WO2011082526A1 - Method and device for frequency spectrum share in different wireless communication systems - Google Patents
Method and device for frequency spectrum share in different wireless communication systems Download PDFInfo
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- WO2011082526A1 WO2011082526A1 PCT/CN2010/070052 CN2010070052W WO2011082526A1 WO 2011082526 A1 WO2011082526 A1 WO 2011082526A1 CN 2010070052 W CN2010070052 W CN 2010070052W WO 2011082526 A1 WO2011082526 A1 WO 2011082526A1
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- H—ELECTRICITY
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- H04W16/14—Spectrum sharing arrangements between different networks
Definitions
- the present invention relates to wireless communications, and more particularly to mechanisms for spectrum sharing in wireless communication systems having different physical layer technologies. Background technique
- the frequency sharing can be used to cause the slave device to utilize the spectrum band of the master device in a random manner.
- the IEEE 802.22 system has used the TV band as a shared target band to implement a point-to-multipoint (P-MP) wireless area network (WRAN).
- P-MP point-to-multipoint
- WRAN wireless area network
- spectrum sharing technology can achieve the coexistence of multiple wireless systems. Improving frequency usage.
- the IEEE 802.16h working group is defining improved mechanisms based on the IEEE 802.16 standard, such as policy and media access control enhancements to achieve inter-system coexistence.
- Additional interference and coexistence issues are examples of interference and coexistence issues.
- the frequency sharing mechanism can be divided into two categories: collaborative mode and non-cooperative mode.
- collaborative mode the wireless system can share information including IP addresses, channel states, and the like with each other using a wireless interface or other communication link.
- cooperative mode can achieve higher spectrum utilization than the non-cooperative mode.
- PHY technology multiple systems using different physical layer technologies (hereinafter referred to as PHY technology) may operate in the same region at the same time in the same frequency band.
- IEEE 802.il ie compatible wireless LAN WLAN
- Bluetooth devices ie compatible wireless LAN WLAN
- home RF solutions ie compatible cordless phones, etc.
- the IEEE 802.16h group has specified a technique for applying different PHY technologies.
- the communication mechanism of the system pre-defined the reserved short time slots at the end of the DL (downlink) subframe.
- the short time slot is referred to as CSI (Coexistence Signaling Interval), in which each base station (BS) identifies itself to the neighboring system, and Figure 1 shows the coexistence signaling interval allocation in the CX frame.
- the shared channel includes a plurality of CX frames, and each CX frame is composed of 4 MAC frames. Each CX frame is subdivided into specific subframes including master, slave, and shared frames. For an originating base station (IBS), the corresponding CSI is called ICSI, which is allocated in the shared frame of the CX frame.
- IBS originating base station
- IBS uses ICSI to broadcast coexisting signaling messages to its neighboring systems. By cooperating with other BSs, the IBS will obtain its OCSI, which is the coexistence signaling interval assigned to one of the three non-shared frames in the CX frame. Once the BS has initiated the working phase and declares its primary frame, the BS will occupy the OSCI within the primary frame and release the ICSI described above for the new IBS.
- OCSI the coexistence signaling interval assigned to one of the three non-shared frames in the CX frame.
- a CSI sequence consisting of 256 slots should start at the first CX frame of every 256 CX frame in each system.
- the CSI sequence should always start with 8 bits 1 (sequence start) and end with 8 bit 0 (end of sequence).
- Each CSI sequence shall have an 8-bit additional cyclic redundancy check CRC to verify the correctness of the information carried in the CSI sequence.
- the conventional CSI infrastructure is shown in Figure 2.
- the traditional CSI allocation method defined in 802.16h does not guarantee that no conflicts will occur in ICSI.
- IBSs When two or more IBSs wish to enter a coexisting community, they will start transmitting coexistence signaling messages at the first CX frame of every 256 CX frame in each system since they do not know each other's existence. In this case, their CSI sequences will collide with each other, and the neighboring system cannot successfully obtain the information of the IBS through the energy detection method. Therefore, these IBSs will resend their coexistence messages in the next 256CX frame, so collisions in the ICSI sequence sent from these IBSs will occur again. As a result, no IBS can go to other The OBS sends any information so that it cannot share channels with other OBSs.
- the present invention proposes an optimized communication mechanism in a system having different PHY technologies, which can effectively solve the conflict problem of PHY signaling messages.
- This communication mechanism referred to as Coexistence Signaling with Collision Resolution Policy (CS-CR) introduces a backoff scheme and a pre-announcement procedure with a specific priority of IBS in the conventional CSI mechanism.
- each IBS base station needs to transmit an additional energy coded signal (referred to herein as a reservation signal) to reserve subsequent transmission opportunities before transmitting the coexistence signaling message.
- the content of the reservation signal contains the specific priority of each IBS access ICSI.
- a competition window having an arbitrary length is used to avoid collision of reservation signals from different IBSs.
- the present invention provides a method for frequency sharing between a base station and at least one other base station, wherein all base stations belong to different wireless communication systems, the method comprising: a. the base station and the at least One other base station selects a time window from a plurality of reserved time windows to prepare a transmission reservation signal and at least one other reservation signal, the reservation signal includes priority information of the base station, and the at least one other reservation signal includes Priority information of the at least one other base station; b. the base station obtains priority information included in the at least one other reservation signal, and compares priorities included in the reservation signal and the at least one other reservation signal And c.
- a coexistence signaling transmission time of the base station after the plurality of reserved time windows in a case where a priority included in the reservation signal is greater than a priority included in the at least one other reservation signal The segment transmits a coexistence signaling message, otherwise the transmission of the coexistence signaling message is suspended.
- step b further comprises the base station obtaining a priority of the at least one other base station by scanning a power level of a reserved time window selected by the at least one other base station.
- the method according to an embodiment of the present invention further comprises: in a time window selected by the base station, if the priority of the base station is greater than a priority of the at least one other base station, the base station sends the reservation signal.
- the method according to the embodiment of the present invention further comprises: in a time window selected by the base station, if the priority of the base station is less than the priority of the at least one other base station, the base station suspends transmitting The reservation signal is described.
- the priority of the base station depends on the number of coexistence signaling messages that the base station has experienced.
- the priority of the base station will also depend on the particular communication requirements of the base station, the particular communication requirements including at least one of military, medical, or emergency communication requirements.
- the priority of the base station is increased by one.
- the present invention also provides a base station of a wireless communication system, wherein the base station performs frequency sharing with at least one other base station belonging to another wireless communication system, and the base station includes: a. a time window selecting device, configured to: Selecting a time window from a plurality of reserved time windows to prepare a transmission reservation signal, wherein the reservation signal includes priority information of the base station; b. priority comparison means, configured to obtain an appointment sent by the other base station a priority information included in the signal, and comparing a priority of the base station with a priority of the other base station; and C.
- the coexistence signaling message is transmitted in the coexistence signaling transmission period after the reserved time window, otherwise, the transmission of the coexistence signaling message is suspended.
- the priority comparison means is further configured to obtain a priority of the other base station by scanning a power level of a reserved time window selected by the other base station.
