WO2012130027A1 - 用于接入无线网络的方法及装置 - Google Patents
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- WO2012130027A1 WO2012130027A1 PCT/CN2012/072054 CN2012072054W WO2012130027A1 WO 2012130027 A1 WO2012130027 A1 WO 2012130027A1 CN 2012072054 W CN2012072054 W CN 2012072054W WO 2012130027 A1 WO2012130027 A1 WO 2012130027A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/0091—Signaling for the administration of the divided path
- H04L5/0094—Indication of how sub-channels of the path are allocated
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W48/00—Access restriction; Network selection; Access point selection
- H04W48/08—Access restriction or access information delivery, e.g. discovery data delivery
- H04W48/12—Access restriction or access information delivery, e.g. discovery data delivery using downlink control channel
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W56/00—Synchronisation arrangements
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W74/00—Wireless channel access
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- H04—ELECTRIC COMMUNICATION TECHNIQUE
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- H04W74/08—Non-scheduled access, e.g. ALOHA
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- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W28/00—Network traffic management; Network resource management
- H04W28/16—Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]
- H04W28/18—Negotiating wireless communication parameters
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
Definitions
- the present invention belongs to the field of wireless communications, and in particular, to a method and apparatus for accessing a wireless network. Background technique
- wireless communication systems have developed rapidly, such as 802.11-based wireless LAN technology WiFi, 802.15-based Bluetooth systems, and Femto technology for indoor applications generated by mobile communication systems. A wide range of applications.
- 802.11-based WiFi technology is one of the most widely used wireless network transmission technologies. Since the WiFi system uses the Carrier Sense Multiple Access with Collision Avoidance (CSMA/CA) mechanism, the system efficiency is higher than that of the wireless system. The root cause of this problem is that the CSMA/CA mechanism is a contention-based random multiple access mechanism, between a central access point (CAP, Access Point) and a station (STA, Station), or between different STAs. The CSMA/CA mechanism will compete for the right to use radio resources, and at the same time compete for the wireless channel. At this time, collision will occur, resulting in waste of radio resources.
- CAP central access point
- STA Station
- the CSMA/CA mechanism requires CAPs or STAs to need random backoff when competing for wireless channels, in all CAPs and STAs.
- the wireless channel is idle, but it is not used, which is also a great waste of the wireless channel.
- 802.11 systems are less efficient. For example: 802. l lg system physical layer peak rate of up to 54Mbps, but the TCP layer can not reach higher than 30Mbps under the big packet download service.
- the 802.11 system is flexible and does not rely on a centralized control mechanism, so it can also achieve lower equipment costs.
- the Femto technology based on the 3GPP standard is a new technology for indoor coverage that has evolved from a mobile communication system. Based on the statistics of 3G systems, about 70% of data services occur indoors, so indoor high-rate data access solutions are especially important.
- Femto base stations called pico base stations, are compact (similar to Wi-Fi) and flexible to deploy. Due to the evolution from mobile communication systems, Femto base stations have inherited almost all the characteristics of mobile communication systems. The Femto device only combines its limited coverage and fewer access user features, which reduces the processing power of the device and reduces the cost of the device.
- the duplex mode like the mobile communication system, the Femto base station can be divided into two types of duplex mechanisms: FDD and TDD.
- the uplink and downlink carrier resources of the FDD are symmetric, and the asymmetric service characteristics of the data traffic on the uplink and the downlink make the FDD system have a certain resource waste when facing the data service.
- the uplink and downlink of the TDD system work on the same carrier, and allocates different radio resources to the uplink and the downlink by dividing the time resources. Therefore, the FDD can better adapt to the asymmetric data service of the uplink and downlink services.
- the TDD duplex mode of the mobile communication system including the Femto system
- the static allocation of uplink and downlink resources, and the various types of data services with different needs, such as: browsing web pages, mobile video, mobile games, etc. it is difficult to achieve business needs and resources. Dynamic adaptation of the partition. Compared with Wi-Fi, since Femto uses a scheduling-based centralized control mechanism, there is no waste of radio resources between the base station or the CAP and the terminal or the terminal due to competition conflict and random backoff, so the link efficiency is high.
