 1104 is further configured to use, in the process of triggering the interference coordination, an interference parameter carried in the association request frame received by the receiving unit.
- the second beacon slot is located in a CFP area in a superframe
- the sending unit 1101 is further configured to: when the receiving unit 1102 receives the second beacon request frame sent by the device, determine that the time occupied by the N super frames does not reach the set threshold, And respectively, the first beacon slot and the third beacon slot in each superframe after the N superframes are respectively used to transmit a beacon, where the third beacon slot is located in the CFP area.
- the first beacon request frame carries a field that represents an address of the device; the format of the second beacon request frame is the same as the format of the first beacon request frame.
- the first beacon request frame further carries a field indicating the reason of the request, a field indicating the sequence number of the transmitted beacon request frame, a field indicating the number of retransmission beacon request frames, and a field indicating the address of the target access coordinator. At least one of them.
- a network access device 1200 is provided in the embodiment of the present application, including: a detecting unit 1201 and a sending unit 1202.
- the detecting unit 1201 is configured to perform beacon detection before accessing the first network.
- the sending unit 1202 sends a first beacon request frame when the time detected by the detecting unit 1201 reaches the set first duration threshold and cannot correctly detect the beacon, and the first beacon request frame is used to indicate the location.
- the device is in an interfered state.
- the detecting unit 1201 is further configured to: after the sending unit 1202 sends the first beacon request frame to the coordinator in the first network, continue to perform beacon detection; and if When the time of the continuous detection does not reach the set second duration threshold, the beacon is correctly detected, and it is further determined whether the detected beacon is sent by the coordinator in the first network;
- the sending unit 1202 is further configured to: if the detecting unit 1201 determines that the detected beacon is sent by a coordinator in the first network, send an association request frame to a coordinator in the first network, where The association request frame is configured to request an association from a coordinator in the first network;
- the detecting unit 1201 does not correctly detect the beacon when the time for continuing to detect reaches the set second duration threshold, sending a second beacon request frame to the coordinator in the first network,
- the second beacon request frame is used to indicate that the device is still in an interfered state.
- the detecting unit 1201 is further configured to: after detecting the beacon correctly, parsing the detected beacon, and determining a beacon type included in the beacon;
- the beacon type is an original beacon or an additional beacon
- the original beacon is used to indicate that the beacon is a beacon periodically sent by the coordinator; the attaching The beacon is used to indicate that the beacon is an additional beacon sent by the coordinator beyond the original beacon.
- the sending unit 1202 is further configured to: when the detecting unit 1201 determines that the beacon type included in the beacon is the original beacon, carry the association request frame sent by the coordinator in the first network. a beacon type indication for characterizing an association request initiated by the device by detecting an original beacon;
- the association request frame sent to the coordinator in the first network carries an identifier for detecting that the device detects the additional beacon And the beacon type indication of the initiated association request.
- the detecting unit 1201 is further configured to perform interference parameter detection during the beacon detection process
- the sending unit 1202 is further configured to: when the detecting unit 1201 determines that the beacon type included in the beacon is an additional beacon, the association request frame sent to the coordinator in the first network further carries the The interference parameter detected by the detection unit.
- the first beacon request frame carries a field characterizing the device address; the format of the second beacon request frame is the same as the format of the first beacon request frame.
- the first beacon request frame further carries a field indicating the reason of the request, a field indicating the sequence number of the transmitted beacon request frame, a field indicating the number of retransmission beacon request frames, and a field indicating the address of the target access coordinator. At least one of them.
- another network access apparatus 1300 is further provided in the embodiment of the present application, including: a detecting unit 1301 and a sending unit 1302.
- the detecting unit 1301 is configured to perform network detection before accessing the first network, where the network detection includes beacon detection and interference parameter detection;
- the sending unit 1302 is configured to: when the time detected by the detecting unit 1301 reaches the set first duration threshold and still cannot correctly detect the beacon, send an interference indication frame to the coordinator in the first network, where the interference The indication frame carries the detected interference parameters of the first network and the at least one second network.