- the base station further includes a reservation signal transmission control device, the device configured to: if the base is within a time window selected by the base station If the priority of the station is greater than the priority of the other base station, the base station sends the reservation signal; if the priority of the base station is less than the priority of the other base station, the base station suspends transmitting the reservation signal , and increase its priority accordingly.
- a reservation signal transmission control device configured to: if the base is within a time window selected by the base station If the priority of the station is greater than the priority of the other base station, the base station sends the reservation signal; if the priority of the base station is less than the priority of the other base station, the base station suspends transmitting the reservation signal , and increase its priority accordingly.
- the priority of the base station depends on the number of coexistence signaling messages that the base station has experienced, or depends on the specific communication requirements of the base station, the specific communication requirements including military, medical or emergency communication requirements At least one of them.
- the invention also relates to a computer program product in which computer instructions for performing the method according to the invention are stored.
- FIG. 1 shows a coexistence signaling interval CSI allocation in a CX frame according to the prior art
- FIG. 2 shows a construction of a CSI sequence according to the prior art
- FIG. 3 illustrates an ICSI sequence configuration in accordance with an embodiment of the present invention
- FIG. 4 is a flow chart showing a base station transmitting an ICSI sequence according to an embodiment of the present invention
- FIG. 5 is a schematic diagram showing three base stations transmitting CSI sequences according to an embodiment of the present invention
- FIG. 6 is a block diagram showing a base station structure according to the present invention. . detailed description
- Figure 3 illustrates an ICSI sequence configuration in accordance with an embodiment of the present invention.
- coexistence signaling is mainly used to transmit BS_NURBC messages and BSD messages, and their maximum length is 192 bits.
- the length of the CSI sequence defined in 802.16h is 256 bits. Except for the 8-bit CRC, the 8-bit start sequence and the 8-bit end sequence, there are still 40 remaining bits that are not used.
- Figure 3 shows the optimized CSI sequence construction according to the new CS-CR mechanism.
- the entire 256-bit ICSI sequence consists of two parts: 32ICSI is used to transmit reservation signals from different IBS. These 32 ICSIs are in turn divided into four super ICSIs, each super ICSI consisting of eight ICSIs and used to send a reservation signal. Each super CSI should start with 2 bits "1" and 2 bits "0", indicating the beginning of the super CSI, and the remaining 4 bits indicate the specific priority of the IBS.
- the specific priority of the IBS can be set depending on many factors. For example, an IBS with a particular military, medical, or emergency communication can be preset to have a high priority value.
- the priority of the IBS may be set according to the number of ICSI sequences that the IBS has experienced. For example, if an IBS has no chance or cannot send its own coexistence signaling within two ICSI sequences (ie 10.24 seconds) due to a collision, its priority will be set to 2. The greater the number of ICSI experienced by the IBS (which means that the IBS has spent more time transmitting coexistence signaling, but none succeeded), then the more priority the IBS gets to send its own coexistence signaling high.
- each super CSI is composed of 8 ICSIs and used to transmit a reservation signal.
- the manner in which the super CSI is divided is not limited to this. The more the number of super CSIs, the lower the probability of collision of IBS messages, and the less information transmitted accordingly. Conversely, the fewer the number of super CSIs, the greater the probability that IBS messages will collide. The more information is transmitted accordingly.
- the number of super CSIs can be dynamically set according to the scenario in the actual application. Herein, preferably, the number of super CSIs is selected to be four.
- each IBS arbitrarily selects one of the four super CSIs in preparation for transmitting the reservation signal.
- the value of the last 4 bits of the selected super CSI is set according to the number of ICSI sequences that the IBS has experienced.
- the IBS needs to scan the power energy levels of other super CSIs to obtain the priority of other IBSs.
- the IBS compares its own priority with the priority of other IBSs.
- step 404 the transmission of its own reservation signal is suspended until the next ICSI sequence. If not, then in step 405, the IBS will send its own reservation signal within the pre-selected super CSI.
- step 406 the IBS continues to scan the power levels of other super CSIs and compares their own priorities with those of other IBSs. As shown in step 407, after completing the power level sweep of the four super CSIs, the IBS will determine whether it wants to transmit its own coexistence signaling within the next 224 ICSI by comparing the priorities.
- the IBS will send its own coexistence signaling in the subsequent 224-bit ICSI. Otherwise, as shown in Figure 408, it will suspend the transmission of its own signaling message within the next 224-bit ICSI, while its own priority is automatically incremented by 1, indicating that the IBS has experienced another ICSI sequence but failed to send its own Coexisting signaling, but its priority is increased by one over the last time the ICSI sequence is sent.
- the SS (client terminal equipment) of the OBS that successfully receives the coexistence signaling will report the contents of the coexistence signaling message to their OBS.
- the neighboring OBS will discover the IBS in the IP network after receiving the SS report of the signaling.
- the IBS and OBS begin further negotiation for frequency sharing. After negotiating with multiple OBSs, the IBS will acquire a periodic interference-free OCSI and become an OBSS, after which it will stop using the current ICSI.
- a process of transmitting coexistence signaling is shown by taking three base stations as an example.
- the priorities of the three base stations IBS1, IBS2, IBS3 are initially 0, 1, and 2, respectively. That is, IBS 2 failed to send its own coexistence signaling in the previous ICSI sequence according to the number of ICSI sequences that IBS has experienced. In the previous two sequences, IBS 3 failed to send its own. Coexistence signaling.
- the IBS 1 arbitrarily selects the super CSI 1 to transmit its own reservation signal
- the IBS 2 arbitrarily selects the super CSI 4 to transmit its own reservation signal
- the IBS 3 arbitrarily selects the super CSI 2 to transmit itself. Reservation signal.
- IBS2 and IBS3 can scan the current super CSI during work.
- the rate energy level takes the priority of IBS 1. Since the priority of IBS 1 is lower than their own priority, IBS 2/IBS 3 decides to continue transmitting its own reservation signal.
- IBS 3 sends its own reservation signal. IBS2 and IBS 1 can obtain the priority of IBS3 by scanning the power energy level during the current super CSI.
- IBS 1, IBS 2 and IBS 3 After completing the power level sweep of 4 super CSIs, IBS 1, IBS 2 and IBS 3 if compare the priorities of other IBSs with their own priorities to decide whether to transmit coexistence signaling. Since IBS 3 has the highest priority, IBS 3 can obtain the opportunity to transmit its own coexistence signaling and become OBS through coordination with other OBSs. While IBS 1 and IBS 2 will suspend coexistence signaling in the subsequent 224 ICSI and their priority will increase by 1. In the next ICSI sequence, IBS 1 and IBS 2 will restart similar procedures to transmit coexistence signaling. .
- FIG. 6 shows a schematic block diagram of an IBS base station according to an embodiment of the present invention.
- the figure shows three base stations 601, 602, 603, each belonging to a different wireless communication system.
- the base station includes a time window selecting means 611, a priority comparing means 612, and a coexistence signaling transmitting control means 613.
- the base station 603 further includes a reservation signal transmission control means 614.