- Another object of the present invention is to provide an apparatus for accessing a wireless network.
- a method for accessing a wireless network comprising: acquiring a synchronization process, where the process of acquiring synchronization includes:
- the process of acquiring synchronization further includes: after acquiring the system parameter, transferring to the next subchannel to continue performing the step of searching for a physical frame until traversing each subchannel in the channel list.
- the method further includes: selecting all subchannels of the acquired system parameters as available subchannels, and selecting any one of the subchannels.
- the method further includes a process of maintaining synchronization, where the maintaining the synchronization process includes: continuing to search for a physical frame on the selected subchannel;
- the BCF is detected from the found physical frame by using the parsing result to obtain system parameters.
- the process of maintaining synchronization further includes:
- the process of maintaining synchronization further includes:
- the process of maintaining synchronization further includes:
- the start time of the next physical frame is determined by using the SICH in the current physical frame that is found.
- a physical frame is searched by detecting a frame header of a physical frame.
- the detecting is continued on the current subchannel until the waiting time of the subchannel is exceeded, and the process proceeds to the next subchannel to continue to perform the step H of searching for the physical frame.
- the step of performing the searching for a physical frame is continued on the current subchannel, until the waiting time of the subchannel is exceeded, and the process proceeds to The next subchannel continues the step of finding the physical frame.
- the acquiring system parameters includes: detecting, by using the parsing result, a broadcast information frame BCF from the physical frame;
- the step of performing the searching for a physical frame is continued on the current subchannel, and when the waiting time of the subchannel is exceeded, the process proceeds to the next subchannel to continue to perform the foregoing.
- the step of finding a physical frame is not detected in the physical frame.
- An apparatus for accessing a wireless network includes a module for acquiring synchronization, and the module for acquiring synchronization includes:
- a first detecting unit configured to search for a physical frame on the current subchannel
- a first parsing unit configured to parse a SICH and a CCH in a physical frame that is searched by the first detecting unit, where the SICH indicates a structure of a physical frame, where the CCH indicates allocation of system resources;
- a first acquiring unit configured to obtain a system parameter from a physical frame found by the first detecting unit by using a result of the parsing by the first parsing unit.
- the first acquiring unit triggers the first detecting unit to transfer to the next subchannel to continue searching for physical frames until each subchannel in the predetermined channel list is traversed.
- the first acquiring unit further uses all subchannels that have acquired system parameters as available subchannels, and selects any one of the subchannels.
- the device further includes: a module for maintaining synchronization, where the module for maintaining synchronization includes: a second detecting unit, configured to continue to search for a physical frame on the selected subchannel;
- a second parsing unit configured to parse the SICH and the CCH in a physical frame that is searched by the second detecting unit
- a second acquiring unit configured to detect, by using an analysis result of the second parsing unit, a BCF from a physical frame that is searched by the second detecting unit, to obtain an ear system parameter.
- the module for maintaining synchronization further includes: a SICH timer, a BCF timer, and a determining unit;
- the second detecting unit further starts the SICH timer and the BCF timer when starting to search for a physical frame
- the determining unit is configured to determine whether the second parsing unit successfully parses the SICH before the SICH timer expires, and if yes, reset the SICH timer, otherwise trigger the acquiring synchronization module to select
- the subchannel is the starting point, and the operation is re-executed according to the channel list; Determining whether the second acquiring unit detects the BCF before the BCF timer expires, and if so, resetting the BCF timer, and triggering the second detecting unit to continue searching for a physical frame on the selected subchannel
- the module that triggers the acquisition synchronization starts with the selected subchannel as a starting point, and performs operations again according to the channel list;
- the first obtaining unit further triggers the module that maintains synchronization to perform the operation again by using the subchannel as the selected subchannel after acquiring the system parameter on one subchannel in the process of re-executing the operation.