- the interference parameter includes identification information of the first network and the second network
- the device receives a quality of the first network signal and the at least one second network signal.
- the embodiment of the present application further provides another network access device 1400.
- the device 1400 is located in a first network, and the device 1400 includes: a receiving unit 1401 and a coordination unit 1402.
- the receiving unit 1401 is configured to receive, by the device, an interference indication frame, where the interference indication frame carries an interference parameter, where the interference parameter indicates that the at least one second network interferes with the interference information of the first network;
- the coordination unit 1402 is configured to trigger interference coordination according to the interference indication frame.
- the interference parameter includes the identifier information of the first network and the identifier information of the at least one second network, and/or the device receives the first network signal and the at least one second network Information on the quality of the signal.
- the method further includes a sending unit 1403, configured to: when the coordinating unit 1402 triggers interference coordination, send an interference coordination request message to the global coordinator that manages the device 1400, the interference coordination request The interference parameter is included in the message;
- the receiving unit 1401 is further configured to receive an interference coordination response message returned by the global coordinator, where the interference coordination response message includes a beacon slot used by the coordinator to send a beacon;
- the sending unit 1403 is further configured to: according to the interference coordination response message received by the receiving unit 1401, occupy a beacon slot indicated by the global coordinator to send a beacon.
- a coordinator 1500 is provided in the embodiment of the present application for performing the functions of the coordinator in the beacon sending method and the network access method provided in the foregoing embodiments of the present application.
- the coordinator 1500 includes a transceiver 1501, a processor 1502, and a memory 1503, wherein the memory 1503 stores a set of programs, and the processor 1502 is configured to invoke a program stored in the memory 1503 such that the coordinator 1500 The method provided in Figure 7 or Figure 10 is performed.
- connection manner between the parts shown in FIG. 15 is only one possible example.
- the transceiver 1501 and the memory 1503 are both connected to the processor 1502, and between the transceiver 1501 and the memory 1503. There is no connection, or it can be other possible connections.
- the processor 1502 may be a central processing unit (English: central processing unit, abbreviation: CPU).
- Network processor English: network processor, abbreviation: NP
- CPU central processing unit
- NP network processor
- the processor 1502 may further include a hardware chip.
- the hardware chip may be an application-specific integrated circuit (ASIC), a programmable logic device (abbreviated as PLD), or a combination thereof.
- ASIC application-specific integrated circuit
- PLD programmable logic device
- the above PLD can be a complex programmable logic device (English: complex programmable logic device, abbreviation: CPLD), field-programmable gate array (English: field-programmable gate array, abbreviation: FPGA), general array logic (English: generic array Logic, abbreviation: GAL) or any combination thereof.
- the memory 1501 may include a volatile memory (English: volatile memory), such as a random access memory (English: random-access memory, abbreviation: RAM); the memory 1501 may also include a non-volatile memory (English: non-volatile memory) ), such as flash memory (English: flash memory), hard disk (English: hard disk drive, abbreviated: HDD) or solid state drive (English: solid-state drive, abbreviation: SSD); the memory 1501 may also include the above types of memory The combination.
- a volatile memory English: volatile memory
- RAM random access memory
- non-volatile memory such as flash memory (English: flash memory), hard disk (English: hard disk drive, abbreviated: HDD) or solid state drive (English: solid-state drive, abbreviation: SSD)
- the memory 1501 may also include the above types of memory The combination.
- an apparatus 1600 is provided in the embodiment of the present application for performing the functions of the device in the beacon sending method and the network access method provided in the foregoing embodiments of the present application.
- the device 1600 includes a transceiver 1601, a processor 1602, and a memory 1603, wherein the memory 1603 stores a set of programs, and the processor 1602 is configured to invoke a program stored in the memory 1603, such that the device 1600 executes a map. 7 or the method provided in Figure 10.
- connection manner between the parts shown in FIG. 16 is only one possible example. It may also be that the transceiver 1601 and the memory 1603 are both connected to the processor 1602, and between the transceiver 1601 and the memory 1603. There is no connection, or it can be other possible connections.