- the device 611 is configured to select a time window from a plurality of reserved time windows, for example, 4 super CSIs, for example, the time window selected in FIG. 5 exceeds CSI 2 (CX frames 9 - 16 ) to prepare to transmit a reservation signal, where
- the reservation signal includes the priority information of the base station 603; correspondingly, the corresponding devices of the other base stations 601, 602 also arbitrarily select a reserved time window, such as the super CSI 1 and the super CSI 4 in FIG. 5, we can also call them The first time window and the fourth reserved time window.
- the device 612 is configured to obtain priority information included in a reservation signal of another base station (ie, the base station 601, 602 in this example), and compare the priority information of the base station 603 with the priorities of the other base stations 601, 602.
- the device 613 At the end of the total reservation time window, for example, at the end of the four super CSIs in FIG. 5, the device 613, in the case where the base station 603 has a priority greater than the priorities of the base stations 601, 602, The coexistence signaling message is transmitted in the subsequent coexistence signaling transmission period (ie, within CX frames 33 to 256).
- Apparatus 614 is configured to: within a time window selected by the 603 base station, if the priority of base station 603 is greater than the priority of other base stations (e.g., 601) that have been learned by power level sweeping, base station 603 transmits a reservation signal if the base station If the priority of 603 is less than the priority of these base stations (e.g., 601), the base station 603 suspends the transmission of the reservation signal and increases its priority accordingly. Such a setting can further avoid conflicting problems that may occur when the reservation signal is transmitted.
- the base station according to the embodiment of the present invention does not involve hardware improvement, and can be implemented on the basis of the existing base station by combining computer software.
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Abstract
The present invention discloses a method and a device for frequency spectrum share between a base station and at least one of other base stations. All of the base stations belong to different wireless communication systems separately. The method includes: a. the base station and at least one of other base stations select a time window separately from multiple reserved time windows to prepare for sending reservation signal and at least one of other reservation signals, wherein the reservation signal contains priority level information of the base station, and the at least one of other reservation signals contains priority level information of at least one of other base stations; b. the base station obtains the priority level information contained in the at least one of other reservation signals, and compares the priority level contained in the reservation signal with the priority level contained in the at least one of other reservation signals; c. if the priority level contained in the reservation signal is higher than the priority level contained in the at least one of other reservation signals, the base station sends a concomitant signaling message in a concomitant signaling sending time segment, which is after the multiple reserved time windows; otherwise, the base station pauses the sending of the concomitant signaling message.
Description
在不同无线通信系统中进行频语共享的方法和设备 技术领域 Method and device for frequency sharing in different wireless communication systems
本发明涉及无线通信, 尤其涉及在具有不同物理层技术的无线通 信系统中进行频谱共享的机制。 背景技术 The present invention relates to wireless communications, and more particularly to mechanisms for spectrum sharing in wireless communication systems having different physical layer technologies. Background technique
近来, 由于可以减轻频语匮乏问题, 频语共享技术已经吸引了相 当多的关注。 一方面, 在许可频段, 频语共享能用于使得从设备以随 机方式利用主设备的频谱带。 例如, IEEE 802.22 系统已经把使用电 视频段作为共享目标频段, 以实现点到多点 (P-MP )无线区域网络 ( WRAN )„ 在免许可频段, 频谱共享技术可以实现多个无线系统的 共存以改善频语利用率。 例如, IEEE 802.16h工作组正在基于 IEEE 802.16标准定义改进的机制, 如策略和媒体访问控制增强, 以实现系 统间的共存。 然而, 随着免许可频段使用的增加, 引入了另外的干扰 和共存问题。 Recently, frequency sharing technology has attracted a lot of attention because it can alleviate the lack of frequency. On the one hand, in the licensed band, the frequency sharing can be used to cause the slave device to utilize the spectrum band of the master device in a random manner. For example, the IEEE 802.22 system has used the TV band as a shared target band to implement a point-to-multipoint (P-MP) wireless area network (WRAN). In the unlicensed band, spectrum sharing technology can achieve the coexistence of multiple wireless systems. Improving frequency usage. For example, the IEEE 802.16h working group is defining improved mechanisms based on the IEEE 802.16 standard, such as policy and media access control enhancements to achieve inter-system coexistence. However, as the use of unlicensed bands increases, Additional interference and coexistence issues.
根据无线系统之间的信息交换是否必需, 频语共享机制可以划分 为两类: 协同模式和非协同模式。 在协同模式中, 无线系统可以使用 无线接口或其他通信链路彼此共享包括 IP地址、 信道状态等的信息。 一般地, 与非协同模式比较, 协同模式可以获得更高的频谱利用率。 According to whether information exchange between wireless systems is necessary, the frequency sharing mechanism can be divided into two categories: collaborative mode and non-cooperative mode. In the collaborative mode, the wireless system can share information including IP addresses, channel states, and the like with each other using a wireless interface or other communication link. In general, the cooperative mode can achieve higher spectrum utilization than the non-cooperative mode.
然而, 由于免许可频段的不排他性质, 采用不同物理层技术(下 文中简称 PHY技术)的多个系统可能在相同频段相同时间相同区域中 工作。 例如, IEEE802.il (即兼容的无线局域网 WLAN )、 蓝牙设备、 家庭射频解决方案、 无繩电话等, 当前都拥挤在 2.4GHz频段。 在这 种情况下,重要的是,设计一种在这些采用不同 PHY技术的系统中可 行的通信机制, 然后采用协同的干扰解决机制以获得更好的共存。 However, due to the non-exclusive nature of the unlicensed bands, multiple systems using different physical layer technologies (hereinafter referred to as PHY technology) may operate in the same region at the same time in the same frequency band. For example, IEEE 802.il (ie compatible wireless LAN WLAN), Bluetooth devices, home RF solutions, cordless phones, etc., are currently crowded in the 2.4 GHz band. In this case, it is important to design a communication mechanism that is viable in these systems using different PHY technologies, and then use a coordinated interference resolution mechanism to achieve better coexistence.
当前, IEEE 802.16h组已经规定了一种应用于具有不同 PHY技
术的系统的通信机制, 预定义了 DL (下行链路)子帧末端的预留短 时隙。 该短时隙被称之为为 CSI (共存信令间隔), 在 CSI中每个基站 ( BS )向邻近系统标识它自身, 图 1给出了 CX帧中的共存信令间隔 分配。 共享信道包括多个 CX帧, 每一个 CX帧由 4个 MAC帧构成。 每一个 CX帧被细分为包括主、 从和共享帧的特定子帧。 对于发起基 站(IBS )来说, 对应的 CSI被称为 ICSI, 它被分配在 CX帧的共享 帧中。 IBS使用 ICSI 向其邻近系统广播共存信令消息。 通过与其它 BS协作, IBS将获得它的 OCSI, OCSI是被分配到 CX帧中三个非 共享帧之一的共存信令间隔。 一旦 BS 已经启动工作阶段并且声明它 的主帧, 该 BS就将占用该主帧内的 OSCI并释放上述 ICSI用于新的 IBS。 Currently, the IEEE 802.16h group has specified a technique for applying different PHY technologies. The communication mechanism of the system, pre-defined the reserved short time slots at the end of the DL (downlink) subframe. The short time slot is referred to as CSI (Coexistence Signaling Interval), in which each base station (BS) identifies itself to the neighboring system, and Figure 1 shows the coexistence signaling interval allocation in the CX frame. The shared channel includes a plurality of CX frames, and each CX frame is composed of 4 MAC frames. Each CX frame is subdivided into specific subframes including master, slave, and shared frames. For an originating base station (IBS), the corresponding CSI is called ICSI, which is allocated in the shared frame of the CX frame. IBS uses ICSI to broadcast coexisting signaling messages to its neighboring systems. By cooperating with other BSs, the IBS will obtain its OCSI, which is the coexistence signaling interval assigned to one of the three non-shared frames in the CX frame. Once the BS has initiated the working phase and declares its primary frame, the BS will occupy the OSCI within the primary frame and release the ICSI described above for the new IBS.