- the module for maintaining synchronization further includes: a SICH timer, a BCF timer, and a determining unit;
- the second detecting unit further starts the SICH timer and the BCF timer when starting to search for a physical frame
- the determining unit is configured to determine whether the second parsing unit successfully parses the SICH before the SICH timer expires, and if yes, reset the SICH timer, otherwise the module that triggers the acquiring synchronization according to the channel Re-execution operation; determining whether the second obtaining unit detects the BCF before the BCF timer expires, and if yes, resetting the BCF timer, and triggering the second detecting unit to select the subchannel
- the physical frame continues to be searched for, otherwise the module that triggers the acquisition synchronization re-executes the operation according to the channel list.
- the module for maintaining synchronization further includes: a SICH timer, a BCF timer, and a determining unit;
- the second detecting unit further starts the SICH timer and the BCF timer when starting to search for a physical frame
- the determining unit is configured to determine whether the second parsing unit successfully parses the SICH before the SICH timer expires, and if yes, reset the SICH timer, otherwise triggering the first acquiring unit to be available again Determining one of the subchannels; determining whether the second obtaining unit detects the BCF before the BCF timer expires, and if so, resetting the BCF timer, and triggering the selected unit by the second detecting unit
- the physical frame continues to be searched on the channel, otherwise the first acquiring unit is triggered to reselect one of the available subchannels.
- the second detecting unit determines, by using the SICH in the current physical frame that is found on the selected subchannel, a start time of the next physical frame.
- the first detecting unit searches for a physical frame by detecting a frame header of the physical frame.
- the detecting unit when the first detecting unit does not detect the frame header on the current subchannel, the detecting unit continues to perform detection on the current subchannel until the waiting time of the subchannel is exceeded, and then transfers to the next subchannel to continue searching for the physical frame. .
- the first parsing unit parses the SICH and the CCH is unsuccessful, triggering the first detecting unit to continue to search for a physical frame on the current subchannel until the waiting time of the subchannel is exceeded, triggering the A detection unit moves to the next subchannel to continue looking for physical frames.
- the first acquiring unit detects a broadcast information frame BCF from the physical frame, and acquires a system parameter from the BCF.
- the first detecting unit when the first acquiring unit does not detect the BCF, the first detecting unit is triggered to continue to search for a physical frame on the current subchannel, and when the waiting time of the subchannel is exceeded, the first detecting unit is triggered to be transferred. Continue to find physical frames to the next subchannel.
- the acquisition system synchronization is implemented for the dynamic configuration of the physical frame structure.
- FIG. 1 is a flow chart of a method for accessing a wireless network in the present invention
- FIG. 3 is a reference model of an enhanced ultra high speed wireless local area network (EUHT) system
- Figure 4 shows the composition of the access system of the EUHT system
- FIG. 5 is a process of transmitting and receiving protocol data between a STA and a CAP in an EUHT system
- FIG. 6 is a flowchart of a method for accessing a wireless network in an embodiment of the present invention
- Figure 7 is a flow chart of the STA maintaining downlink synchronization
- FIG. 8 is a schematic structural diagram of a terminal side device accessing a wireless network in the present invention.
- FIG. 9 is a schematic structural diagram of an apparatus for acquiring system synchronization according to an embodiment of the present invention
- FIG. 10 is another schematic structural diagram of an apparatus for acquiring system synchronization according to an embodiment of the present invention.
- FIG. 1 is a flowchart of a method for accessing a wireless network in the present invention, where the process includes:
- Step 11 Get system synchronization.
- Step 12 Randomly access the CAP and perform capability negotiation with the CAP.
- the method for accessing a wireless network in the present invention refers to a process of acquiring system synchronization in the flow shown in FIG. 1.
- the method includes the process of acquiring synchronization, and the process of acquiring synchronization includes:
- Step 21 Find a physical frame on the current subchannel.