- the processor 1602 may be a central processing unit (English: central processing unit, abbreviated: CPU), a network processor (English: network processor, abbreviated: NP) or a combination of a CPU and an NP.
- CPU central processing unit
- NP network processor
- the processor 1602 can also further include a hardware chip.
- the hardware chip may be an application-specific integrated circuit (ASIC), a programmable logic device (abbreviated as PLD), or a combination thereof.
- ASIC application-specific integrated circuit
- PLD programmable logic device
- PLD programmable logic device
- It can be a complex programmable logic device (English: complex programmable logic device, abbreviation: CPLD), field-programmable gate array (English: field-programmable gate array, abbreviation: FPGA), general array logic (English: general array logic, Abbreviation: GAL) or any combination thereof.
- the memory 1601 may include a volatile memory (English: volatile memory), such as a random access memory (English: random-access memory, abbreviation: RAM); the memory 1001 may also include a non-volatile memory (English: non-volatile memory) ), such as flash memory (English: flash memory), hard disk (English: hard disk drive, abbreviated: HDD) or solid state drive (English: solid-state drive, abbreviation: SSD); the memory 1001 may also include the above types of memory The combination.
- a volatile memory English: volatile memory
- RAM random access memory
- the memory 1001 may also include a non-volatile memory (English: non-volatile memory) ), such as flash memory (English: flash memory), hard disk (English: hard disk drive, abbreviated: HDD) or solid state drive (English: solid-state drive, abbreviation: SSD); the memory 1001 may also include the above types of memory The combination.
- embodiments of the present application can be provided as a method, system, or computer program product.
- the present application can take the form of an entirely hardware embodiment, an entirely software embodiment, or an embodiment in combination of software and hardware.
- the application can take the form of a computer program product embodied on one or more computer-usable storage media (including but not limited to disk storage, CD-ROM, optical storage, etc.) including computer usable program code.