由于进行频语共享的若干系统采用不同 PHY技术,在这些系统间 用于携带频语共享信息(包括共存信令消息等) 的报文需要借助于时 域中的能量键控来传送。 CSI持续期间的能量功率是否大于预定阈值 被表示为信息位 "1" 或 "0"。 根据 802.16h规范, 由 256个时隙组成 的 CSI序列应当在各系统中每 256CX帧的第一个 CX帧开始。 CSI 序列应当总是以 8位 1开始 (序列起始)并且以 8位 0结束(序列末 端)。每个 CSI序列应当具有 8位附加的循环冗余码校验 CRC以检验 CSI序列中携带的信息的正确性。传统的 CSI基础结构在图 2中示出。 Since several systems that use frequency sharing use different PHY technologies, messages used to carry frequency-shared information (including coexisting signaling messages, etc.) between these systems need to be transmitted by energy keying in the time domain. Whether the energy power during the CSI duration is greater than a predetermined threshold is expressed as information bit "1" or "0". According to the 802.16h specification, a CSI sequence consisting of 256 slots should start at the first CX frame of every 256 CX frame in each system. The CSI sequence should always start with 8 bits 1 (sequence start) and end with 8 bit 0 (end of sequence). Each CSI sequence shall have an 8-bit additional cyclic redundancy check CRC to verify the correctness of the information carried in the CSI sequence. The conventional CSI infrastructure is shown in Figure 2.
尽管 OCSI 的排他分配能解决若干 OCSI 中的信息冲突, 但是 802.16h 中定义的传统 CSI分配方式并不能保证在 ICSI 中不发生冲 突。 当两个或更多 IBS希望进入共存团体时, 由于它们并不知道彼此 的存在,它们将在各系统中的每 256CX帧的第一个 CX帧开始发送共 存信令消息。 在这种情况下, 它们的 CSI序列彼此之间会发生冲突, 邻近系统通过能量检测方式不能成功获得 IBS的信息。因此,这些 IBS 将在下一个 256CX 帧中再次发送它们的共存消息, 于是从这些 IBS 发出的 ICSI序列中的冲突将再次发生。 结果是, 没有 IBS能向其它
OBS发送任何信息从而不能与其它 OBS共享信道。 Although the exclusive allocation of OCSI can resolve information conflicts in several OCSIs, the traditional CSI allocation method defined in 802.16h does not guarantee that no conflicts will occur in ICSI. When two or more IBSs wish to enter a coexisting community, they will start transmitting coexistence signaling messages at the first CX frame of every 256 CX frame in each system since they do not know each other's existence. In this case, their CSI sequences will collide with each other, and the neighboring system cannot successfully obtain the information of the IBS through the energy detection method. Therefore, these IBSs will resend their coexistence messages in the next 256CX frame, so collisions in the ICSI sequence sent from these IBSs will occur again. As a result, no IBS can go to other The OBS sends any information so that it cannot share channels with other OBSs.
如上所述, 当多于一个 IBS想要加入共存团体时, 由于在 ICSI 期间共存信令消息的冲突, 以致不能与 "邻居" 通信。 发明内容 As described above, when more than one IBS wants to join a coexistence community, there is a conflict of coexistence of signaling messages during ICSI, so that it cannot communicate with "neighbors". Summary of the invention
为了解决以上问题,本发明提出一种在具有不同 PHY技术的系统 中的优化通信机制,该机制能有效解决 PHY信令消息的冲突问题。被 称为带有冲突解决策略的共存信令(CS-CR ) 的这种通信机制在传统 CSI机制中引入退避方案和具有 IBS的特定优先级的预宣告过程。 一 方面, 在发送共存信令消息之前, 每个 IBS基站需要发送附加的能量 编码信号(本文中称为预约信号) 以预留后续的发送机会。 该预约信 号的内容包含每个 IBS接入 ICSI的特定优先级。 另一方面, 使用具 有任意长度的竟争窗口以避免来自于不同 IBS的预约信号的冲突。 In order to solve the above problems, the present invention proposes an optimized communication mechanism in a system having different PHY technologies, which can effectively solve the conflict problem of PHY signaling messages. This communication mechanism, referred to as Coexistence Signaling with Collision Resolution Policy (CS-CR), introduces a backoff scheme and a pre-announcement procedure with a specific priority of IBS in the conventional CSI mechanism. In one aspect, each IBS base station needs to transmit an additional energy coded signal (referred to herein as a reservation signal) to reserve subsequent transmission opportunities before transmitting the coexistence signaling message. The content of the reservation signal contains the specific priority of each IBS access ICSI. On the other hand, a competition window having an arbitrary length is used to avoid collision of reservation signals from different IBSs.
为此, 本发明提供了一种在基站和至少一个其他基站之间进行频 语共享的方法, 其中, 所有基站分别属于不同的无线通信系统, 该方 法包括: a. 所述基站和所述至少一个其他基站从多个预留时间窗口内 分别选择一个时间窗口, 以准备发送预约信号和至少一个其他预约信 号, 所述预约信号包含所述基站的优先级信息, 所述至少一个其他预 约信号包含所述至少一个其他基站的优先级信息; b. 所述基站获得所 述至少一个其他预约信号中包含的优先级信息, 并比较所述预约信号 和所述至少一个其他预约信号中包含的优先级;以及 c. 在所述预约信 号中包含的优先级大于所述至少一个其他预约信号中包含的优先级的 情况下, 所述基站在所述多个预留时间窗口之后的共存信令发送时间 段发送共存信令消息, 否则暂停所述共存信令消息的发送。 To this end, the present invention provides a method for frequency sharing between a base station and at least one other base station, wherein all base stations belong to different wireless communication systems, the method comprising: a. the base station and the at least One other base station selects a time window from a plurality of reserved time windows to prepare a transmission reservation signal and at least one other reservation signal, the reservation signal includes priority information of the base station, and the at least one other reservation signal includes Priority information of the at least one other base station; b. the base station obtains priority information included in the at least one other reservation signal, and compares priorities included in the reservation signal and the at least one other reservation signal And c. a coexistence signaling transmission time of the base station after the plurality of reserved time windows in a case where a priority included in the reservation signal is greater than a priority included in the at least one other reservation signal The segment transmits a coexistence signaling message, otherwise the transmission of the coexistence signaling message is suspended.