- Step 22 Parse the system information channel (SICH) and the control channel (CCH) in the found physical frame, where the SICH indicates the structure of the physical frame, and the CCH indicates the system resource.
- SICH system information channel
- CCH control channel
- the method for accessing a wireless network in the present invention is directed to the case where the physical frame structure can be dynamically configured.
- the SICH in the physical frame indicates the structural configuration of the physical frame, for example, indicating whether the channel in the physical frame is timely or not.
- the CCH in the physical frame indicates the allocation of system resources, including an indication of the resources allocated for the system parameters.
- Step 23 Using the parsing result, obtain system parameters from the physical frame.
- the acquisition system synchronization is implemented for the dynamic configuration of the physical frame structure.
- the application scenario is only a specific example, and does not limit the scope of protection of the present invention.
- Figure 3 shows the reference model for the EUHT system.
- the system reference model shown in Figure 3 mainly refers to the air interface reference model, including: Media Access Control (MAC) layer and physical (PHY) layer.
- MAC Media Access Control
- PHY physical
- the MAC layer includes an adaptation sublayer and a MAC sublayer.
- MSDU refers to information delivered as a unit between MAC Service Access Points (SAP).
- SAP MAC Service Access Points
- MAC sublayer In addition to acting as a media access control function, it also includes management and control of the system and support for specific functions of the PHY layer.
- PHY layer mainly provides PHY transmission mechanism for mapping MPDUs to corresponding physical channels, such as Orthogonal Frequency Division Multiplexing (OFDM) and Multiple Input Multiple Output (MIMO) technologies.
- MPDU refers to the data unit exchanged between two peer MAC entities using the PHY layer service.
- FIG. 4 shows the access system of the EUHT system, including the central access point (CAP) and the station (STA), where the STA can be various data devices, such as: PDA, notebook, camera, camera, mobile phone, tablet and pad. Wait.
- STA1 and STA2 access the CAP through an air interface protocol, and the CAP establishes communication with an existing external network (such as IP backbone network, Ethernet) through wired or wireless.
- the protocol composition of the CAP includes a MAC layer and a PHY layer.
- the STA protocol consists of an Application layer, a Transmission Control (TCP) layer, a Network (IP) layer, a MAC layer, and a PHY layer. Based on the protocol composition shown in FIG. 4, FIG.
- the STA wants to send data to the CAP, and the STA first applies the application data (such as VoIP, video, etc.).
- the application layer and the TCP/IP layer process and package, and send it to the IP adaptation sublayer in the form of IP packets, which are converted and mapped by the IP adaptation sublayer, and sent to the MAC sublayer.
- the MAC sublayer is fragmented, encrypted, and Operations such as framing, aggregation, etc. are sent to the PHY layer, which is ultimately mapped by the PHY to the wireless channel for data transmission.
- both STA and CAP can support 20MHz, 40MHz and 80MHz.
- the system pre-determines the channel list to indicate the sub-channels of the system. These sub-channels can contain one or more working sub-channels of CAP.
- Table 1 An example of a list of predetermined channels in the 2.4 GHz band is given in Table 1 below. Table 1
- FIG. 6 is a flowchart of a method for accessing a wireless network according to an embodiment of the present invention, where the method includes the process of acquiring synchronization, where the process of acquiring synchronization includes:
- Step 61 Find a physical frame on the current subchannel, specifically, determine whether a frame header of the physical frame is detected on the current subchannel, and if yes, perform step 62, otherwise continue to perform detection until the waiting time of the subchannel is exceeded. , move to the next subchannel and proceed to step 61.
- Step 62 Determine whether the SICH and CCH in the physical frame can be parsed. If yes, go to step 63. Otherwise, go to step 61. When the waiting time of the subchannel is exceeded, go to the next subchannel and continue to step 61.
- the positions of the preamble sequence and the SICH are preset in advance, and dynamic configuration is not performed.