- the computer program instructions can also be stored in a computer readable memory that can direct a computer or other programmable data processing device to operate in a particular manner, such that the instructions stored in the computer readable memory produce an article of manufacture comprising the instruction device.
- the apparatus implements the functions specified in one or more blocks of a flow or a flow and/or block diagram of the flowchart.
- These computer program instructions can also be loaded onto a computer or other programmable data processing device such that a series of operational steps are performed on a computer or other programmable device to produce computer-implemented processing for execution on a computer or other programmable device.
- the instructions provide steps for implementing the functions specified in one or more of the flow or in a block or blocks of a flow diagram.
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Abstract
Description
域(Field) | 描述(Description) |
CCO1信息 | CCO1的地址信息 |
信标时隙序号1 | 分配给CCO1的信标时隙序号 |
CCO2信息 | CCO2的地址信息 |
信标时隙序号2 | 分配给CCO2的信标时隙序号 |
生效时间 | 本次分配的信标时隙的生效时间 |
Claims (42)
- 一种信标发送方法,其特征在于,包括:协调器发送信标,所述信标占用当前超帧的第一信标时隙;所述协调器接收第一信标请求帧,所述第一信标请求帧用于指示设备处于所述协调器所在的第一网络的区域与至少一个第二网络的区域之间的干扰区域;所述协调器发送信标,并满足以下条件:在从下一个超帧开始的N个超帧中,分别占用所述N个超帧中的每一个超帧的第一信标时隙和第二信标时隙,N≥1,N为正整数。
- 如权利要求1所述的方法,其特征在于,所述第一信标时隙和所述第二信标时隙均位于超帧中的信标时隙区域,且所述第二信标时隙为空闲时隙,所述信标时隙区域为一个超帧中仅用于发送信标的时间段,所述空闲时隙为所述信标时隙区域中未用于其他任何一个互相干扰的VPAN中的协调器发送信标的时隙;或者,所述第一信标时隙位于超帧中的信标时隙区域,所述第二信标时隙位于超帧中的免竞争期CFP区域。
- 如权利要求1或2所述的方法,其特征在于,所述协调器在占用所述第一信标时隙发送的信标中携带的信标类型为原信标;所述协调器在占用所述第二信标时隙发送的信标中携带的信标类型为附加信标;其中,所述原信标用于指示该信标为协调器周期性常规发送的信标;所述附加信标用于指示该信标为协调器在原信标之外额外发送的信标。
- 如权利要求3所述的方法,其特征在于,所述协调器分别占用所述N个超帧中的每一个超帧的所述第一信标时隙和第二信标时隙发送信标之后,还包括:所述协调器若接收到所述设备发送的关联请求帧、且所述N个超帧占用 的时间未达到设定阈值,则与所述设备进行关联;或者,所述协调器若未接收到所述设备发送的关联请求帧、且所述N个超帧占用的时间达到所述设定阈值,则仅占用所述N个超帧之后的每一个超帧中的第一信标时隙发送信标。
- 如权利要求4所述的方法,其特征在于,所述关联请求帧中携带信标类型指示,所述信标类型指示用于表征所述设备通过检测到原信标而发起的关联请求,或者用于表征所述设备通过检测到附加信标而发起的关联请求;所述协调器接收到所述设备发送的关联请求帧后,根据所述关联请求帧中携带的信标类型指示,若确定所述设备通过检测到原信标而发起的关联请求,则不触发干扰协调;若确定所述设备通过检测到附加信标而发起的关联请求,则触发干扰协调。