在根据本发明的实施例中, 步骤 b进一步包括所述基站通过扫描 所述至少一个其他基站选择的预留时间窗口的功率电平以获得所述至 少一个其他基站的优先级。
优选地, 根据本发明的实施例的方法进一步包括: 在所述基站选 择的时间窗口内, 如果所述基站的优先级大于所述至少一个其他基站 的优先级, 则所述基站发送所述预约信号。 In an embodiment in accordance with the invention, step b further comprises the base station obtaining a priority of the at least one other base station by scanning a power level of a reserved time window selected by the at least one other base station. Preferably, the method according to an embodiment of the present invention further comprises: in a time window selected by the base station, if the priority of the base station is greater than a priority of the at least one other base station, the base station sends the reservation signal.
优选地, 根据本发明的实施例的方法进一步包括: 在所述基站选 择的时间窗口内, 如果所述基站的优先级小于所述至少一个其他基站 的优先级, 则所述基站暂緩发送所述预约信号。 Preferably, the method according to the embodiment of the present invention further comprises: in a time window selected by the base station, if the priority of the base station is less than the priority of the at least one other base station, the base station suspends transmitting The reservation signal is described.
根据本发明的实施例, 其中基站的优先级取决于该基站已经经历 的共存信令消息的数量。 According to an embodiment of the invention, the priority of the base station depends on the number of coexistence signaling messages that the base station has experienced.
进一步地, 基站的优先级还将取决于该基站的特定通信要求, 所 述特定通信要求包括军事、 医疗或紧急通信要求中的至少一个。 Further, the priority of the base station will also depend on the particular communication requirements of the base station, the particular communication requirements including at least one of military, medical, or emergency communication requirements.
优选地在, 如果通过优先级的比较, 基站在随后的共存信令发送 时间段暂停自己的共存信令消息的发送, 则基站的优先级增加 1。 Preferably, if the base station suspends transmission of its own coexistence signaling message during the subsequent coexistence signaling transmission period by comparison of priorities, the priority of the base station is increased by one.
另一方面, 本发明还提供了一种无线通信系统的基站, 所述基站 与至少一个属于其他无线通信系统的其他基站进行频语共享, 所述基 站包括: a. 时间窗口选择装置, 用于从多个预留时间窗口内选择一个 时间窗口, 以准备发送预约信号, 其中所述预约信号包含所述基站的 优先级信息; b. 优先级比较装置, 用于获得所述其他基站发送的预约 信号中包含的优先级信息, 并将所述基站的优先级与所述其他基站的 优先级进行比较; 以及 C. 共存信令发送控制装置, 用于在所述预约 信号中包含的优先级大于所述其他预约信号中包含的优先级的情况 下, 在所述预留时间窗口之后的共存信令发送时间段发送共存信令消 息, 否则, 暂停所述共存信令消息的发送。 In another aspect, the present invention also provides a base station of a wireless communication system, wherein the base station performs frequency sharing with at least one other base station belonging to another wireless communication system, and the base station includes: a. a time window selecting device, configured to: Selecting a time window from a plurality of reserved time windows to prepare a transmission reservation signal, wherein the reservation signal includes priority information of the base station; b. priority comparison means, configured to obtain an appointment sent by the other base station a priority information included in the signal, and comparing a priority of the base station with a priority of the other base station; and C. a coexistence signaling control device, wherein the priority included in the reserved signal is greater than In the case of the priority included in the other reservation signal, the coexistence signaling message is transmitted in the coexistence signaling transmission period after the reserved time window, otherwise, the transmission of the coexistence signaling message is suspended.
在根据本发明的实施例中, 所述优先级比较装置进一步被配置为 通过扫描所述其它基站选择的预留时间窗口的功率电平以获得所述其 它基站的优先级。 In an embodiment in accordance with the invention, the priority comparison means is further configured to obtain a priority of the other base station by scanning a power level of a reserved time window selected by the other base station.
优选地, 根据本发明实施例的基站进一步包括预约信号发送控制 装置, 该装置被配置为: 在所述基站选择的时间窗口内, 如果所述基
站的优先级大于所述其它基站的优先级, 则所述基站发送所述预约信 号; 如果所述基站的优先级小于所述其它基站的优先级, 则所述基站 暂緩发送所述预约信号, 并相应增加其优先级。 Preferably, the base station according to an embodiment of the present invention further includes a reservation signal transmission control device, the device configured to: if the base is within a time window selected by the base station If the priority of the station is greater than the priority of the other base station, the base station sends the reservation signal; if the priority of the base station is less than the priority of the other base station, the base station suspends transmitting the reservation signal , and increase its priority accordingly.
根据本发明的实施例, 所述基站的优先级取决于该基站已经经历 的共存信令消息的数量, 或者取决于该基站的特定通信要求, 所述特 定通信要求包括军事、 医疗或紧急通信要求中的至少一个。 According to an embodiment of the invention, the priority of the base station depends on the number of coexistence signaling messages that the base station has experienced, or depends on the specific communication requirements of the base station, the specific communication requirements including military, medical or emergency communication requirements At least one of them.
另一方面, 本发明还涉及一种计算机程序产品, 其中存储有用于 执行根据本发明的方法的计算机指令。 附图说明 In another aspect, the invention also relates to a computer program product in which computer instructions for performing the method according to the invention are stored. DRAWINGS
通过参考以下结合附图的说明, 本发明的其他目的及优点将变得 更加清楚和易于理解, 在附图中: Other objects and advantages of the present invention will become more apparent and appreciated from the description of the appended claims appended claims
图 1示出了根据现有技术的 CX帧中的共存信令间隔 CSI分配; 图 2示出根据现有技术 CSI序列的构造; 1 shows a coexistence signaling interval CSI allocation in a CX frame according to the prior art; FIG. 2 shows a construction of a CSI sequence according to the prior art;
图 3示出根据本发明的实施例的 ICSI序列构造; Figure 3 illustrates an ICSI sequence configuration in accordance with an embodiment of the present invention;
图 4示出根据本发明的实施例, 基站发送 ICSI序列的流程图; 图 5示出根据本发明的实施例,三个基站发送 CSI序列的示意图; 图 6示出根据本发明的基站结构框图。 具体实施方式 4 is a flow chart showing a base station transmitting an ICSI sequence according to an embodiment of the present invention; FIG. 5 is a schematic diagram showing three base stations transmitting CSI sequences according to an embodiment of the present invention; FIG. 6 is a block diagram showing a base station structure according to the present invention. . detailed description
图 3 示出根据本发明的实施例的 ICSI序列构造。 根据 IEEE 802.16h规范, 共存信令主要用于发送 BS_NURBC消息和 BSD消息, 它们的最大长度是 192位。 如上所述, 802.16h中定义的 CSI序列的 长度是 256位。 除了 8位 CRC, 8位起始序列和 8位结尾序列外, 仍 然有 40个位剩余位没有使用。 图 3中是根据新的 CS-CR机制的优化 CSI序列构造。 Figure 3 illustrates an ICSI sequence configuration in accordance with an embodiment of the present invention. According to the IEEE 802.16h specification, coexistence signaling is mainly used to transmit BS_NURBC messages and BSD messages, and their maximum length is 192 bits. As mentioned above, the length of the CSI sequence defined in 802.16h is 256 bits. Except for the 8-bit CRC, the 8-bit start sequence and the 8-bit end sequence, there are still 40 remaining bits that are not used. Figure 3 shows the optimized CSI sequence construction according to the new CS-CR mechanism.