- the CCH is located adjacent to the SICH, and the duration of the CCH can be dynamically configured.
- the SICH indicates the structural configuration of the physical frame, and specifically indicates the presence and/or duration of each channel in the current physical frame. For example, for some channels with fixed duration, the SICH can use 1 bit to indicate the presence or absence of the channel, which implicitly indicates the duration of the channel. For some channels with irregular duration, multiple bits can be used in the SICH to indicate CCH. For example, 6 bits can be used in the SICH, and a maximum of 63 OFDM symbols can be indicated. One OFDM symbol is a minimum resource allocation unit, for example, the 6 bits are 010000, and the converted decimal number is 16, that is, corresponding to 16 OFDM symbols.
- the broadcast scheduling signaling is detected from the CCH in the physical frame to detect the resource allocated for the broadcast information frame (BCF).
- BCF broadcast information frame
- Table 2 An example of broadcast scheduling signaling is shown in Table 2 below.
- the BCF is transmitted in the signaling/feedback channel shown in Table 2, and the signaling/feedback channel is included in the transport channel.
- bb i is taken as 0000, it is determined as a downlink signaling/feedback channel resource indication. If 0 is taken, it is determined that there is a BCF frame, 3 ⁇ 436 H indicates the location of the resource, and 3 ⁇ 439 37 indicates the length of the resource.
- Step 63 Determine whether the BCF is detected. If yes, implement downlink synchronization. Otherwise, go back to step 61 and wait until the waiting time of the subchannel is exceeded. Then, go to the next subchannel and continue to step 61.
- the BCF is a broadcast configuration message, and is periodically broadcast by the CAP on all working subchannels, which carries the MAC address of the CAP, so that the STA identifies the sender of the BCF.
- the system parameters are also carried in the BCF.
- the system parameters carried by the BCF may include various parameters that indicate the subsequent processes of the network access or other processes after the network is completed.
- BCF frame body carrying information is given in Table 3 below.
- Scheduling request backoff 8 Maximum window system for the backoff window of the resource request based on the contention, the maximum window value range is 0 ⁇ 2n-l
- the CAP transmit power is n dBm.
- the channel is divided into two parts, and the latter part has n OFDM symbols.
- the guard interval is 2 OFDM symbol periods
- guard interval is 4 OFDM symbol periods; 2 ⁇ 3: reserved
- the guard interval is 2 OFDM symbol periods
- guard interval is 4 OFDM symbol periods (processing delay);
- the STA can identify the CAP that sent the BCF according to the MAC address. 2) The working channel number and working bandwidth of the CAP. In combination with the working channel number and working bandwidth, the STA can determine other working subchannels of the CAP that broadcast the BCF in addition to the subchannel currently detecting the BCF.
- Network alias indicating the network name, so that the STA can select the network to join.
- the length of the network alias indicating the length of the network alias field.
- the fixed length of the network alias field can save overhead and reduce the resolution bias.
- 6) Indicates the timestamp of the system's common clock, and the STA can adjust its own clock according to the timestamp.
- the STA Indicates the BCF interval of the BCF broadcast period. After the STA obtains the system parameters for the first time, the STA needs to continuously receive the SICH and the BCF to confirm that it is always in contact with the CAP. According to the BCF interval, the STA can obtain the BCF periodically.
- Collision avoidance parameters including: a minimum window for random access backoff and a maximum window for random access backoff, and a minimum window for scheduling request backoff and a maximum window for scheduling request backoff.
- the STA may perform backoff according to the minimum window of the random access evasion and the maximum window of the random access backoff when multiple STAs collide in the subsequent random access procedure.
- the STA can also back off the minimum window according to the scheduling request and the maximum window of the scheduling request backoff, and perform backoff when the scheduling request conflicts. The specific method of performing backoff is described in detail later.
- the transmit power of the CAP after successful access to the wireless network, the STA can perform open-loop power control according to the transmit power.