- 如权利要求5所述的方法,其特征在于,所述协调器在触发所述干扰协调的过程中使用所述关联请求帧中携带的干扰参数。
- 如权利要求4-6任一项所述的方法,其特征在于,若所述第一信标时隙位于超帧中的信标时隙区域,所述第二信标时隙位于超帧中的CFP区域;则,所述协调器分别占用所述N个超帧中的每一个超帧的第一信标时隙和第二信标时隙发送信标之后,还包括:所述协调器若接收到所述设备发送的第二信标请求帧、且所述N个超帧占用的时间未达到所述设定阈值,则分别占用所述N个超帧之后的每一个超帧中的第一信标时隙和第三信标时隙发送信标,所述第三信标时隙位于所述CFP区域。
- 如权利要求1-7任一项所述的方法,其特征在于,所述第一信标请求帧中携带表征所述设备的地址的字段;所述第二信标请求帧的格式与所述第一信标请求帧的格式相同。
- 如权利要求8所述的方法,其特征在于,所述第一信标请求帧还携带表征请求原因的字段、表征发送信标请求帧序号的字段、表征重发信标请求 帧次数的字段、表征目标接入协调器地址的字段中的至少一种。
- 一种网络接入方法,其特征在于,包括:设备在接入第一网络之前,进行信标检测;所述设备在检测的时间达到设定的第一时长阈值时,无法正确检测到信标,则发送第一信标请求帧,所述第一信标请求帧用于指示所述设备处于被干扰状态。
- 如权利要求10所述的方法,其特征在于,还包括:所述设备继续进行信标检测;若在继续检测的时间未达到设定的第二时长阈值时,正确检测到信标,并确定检测到的信标为所述第一网络中的协调器发送的,则向所述第一网络中的协调器发送关联请求帧,所述关联请求帧用于向所述第一网络中的协调器请求关联;若在继续检测的时间达到设定的所述第二时长阈值时,仍未正确检测到信标,则向所述第一网络中的协调器发送第二信标请求帧,所述第二信标请求帧用于指示所述设备依旧处于被干扰状态。
- 如权利要求11所述的方法,其特征在于,所述设备在正确检测到信标之后,还包括:所述设备对检测到信标进行解析,确定信标中包含的信标类型;所述信标类型为原信标或附加信标;所述原信标用于指示该信标为协调器周期性常规发送的信标;所述附加信标用于指示该信标为协调器在原信标之外额外发送的信标。
- 如权利要求12所述的方法,其特征在于,所述设备在确定信标中包含的信标类型后,还包括:所述设备若确定信标中包含的信标类型为原信标,则向所述第一网络中的协调器发送的关联请求帧中携带用于表征所述设备通过检测到原信标而发起的关联请求的信标类型指示;所述设备若确定信标中包含的信标类型为附加信标,则向所述第一网络 中的协调器发送的关联请求帧中携带用于表征所述设备通过检测到附加信标而发起的关联请求的信标类型指示。
- 如权利要求13所述的方法,其特征在于,所述设备在进行所述信标检测的过程中,还进行干扰参数检测;所述设备若确定信标中包含的信标类型为附加信标,则向所述第一网络中的协调器发送的关联请求帧中还携带检测到的干扰参数。
- 如权利要求11-14任一项所述的方法,其特征在于,所述第一信标请求帧携带表征所述设备地址的字段;所述第二信标请求帧的格式与所述第一信标请求帧的格式相同。
- 如权利要求15所述的方法,其特征在于,所述第一信标请求帧还携带表征请求原因的字段、表征发送信标请求帧序号的字段、表征重发信标请求帧次数的字段、表征目标接入协调器地址的字段中的至少一种。
- 一种网络接入方法,其特征在于,包括:设备在接入第一网络之前,进行网络检测,所述网络检测包括信标检测、干扰参数检测;所述设备在检测的时间达到设定的第一时长阈值时,无法正确检测到信标,则向所述第一网络中的协调器发送干扰指示帧,所述干扰指示帧中携带检测到的所述第一网络与至少一个第二网络的干扰参数。
- 如权利要求17所述的方法,其特征在于,所述干扰参数包括所述第一网络和所述第二网络的标识信息、所述设备接收所述第一网络信号和所述至少一个第二网络信号的质量。
- 一种网络接入方法,其特征在于,包括:第一网络中的协调器接收设备发送的干扰指示帧,所述干扰指示帧中携带干扰参数,所述干扰参数表示至少一个第二网络干扰所述第一网络的干扰信息;所述协调器根据所述干扰指示帧,触发干扰协调。
- 如权利要求19所述的方法,其特征在于,所述干扰参数包括所述第 一网络的标识信息和至少一个所述第二网络的标识信息、和/或所述设备接收所述第一网络信号和所述至少一个第二网络信号的质量的信息。
- 如权利要求19或20所述的方法,其特征在于,所述协调器触发干扰协调,包括:所述协调器向管理所述协调器的全局协调器发送干扰协调请求消息,所述干扰协调请求消息中包含所述干扰参数;所述协调器接收所述全局协调器返回的干扰协调响应消息,所述干扰协调响应消息中包含所述协调器用于发送信标的信标时隙;所述协调器根据所述干扰协调响应消息,占用所述全局协调器指示的信标时隙发送信标。
- 一种信标发送装置,其特征在于,包括:发送单元,用于发送信标,所述信标占用当前超帧的第一信标时隙;接收单元,用于在所述发送单元发送所述信标后,接收第一信标请求帧,所述第一信标请求帧用于指示设备处于所述协调器所在的第一网络的区域与至少一个第二网络的区域之间的干扰区域;所述发送单元,用于在所述接收单元接收到所述第一信标请求帧后,从下一个超帧开始的N个超帧中,分别占用所述N个超帧中的每一个超帧的第一信标时隙和第二信标时隙发送信标,N≥1,N为正整数。