如图 3所示, 整个 256位 ICSI序列由两部分组成: 第一部分的
32ICSI用于传送来自不同 IBS的预约信号。 这些 32ICSI又被划分为 4个超 ICSI,每个超 ICSI由 8个 ICSI组成并用于发送一个预约信号。 每个超 CSI应当以 2位 "1" 和 2位 "0" 开始, 表示超 CSI的开始, 其余 4位表示 IBS的特定优先级。 IBS的特定优先级可以取决于许多 因素进行设置。 例如,具有特定军事、 医疗或紧急通信的 IBS可以预设 为具有高优先级值。 在本发明的实施例中, 作为典型的例子, IBS 的 优先级可以根据 IBS 已经经历的 ICSI序列的数量来设定。 例如, 如 果一个 IBS因冲突没有机会或不能在两个 ICSI序列内 (即 10.24秒) 发送它自己的共存信令,它的优先级将设置为 2。 IBS经历的 ICSI的数 量越大(这意味着该 IBS已经花费较多时间以发送共存信令,但都没能 成功), 那么该 IBS获得发送它自己的共存信令的机会的优先级就越 高。 As shown in Figure 3, the entire 256-bit ICSI sequence consists of two parts: 32ICSI is used to transmit reservation signals from different IBS. These 32 ICSIs are in turn divided into four super ICSIs, each super ICSI consisting of eight ICSIs and used to send a reservation signal. Each super CSI should start with 2 bits "1" and 2 bits "0", indicating the beginning of the super CSI, and the remaining 4 bits indicate the specific priority of the IBS. The specific priority of the IBS can be set depending on many factors. For example, an IBS with a particular military, medical, or emergency communication can be preset to have a high priority value. In an embodiment of the invention, as a typical example, the priority of the IBS may be set according to the number of ICSI sequences that the IBS has experienced. For example, if an IBS has no chance or cannot send its own coexistence signaling within two ICSI sequences (ie 10.24 seconds) due to a collision, its priority will be set to 2. The greater the number of ICSI experienced by the IBS (which means that the IBS has spent more time transmitting coexistence signaling, but none succeeded), then the more priority the IBS gets to send its own coexistence signaling high.
需要说明的是, 在本发明的实施例中, 使用了 40位中的 32位, 这些 32ICSI又被划分为 4个超 CSI, 每个超 CSI由 8个 ICSI组成并 用于发送一个预约信号。 然而, 超 CSI 的划分方式并不限于此。 超 CSI的个数越多, IBS消息发生碰撞的可能性就越低, 而相应地传输 的信息就越少; 反之, 超 CSI的个数越少, IBS消息发生碰撞的可能 性就越大, 而相应地传输的信息就越多。 可以根据实际应用中的场景 动态设置超 CSI的数量。 在本文中, 优选地, 超 CSI的数量选择为 4 个。 It should be noted that, in the embodiment of the present invention, 32 bits out of 40 bits are used, and these 32 ICSIs are further divided into 4 super CSIs, and each super CSI is composed of 8 ICSIs and used to transmit a reservation signal. However, the manner in which the super CSI is divided is not limited to this. The more the number of super CSIs, the lower the probability of collision of IBS messages, and the less information transmitted accordingly. Conversely, the fewer the number of super CSIs, the greater the probability that IBS messages will collide. The more information is transmitted accordingly. The number of super CSIs can be dynamically set according to the scenario in the actual application. Herein, preferably, the number of super CSIs is selected to be four.
图 4示出根据本发明的实施例, 基站发送 CSI序列的流程图。 如步骤 401所示,在由 GPS或其它分布式同步方式进行同步之后, 每个 IBS任意选择 4个超 CSI中的一个以准备发送预约信号。 在该实 施例中, 所选择的超 CSI的最后 4位的值根据 IBS已经经历的 ICSI 序列的数量来设定。 在步骤 402中, IBS需要扫描其它超 CSI的功率 能量电平 ( power energy level ) 以获得其它 IBS的优先级。 接着, 在 步骤 403中, IBS将比较自己的优先级与其它 IBS的优先级进行比较。
如果其它 IBS的优先级大于自己的优先级, 则在步骤 404中, 暂緩自 己的预约信号的发送直到下一个 ICSI序列。如果不是这样,则在步骤 405中, 该 IBS将在预先选择的超 CSI内发送自己的预约信号。 接下 来, 在步骤 406内, IBS继续扫描其它超 CSI的功率电平, 并比较自 己的优先级与其它 IBS的优先级。如步骤 407所示,在完成 4个超 CSI 的功率电平扫描后, IBS将通过比较优先级来确定自己是否要在随后 的 224个 ICSI内发送自己的共存信令。如果 IBS的优先级在所有 IBS 中为最高, 在如步骤 409所示, 该 IBS将在随后的 224位 ICSI中发 送自己的共存信令。 否则, 如图 408所示, 它将暂停自己的信令消息 在随后 224位 ICSI内的发送, 同时自己的优先级自动加 1, 这表示该 IBS又经历了一个 ICSI序列但是未能发送自己的共存信令,但是在下 一次 ICSI序列发送时它的优先级比上一次增大了 1。 4 shows a flow diagram of a base station transmitting a CSI sequence in accordance with an embodiment of the present invention. As shown in step 401, after synchronization by GPS or other distributed synchronization mode, each IBS arbitrarily selects one of the four super CSIs in preparation for transmitting the reservation signal. In this embodiment, the value of the last 4 bits of the selected super CSI is set according to the number of ICSI sequences that the IBS has experienced. In step 402, the IBS needs to scan the power energy levels of other super CSIs to obtain the priority of other IBSs. Next, in step 403, the IBS compares its own priority with the priority of other IBSs. If the priority of the other IBS is greater than its own priority, then in step 404, the transmission of its own reservation signal is suspended until the next ICSI sequence. If not, then in step 405, the IBS will send its own reservation signal within the pre-selected super CSI. Next, in step 406, the IBS continues to scan the power levels of other super CSIs and compares their own priorities with those of other IBSs. As shown in step 407, after completing the power level sweep of the four super CSIs, the IBS will determine whether it wants to transmit its own coexistence signaling within the next 224 ICSI by comparing the priorities. If the priority of the IBS is highest in all IBSs, as shown in step 409, the IBS will send its own coexistence signaling in the subsequent 224-bit ICSI. Otherwise, as shown in Figure 408, it will suspend the transmission of its own signaling message within the next 224-bit ICSI, while its own priority is automatically incremented by 1, indicating that the IBS has experienced another ICSI sequence but failed to send its own Coexisting signaling, but its priority is increased by one over the last time the ICSI sequence is sent.