- a DGI for indicating the transition time of the downlink and the uplink
- a UGI for indicating the transition time of the uplink and the downlink
- a location of a downlink sounding channel for indicating a starting position of the downlink sounding channel in the downlink transport channel
- the physical frame structure parameter carried in the BCF frame indicates a part of the structure in the physical frame. This part of the structure generally does not change when the physical frame structure is dynamically configured. Therefore, it carries a unified indication in the BCF, so that there is no need to repeat the indication in the SICH. , saving the cost of SICH.
- An uplink random access channel (UL-RACH) format for indicating a random access format.
- U-RACH uplink random access channel
- different uplink random access channel formats are set for different random access distances to support coverage of further distances, and STA selection and random access are indicated by indicating an uplink random access channel format in the BCF. The distance matches the format.
- the CAP can carry one or several items of the information shown in Table 3 in the generated BCF, and then broadcast the generated BCF.
- the STA After the STA acquires the system parameters on a certain subchannel, it will transfer to the next subchannel to continue to perform step 61 until a scan is performed on all the subchannels in the channel list to complete the process of acquiring synchronization.
- the STA may acquire system parameters on one or more subchannels, which may be working subchannels of the same CAP, and may also include different The working subchannel of the CAP.
- the STA takes all the subchannels that have acquired the system parameters as available subchannels, and selects any one of them as a subchannel for performing the synchronization maintaining process, and also determines the CAP to be accessed.
- the method of the present invention further includes a process of maintaining synchronization, including: continuing to search for a physical frame on the selected subchannel; parsing the SICH and the CCH in the found physical frame; and detecting the BCF from the found physical frame by using the parsing result, To get system parameters.
- FIG. 7 is a flowchart of STA synchronization in an embodiment of the present invention.
- the SICH timer and the BCF timer are set, and the STA continues to search for a physical frame on the selected subchannel, and starts the SICH timer and the BCF timer. If the SICH is successfully parsed before the SICH timer expires, the SICH timer is reset. If the BCF is successfully detected before the BCF timer expires, the BCF timer is reset and the physical frame is continued to be searched on the selected subchannel. When any of the two timers expires but the corresponding information is not successfully detected, the STA is considered to be out of synchronization and the channel needs to be scanned again.
- the rescanning channel here specifically includes the following two implementations:
- the process of re-execution acquisition synchronization according to the channel list is equivalent to scanning each channel in the channel list, and then selecting an available sub-channel to perform the process of maintaining synchronization again.
- another available subchannel can be used as the selected subchannel, and the process of maintaining synchronization is performed again.
- This implementation can be applied to the following application scenarios: After the process of acquiring synchronization ends, it is determined that more than one subchannel is available, and the current channel list has not expired. Of course, if there is no limit on the expiration of the channel list in the system, this implementation can also be used as a predetermined operation mode. When more than one available subchannel is determined when the process of acquiring synchronization is performed for the first time, the operation can be used. mode.
- the timing of the SICH timer and the BCF timer can be flexibly set according to the application requirements. It can be seen that maintaining synchronization is a process in which the STA continuously searches for a physical frame on the selected subchannel, and continuously analyzes the SICH and detects the BCF. Since the SICH indicates the structure of the physical frame to which the subframe belongs, the STA can learn the start time of the next physical frame by using the parsing result of the current SICH while maintaining synchronization.
- FIG. 8 is a schematic structural diagram of a terminal-side device accessing a wireless network according to the present invention.
- the device includes: a device 81 for acquiring system synchronization, a random access terminal-side device 82, and a capability negotiation terminal-side device 83.
- the device 81 for acquiring system synchronization is used to perform a process of acquiring the system synchronization with the CAP.
- the random access terminal side device 82 is configured to randomly access the CAP.
- the capability negotiation terminal side device 83 is configured to perform capability negotiation with the CAP.
- the apparatus for accessing a wireless network in the present invention refers to the apparatus 81 for acquiring the synchronization of the above system.