- 如权利要求22所述的装置,其特征在于,所述第一信标时隙和所述第二信标时隙均位于超帧中的信标时隙区域,且所述第二信标时隙为空闲时隙,所述信标时隙区域为一个超帧中仅用于发送信标的时间段,所述空闲时隙为所述信标时隙区域中未用于其他任何一个互相干扰的VPAN中的协调器发送信标的时隙;或者,所述第一信标时隙位于超帧中的信标时隙区域,所述第二信标时隙位于超帧中的免竞争期CFP区域。
- 如权利要求22或23所述的装置,其特征在于,所述发送单元用于:在占用所述第一信标时隙发送的信标中携带的信标类型为原信标;在占用所述第二信标时隙发送的信标中携带的信标类型为附加信标;其中,所述原信标用于指示该信标为所述发送单元周期性常规发送的信标;所述附加信标用于指示该信标为所述发送单元在原信标之外额外发送的信标。
- 如权利要求24所述的装置,其特征在于,还包括关联单元,所述关联单元用于,在所述接收单元接收到所述设备发送的关联请求帧时,确定所述N个超帧占用的时间未达到设定阈值,则与所述设备进行关联;所述发送单元还用于,若所述接收单元未接收到所述设备发送的关联请求帧、且确定所述N个超帧占用的时间达到所述设定阈值,则仅占用所述N个超帧之后的每一个超帧中的第一信标时隙发送信标。
- 如权利要求25所述的装置,其特征在于,所述关联请求帧中携带信标类型指示,所述信标类型指示用于表征所述设备通过检测到原信标而发起的关联请求,或者用于表征所述设备通过检测到附加信标而发起的关联请求;所述协调器还包括协调单元,用于在所述接收单元接收到所述设备发送的关联请求帧后,根据所述接收单元接收到的所述关联请求帧中携带的信标类型指示,若确定所述设备通过检测到原信标而发起的关联请求,则不触发干扰协调;若确定所述设备通过检测到附加信标而发起的关联请求,则触发干扰协调。
- 如权利要求26所述的装置,其特征在于,所述协调单元还用于,在触发所述干扰协调的过程中使用所述接收单元接收到的所述关联请求帧中携带的干扰参数。
- 如权利要求25-27任一项所述的装置,其特征在于,若所述第一信标时隙位于超帧中的信标时隙区域,所述第二信标时隙位于超帧中的CFP区域;则,所述发送单元还用于,在所述接收单元接收到所述设备发送的第二信标请求帧时,确定所述N个超帧占用的时间未达到所述设定阈值,则分别占用所述N个超帧之后的每一个超帧中的第一信标时隙和第三信标时隙发送信 标,所述第三信标时隙位于所述CFP区域。
- 如权利要求22-28任一项所述的装置,其特征在于,所述第一信标请求帧中携带表征所述设备的地址的字段;所述第二信标请求帧的格式与所述第一信标请求帧的格式相同。
- 如权利要求29所述的装置,其特征在于,所述第一信标请求帧还携带表征请求原因的字段、表征发送信标请求帧序号的字段、表征重发信标请求帧次数的字段、表征目标接入协调器地址的字段中的至少一种。
- 一种网络接入装置,其特征在于,包括:检测单元,用于在接入第一网络之前,进行信标检测;发送单元,在所述检测单元检测的时间达到设定的第一时长阈值,无法正确检测到信标时,发送第一信标请求帧,所述第一信标请求帧用于指示所述设备处于被干扰状态。
- 如权利要求31所述的装置,其特征在于,所述检测单元还用于,在所述发送单元向所述第一网络中的协调器发送所述第一信标请求帧之后,继续进行信标检测;以及,若在继续检测的时间未达到设定的第二时长阈值时,正确检测到信标,进一步确定检测到的信标是否为所述第一网络中的协调器发送的;所述发送单元还用于,若所述检测单元确定检测到的信标为所述第一网络中的协调器发送的,则向所述第一网络中的协调器发送关联请求帧,所述关联请求帧用于向所述第一网络中的协调器请求关联;若所述检测单元在继续检测的时间达到设定的所述第二时长阈值时,仍未正确检测到信标,则向所述第一网络中的协调器发送第二信标请求帧,所述第二信标请求帧用于指示所述设备依旧处于被干扰状态。
- 如权利要求32所述的装置,其特征在于,所述检测单元还用于,在正确检测到信标之后,对检测到信标进行解析,确定信标中包含的信标类型;所述信标类型为原信标或附加信标;所述原信标用于指示该信标为协调器周期性常规发送的信标;所述附加 信标用于指示该信标为协调器在原信标之外额外发送的信标。
- 如权利要求33所述的装置,其特征在于,所述发送单元还用于,在所述检测单元确定信标中包含的信标类型为原信标时,向所述第一网络中的协调器发送的关联请求帧中携带用于表征所述设备通过检测到原信标而发起的关联请求的信标类型指示;在所述检测单元确定信标中包含的信标类型为附加信标时,向所述第一网络中的协调器发送的关联请求帧中携带用于表征所述设备通过检测到附加信标而发起的关联请求的信标类型指示。
- 如权利要求34所述的装置,其特征在于,所述检测单元还用于,在进行所述信标检测的过程中,还进行干扰参数检测;所述发送单元还用于,在所述检测单元确定信标中包含的信标类型为附加信标时,向所述第一网络中的协调器发送的关联请求帧中还携带所述检测单元检测到的干扰参数。