成功接收共存信令的 OBS的 SS (客户终端设备)将向它们的 OBS 报告共存信令消息的内容。 接下来相邻 OBS将在接收该信令的 SS报 告后, 将在 IP网络中发现该 IBS。 接着, 该 IBS和 OBS开始进一步 协商以进行频语共享。在与多个 OBS协商后,该 IBS将获得周期性的 无干扰 OCSI并变成 OBSS, 在这之后它将停止使用当前 ICSI。 The SS (client terminal equipment) of the OBS that successfully receives the coexistence signaling will report the contents of the coexistence signaling message to their OBS. Next, the neighboring OBS will discover the IBS in the IP network after receiving the SS report of the signaling. Next, the IBS and OBS begin further negotiation for frequency sharing. After negotiating with multiple OBSs, the IBS will acquire a periodic interference-free OCSI and become an OBSS, after which it will stop using the current ICSI.
为了更好地理解本发明, 在图 5中, 以三个基站为例, 示出了竟 争发送共存信令的过程。在该例子中,假设三个基站 IBS1、 IBS2、 IBS3 的优先级最初分别为 0、 1和 2。也就是说,按照 IBS已经经历的 ICSI 序列的数量作为优先级的话, 在之前的一个 ICSI序列, IBS 2没能发 送自己的共存信令;在之前的两个序列, IBS 3没能发送自己的共存信 令。 In order to better understand the present invention, in Fig. 5, a process of transmitting coexistence signaling is shown by taking three base stations as an example. In this example, it is assumed that the priorities of the three base stations IBS1, IBS2, IBS3 are initially 0, 1, and 2, respectively. That is, IBS 2 failed to send its own coexistence signaling in the previous ICSI sequence according to the number of ICSI sequences that IBS has experienced. In the previous two sequences, IBS 3 failed to send its own. Coexistence signaling.
在图 5示出的例子中, IBS 1任意地选择超 CSI 1以发送自己的预 约信号, IBS 2任意地选择超 CSI 4以发送自己的预约信号, IBS 3任 意地选择超 CSI 2以发送自己的预约信号。 在超 CSI 1期间, 当 IBS 1 发送其预约信号时, IBS2和 IBS3可以通过扫描当前超 CSI期间的功
率能量电平获得 IBS 1的优先级。 由于 IBS 1的优先级低于它们自己 的优先级, IBS 2/IBS 3决定继续发送它自己的预约信号。 在超 CSI 2 期间, IBS 3发送它自己的预约信号。 IBS2和 IBS 1可以通过扫描当 前超 CSI期间的功率能量电平获得 IBS3的优先级。 In the example shown in FIG. 5, the IBS 1 arbitrarily selects the super CSI 1 to transmit its own reservation signal, the IBS 2 arbitrarily selects the super CSI 4 to transmit its own reservation signal, and the IBS 3 arbitrarily selects the super CSI 2 to transmit itself. Reservation signal. During Super CSI 1, when IBS 1 sends its reservation signal, IBS2 and IBS3 can scan the current super CSI during work. The rate energy level takes the priority of IBS 1. Since the priority of IBS 1 is lower than their own priority, IBS 2/IBS 3 decides to continue transmitting its own reservation signal. During Super CSI 2, IBS 3 sends its own reservation signal. IBS2 and IBS 1 can obtain the priority of IBS3 by scanning the power energy level during the current super CSI.
在完成 4个超 CSI 的功率电平扫描后, IBS 1、 IBS 2和 IBS 3 if 过比较其它 IBS的优先级和自己的优先级来决定是否发送共存信令。 由于 IBS 3的优先级最高, IBS 3可以获得发送自己的共存信令的机会 并通过与其它 OBS的协调成为 OBS。 而 IBS 1和 IBS 2将在随后的 224 ICSI内暂緩发送共存信令并且它们的优先级都会增加 1.在下一 个 ICSI序列中, IBS 1 和 IBS 2将重新开始相似的过程以发送共存信 令。 After completing the power level sweep of 4 super CSIs, IBS 1, IBS 2 and IBS 3 if compare the priorities of other IBSs with their own priorities to decide whether to transmit coexistence signaling. Since IBS 3 has the highest priority, IBS 3 can obtain the opportunity to transmit its own coexistence signaling and become OBS through coordination with other OBSs. While IBS 1 and IBS 2 will suspend coexistence signaling in the subsequent 224 ICSI and their priority will increase by 1. In the next ICSI sequence, IBS 1 and IBS 2 will restart similar procedures to transmit coexistence signaling. .
图 6示出根据本发明实施例的 IBS基站的示意性框图。 图中示出 了三个基站 601、 602、 603, 分别属于不同的无线通信系统。 以其中 一个基站 IBS 603为例,该基站包括时间窗口选择装置 611、优先级比 较装置 612和共存信令发送控制装置 613。 优选地, 基站 603还包括 预约信号发送控制装置 614。 FIG. 6 shows a schematic block diagram of an IBS base station according to an embodiment of the present invention. The figure shows three base stations 601, 602, 603, each belonging to a different wireless communication system. Taking one of the base stations IBS 603 as an example, the base station includes a time window selecting means 611, a priority comparing means 612, and a coexistence signaling transmitting control means 613. Preferably, the base station 603 further includes a reservation signal transmission control means 614.
装置 611用于从多个预留时间窗口, 例如 4个超 CSI内选择一个 时间窗口, 例如图 5中选择的时间窗口超 CSI 2 ( CX帧 9 - 16 ) 以准 备发送预约信号, 其中所述预约信号包含该基站 603的优先级信息; 相应地,其它基站 601, 602的对应装置也任意选择一个预留时间窗口, 例如图 5中的超 CSI 1和超 CSI 4,我们也可以把它们称为第一时间窗 口和第四预留时间窗口。 The device 611 is configured to select a time window from a plurality of reserved time windows, for example, 4 super CSIs, for example, the time window selected in FIG. 5 exceeds CSI 2 (CX frames 9 - 16 ) to prepare to transmit a reservation signal, where The reservation signal includes the priority information of the base station 603; correspondingly, the corresponding devices of the other base stations 601, 602 also arbitrarily select a reserved time window, such as the super CSI 1 and the super CSI 4 in FIG. 5, we can also call them The first time window and the fourth reserved time window.
装置 612, 用于获得其他基站(即本例中的基站 601、 602 ) 的预 约信号中包含的优先级信息, 并将基站 603的优先级信息与其他基站 601、 602的优先级进行比较。 The device 612 is configured to obtain priority information included in a reservation signal of another base station (ie, the base station 601, 602 in this example), and compare the priority information of the base station 603 with the priorities of the other base stations 601, 602.
在全部预留时间窗口结束时,例如在图 5中的 4个超 CSI结束时, 装置 613, 在基站 603优先级大于基站 601、 602的优先级的情况下,
在随后的共存信令发送时间段(即 CX帧 33 ~ 256内)发送共存信令 消息。 At the end of the total reservation time window, for example, at the end of the four super CSIs in FIG. 5, the device 613, in the case where the base station 603 has a priority greater than the priorities of the base stations 601, 602, The coexistence signaling message is transmitted in the subsequent coexistence signaling transmission period (ie, within CX frames 33 to 256).