- the device for acquiring system synchronization in the present invention includes: a module for acquiring synchronization, and the module for acquiring synchronization includes: a first detecting unit, a first analyzing unit, and a first acquiring unit.
- the first detecting unit is configured to search for a physical frame on the current subchannel.
- the first parsing unit is configured to parse the physical frame that is found by the first detecting unit
- SICH indicates a structure of a physical frame
- CCH indicates allocation of system resources
- the first acquiring unit is configured to obtain a system parameter from a physical frame that is searched by the first detecting unit by using a result of the parsing by the first parsing unit.
- FIG. 9 is a schematic structural diagram of an apparatus for acquiring system synchronization according to an embodiment of the present invention.
- the apparatus includes: a module 91 for acquiring synchronization, and the module 91 for acquiring synchronization includes: a first detecting unit 911, a first parsing unit 912, and a first The obtaining unit 913.
- the first detecting unit 911 is configured to search for a physical frame on the current subchannel.
- a first parsing unit 912 configured to parse the physical frame that is found by the first detecting unit 911
- SICH indicates a structure of a physical frame
- CCH indicates allocation of system resources
- the first obtaining unit 913 is configured to obtain the system parameters from the physical frame found by the first detecting unit 911 by using the result of the parsing by the first parsing unit 912.
- the first acquiring unit 913 may trigger the first detecting unit 911 to transfer to the next subchannel to continue searching for physical frames until each subchannel in the predetermined channel list is traversed.
- the first obtaining unit 913 may use all subchannels of the acquired system parameters as available subchannels, and select any one of the subchannels therefrom.
- the first detecting unit 911 finds a physical frame by detecting the frame header of the physical frame on the current subchannel.
- the first detecting unit 911 when the first detecting unit 911 does not detect the frame header on the current subchannel, it continues to perform detection until the waiting time of the subchannel is exceeded, and shifts to the next subchannel to continue searching for the physical frame.
- the first detecting unit 911 when the first parsing unit 912 parses the SICH and the CCH is unsuccessful, the first detecting unit 911 is triggered to continue to perform the operation, and when the waiting time of the subchannel is exceeded, the first detecting unit 911 is triggered to move to the next. A subchannel continues to look for physical frames.
- the first obtaining unit 913 detects the broadcast information frame BCF from the physical frame, and acquires system parameters from the BCF.
- the device for obtaining synchronization of the system in the embodiment of the present invention further includes a module 92 for maintaining synchronization, and the module 92 for maintaining synchronization includes: a second detecting unit 921, a second analyzing unit 922, and a second obtaining unit 923.
- the second detecting unit 921 is configured to continue searching for a physical frame on the selected subchannel.
- the second parsing unit 922 is configured to parse the SICH and the CCH in the physical frame sought by the second detecting unit 921.
- the second obtaining unit 923 is configured to detect the BCF from the physical frame sought by the second detecting unit 921 by using the parsing result of the second parsing unit 922 to obtain the system parameter.
- the module 92 that maintains synchronization further includes: a SICH timer 924, a BCF timer 925, and a decision unit 926.
- the second detecting unit 921 further starts the SICH timer 924 and the BCF timer 925 when starting to search for a physical frame.
- the determining unit 926 is configured to determine whether the second parsing unit 922 successfully parses the SICH before the SICH timer 924 times out, and if so, resets the SICH timer 924, otherwise the module 91 that triggers the acquisition synchronization re-executes the operation according to the channel list; Determining whether the second obtaining unit 923 detects the BCF before the BCF timer 925 times out, and if so, resetting the BCF timer 925, and triggering the second detecting unit 921 to continue searching for the physical frame on the selected subchannel, otherwise triggering acquisition The synchronized module 91 re-executes the operation in accordance with the channel list.
- the module 91 for maintaining synchronization further includes: a SICH timer 924, a BCF timer 925, and a judging unit 926.