- 如权利要求32-35任一项所述的装置,其特征在于,所述第一信标请求帧携带表征所述设备地址的字段;所述第二信标请求帧的格式与所述第一信标请求帧的格式相同。
- 如权利要求36所述的装置,其特征在于,所述第一信标请求帧还携带表征请求原因的字段、表征发送信标请求帧序号的字段、表征重发信标请求帧次数的字段、表征目标接入协调器地址的字段中的至少一种。
- 一种网络接入装置,其特征在于,包括:检测单元,用于在接入第一网络之前,进行网络检测,所述网络检测包括信标检测、干扰参数检测;发送单元,用于在所述检测单元检测的时间达到设定的第一时长阈值仍无法正确检测到信标时,向所述第一网络中的协调器发送干扰指示帧,所述干扰指示帧中携带检测到的所述第一网络与至少一个第二网络的干扰参数。
- 如权利要求38所述的装置,其特征在于,所述干扰参数包括所述第一网络和所述第二网络的标识信息、所述设备接收所述第一网络信号和所述 至少一个第二网络信号的质量。
- 一种网络接入装置,其特征在于,所述装置位于第一网络中,所述装置包括:接收单元,用于接收设备发送的干扰指示帧,所述干扰指示帧中携带干扰参数,所述干扰参数表示至少一个第二网络干扰所述第一网络的干扰信息;协调单元,用于根据所述干扰指示帧,触发干扰协调。
- 如权利要求40所述的装置,其特征在于,所述干扰参数包括所述第一网络的标识信息和所述至少一个第二网络的标识信息、和/或所述设备接收所述第一网络信号和所述至少一个第二网络信号的质量的信息。
- 如权利要求39或40所述的装置,其特征在于,还包括发送单元,所述发送单元用于,在所述协调单元触发干扰协调时,向管理所述装置的全局协调器发送干扰协调请求消息,所述干扰协调请求消息中包含所述干扰参数;所述接收单元还用于,接收所述全局协调器返回的干扰协调响应消息,所述干扰协调响应消息中包含所述协调器用于发送信标的信标时隙;所述发送单元还用于,根据所述接收单元接收到的所述干扰协调响应消息,占用所述全局协调器指示的信标时隙发送信标。
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WO2019179761A1 (en) * | 2018-03-19 | 2019-09-26 | Signify Holding B.V. | Interference handling for wireless networks with multiple coordinators |
WO2020053235A1 (en) * | 2018-09-10 | 2020-03-19 | Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V. | Communication techniques |
WO2020104288A1 (en) * | 2018-11-23 | 2020-05-28 | Signify Holding B.V. | Interference-free scheduling for wireless optical networks with multiple coordinators |
WO2020104274A1 (en) | 2018-11-23 | 2020-05-28 | Signify Holding B.V. | Interference handling by automatic time slot allocation for multiple coordinators |
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US11038661B1 (en) * | 2019-12-11 | 2021-06-15 | Wipro Limited | System and method for managing interference in Li-Fi communication networks |
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Also Published As
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JP6671501B2 (ja) | 2020-03-25 |
KR102259678B1 (ko) | 2021-06-01 |
US20190020414A1 (en) | 2019-01-17 |
CN108886735A (zh) | 2018-11-23 |
EP3422772A1 (en) | 2019-01-02 |
KR20180124073A (ko) | 2018-11-20 |
EP3422772A4 (en) | 2019-01-02 |
JP2019508983A (ja) | 2019-03-28 |
EP3422772B1 (en) | 2020-07-29 |
CN108886735B (zh) | 2021-02-05 |
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