- the second detecting unit 921 further starts the SICH timer 924 and the BCF timer 925 when starting to search for a physical frame.
- the determining unit 926 is configured to determine whether the second parsing unit 922 successfully parses the SICH before the SICH timer 924 times out. If yes, reset the SICH timer 924, otherwise the module 91 that triggers the acquisition synchronization starts with the selected subchannel. And re-executing the operation according to the channel list; determining whether the second obtaining unit 923 detects the BCF before the BCF timer 925 times out, and if so, resetting the BCF timer 925, and triggering the second detecting unit 921 to select the child.
- the physical frame continues to be searched on the channel, otherwise the module 91 that triggers the acquisition synchronization starts with the selected subchannel and re-executes the operation according to the channel list.
- the first obtaining unit 913 further, after acquiring the system parameters on one subchannel in the process of re-executing the operation, directly triggering the module 92 that maintains synchronization to perform the operation again by using the subchannel as the selected subchannel. .
- the module 92 for maintaining synchronization further includes: a SICH timer 924, a BCF timer 925, and a judging unit 926.
- the second detecting unit 921 further starts the SICH timer 924 and the BCF timer 925 when starting to search for a physical frame.
- the determining unit 926 is configured to determine whether the second parsing unit 922 successfully parses the SICH before the SICH timer 924 times out, and if so, resets the SICH timer 924, otherwise triggers the first acquiring unit 913 to reselect one of the available subchannels.
- the first acquisition unit 913 reselects one of the available subchannels.
- the device may further include a module for determining whether the channel list is expired, and the module may monitor the module 91 for acquiring synchronization. The operation starts counting after it completes the channel list scan. After the set time is reached, the result of the channel list expiration is obtained.
- the module 92 that maintains synchronization can directly utilize the result of whether the channel list derived by the module expires.
- the second detecting unit 921 can determine the start time of the next physical frame by using the SICH in the found current physical frame on the selected subchannel.
- the apparatus for acquiring system synchronization in the embodiment of the present invention may further include: a synchronization unit that establishes synchronization with the CAP by using a system common clock in the system parameter.
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KR1020137028960A KR101903648B1 (ko) | 2011-03-31 | 2012-03-07 | 무선 네트워크에 액세스하는 방법 및 장치 |
US14/008,958 US9391760B2 (en) | 2011-03-31 | 2012-03-07 | Method and device for accessing wireless network |
CN201280012764.1A CN103583075B (zh) | 2011-03-31 | 2012-03-07 | 用于接入无线网络的方法及装置 |
EP12764244.5A EP2693825B1 (en) | 2011-03-31 | 2012-03-07 | Method and device for accessing wireless network |
JP2014501411A JP6164693B2 (ja) | 2011-03-31 | 2012-03-07 | 無線ネットワークアクセス用の方法及び装置 |
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CN2012100505543A CN102625441A (zh) | 2011-03-31 | 2012-02-29 | 用于接入无线网络的方法及装置 |
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US20180048414A1 (en) * | 2016-08-11 | 2018-02-15 | Commscope Technologies Llc | Discovering physical cell identification in a sub-banded signal in a distributed base station |
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CN110881194B (zh) * | 2018-09-05 | 2023-09-19 | 广东新岸线科技有限公司 | 一种基于超高吞吐无线系统的通信方法及装置 |
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JP2014514819A (ja) | 2014-06-19 |
JP6164693B2 (ja) | 2017-07-19 |
US20140086169A1 (en) | 2014-03-27 |
US9391760B2 (en) | 2016-07-12 |
KR101903648B1 (ko) | 2018-10-04 |
CN102625441A (zh) | 2012-08-01 |
EP2693825A1 (en) | 2014-02-05 |
EP2693825B1 (en) | 2018-08-08 |
KR20140027203A (ko) | 2014-03-06 |
CN103583075B (zh) | 2017-02-22 |
CN103583075A (zh) | 2014-02-12 |
EP2693825A4 (en) | 2015-01-07 |
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