同样, 以基站 601、 602为例, 由于在 4个超 CSI结束时, 自己 的优先级(分别为 0和 1 ) 小于装置 603的优先级, 因此, 在随后的 共存信令发送时间段内,暂緩或者说暂停自己的共存信令消息的发送。 Similarly, taking the base stations 601 and 602 as an example, since the priorities (0 and 1 respectively) are smaller than the priority of the device 603 at the end of the four super CSIs, in the subsequent coexistence signaling transmission period, Suspend or suspend the transmission of its own coexistence signaling message.
装置 614被配置为:在 603基站选择的时间窗口内,如果基站 603 的优先级大于已经通过功率电平扫描获知的的其它基站(如 601 ) 的 优先级, 则基站 603发送预约信号, 如果基站 603的优先级小于这些 基站(如 601 ) 的优先级, 则基站 603暂緩发送预约信号, 并相应增 加其优先级。 这样的设置可以进一步避免预约信号在发送时可能引起 的冲突问题。 Apparatus 614 is configured to: within a time window selected by the 603 base station, if the priority of base station 603 is greater than the priority of other base stations (e.g., 601) that have been learned by power level sweeping, base station 603 transmits a reservation signal if the base station If the priority of 603 is less than the priority of these base stations (e.g., 601), the base station 603 suspends the transmission of the reservation signal and increases its priority accordingly. Such a setting can further avoid conflicting problems that may occur when the reservation signal is transmitted.
对于本领域技术人员而言, 图 6中只是提供了 IBS基站的一种可 能的功能构造。 根据本发明实施例的基站本身并不涉及硬件的改进, 可以在现有基站的基 上, 通过结合计算机软件方式来实现。 For those skilled in the art, only one possible functional configuration of the IBS base station is provided in FIG. The base station according to the embodiment of the present invention does not involve hardware improvement, and can be implemented on the basis of the existing base station by combining computer software.
尽管结合了实施例来描述本发明, 但是本发明并不局限于任何实 施例。 本发明的范围由权利要求书限定, 并且包括各种可选方式、 修 改和等效替换。 因此, 本发明的保护范围应当由所附的权利要求书的 内容确定。
Although the invention has been described in connection with the embodiments, the invention is not limited to any embodiments. The scope of the invention is defined by the claims, and includes various alternatives, modifications and equivalents. Therefore, the scope of the invention should be determined by the scope of the appended claims.
Claims
1. 一种在基站和至少一个其他基站之间进行频谱共享的方法,其 中, 所有基站分别属于不同的无线通信系统, 该方法包括: A method for performing spectrum sharing between a base station and at least one other base station, wherein all base stations belong to different wireless communication systems, and the method includes:
a. 所述基站和所述至少一个其他基站从多个预留时间窗口内分 别选择一个时间窗口,以准备发送预约信号和至少一个其他预约信号, 所述预约信号包含所述基站的优先级信息, 所述至少一个其他预约信 号包含所述至少一个其他基站的优先级信息; a. the base station and the at least one other base station respectively select a time window from a plurality of reserved time windows to prepare to transmit a reservation signal and at least one other reservation signal, the reservation signal including priority information of the base station The at least one other reservation signal includes priority information of the at least one other base station;
b. 所述基站获得所述至少一个其他预约信号中包含的优先级信 息, 并比较所述预约信号和所述至少一个其他预约信号中包含的优先 级; 以及 b. the base station obtains priority information included in the at least one other reservation signal, and compares priorities included in the reservation signal and the at least one other reservation signal;
c 在所述预约信号中包含的优先级大于所述至少一个其他预约 信号中包含的优先级的情况下, 所述基站在所述多个预留时间窗口之 后的共存信令发送时间段发送共存信令消息; 否则暂停所述共存信令 消息的发送。 c. In a case where the priority included in the reservation signal is greater than a priority included in the at least one other reservation signal, the base station transmits coexistence in a coexistence signaling transmission period after the plurality of reserved time windows Signaling message; otherwise suspend transmission of the coexistence signaling message.
2. 根据权利要求 1所述的方法, 其中, 步骤 b进一步包括所述基 站通过扫描所述至少一个其他基站选择的预留时间窗口的功率电平以 获得所述至少一个其他基站的优先级。 2. The method of claim 1, wherein step b further comprises the base station obtaining a priority of the at least one other base station by scanning a power level of a reserved time window selected by the at least one other base station.
3. 根据权利要求 1或 2所述的方法, 进一步包括: 在所述基站选 择的时间窗口内, 如果所述基站的优先级大于所述至少一个其他基站 的优先级, 则所述基站发送所述预约信号。 The method according to claim 1 or 2, further comprising: transmitting, in a time window selected by the base station, if a priority of the base station is greater than a priority of the at least one other base station, The reservation signal is described.
4. 根据权利要求 1或 2所述的方法, 进一步包括: 在所述基站选 择的时间窗口内, 如果所述基站的优先级小于所述至少一个其他基站 的优先级, 则所述基站暂緩发送所述预约信号。 The method according to claim 1 or 2, further comprising: in a time window selected by the base station, if the priority of the base station is less than the priority of the at least one other base station, the base station is suspended Sending the reservation signal.
5. 根据权利要求 1或 2所述的方法,其中基站的优先级取决于该 基站已经经历的共存信令消息的数量。 5. Method according to claim 1 or 2, wherein the priority of the base station depends on the number of coexistence signaling messages that the base station has experienced.
6. 根据权利要求 1或 2所述的方法,其中基站的优先级取决于该 基站的特定通信要求, 所述特定通信要求包括军事、 医疗或紧急通信 要求中的至少一个。 6. The method of claim 1 or 2, wherein the priority of the base station is dependent on a specific communication requirement of the base station, the specific communication requirement including military, medical or emergency communication At least one of the requirements.
7. 根据权利要求 1或 2所述的方法, 其中在步骤 c中, 如果暂停 所述共存信令消息的发送, 则所述基站的优先级增加 1。 The method according to claim 1 or 2, wherein in step c, if the transmission of the coexistence signaling message is suspended, the priority of the base station is increased by one.
8. 一种无线通信系统的基站, 所述基站与至少一个属于其他无线 通信系统的其他基站进行频谱共享, 所述基站包括: A base station of a wireless communication system, the base station performing spectrum sharing with at least one other base station belonging to another wireless communication system, the base station comprising:
a. 时间窗口选择装置, 用于从多个预留时间窗口内选择一个时间 窗口, 以准备发送预约信号, 其中所述预约信号包含所述基站的优先 级信息; a time window selecting means for selecting a time window from a plurality of reserved time windows to prepare to transmit a reservation signal, wherein the reservation signal includes priority information of the base station;
b. 优先级比较装置,用于获得所述其他基站发送的预约信号中包 含的优先级信息, 并将所述基站的优先级与所述其他基站的优先级进 行比较; 以及 a priority comparison device, configured to obtain priority information included in a reservation signal sent by the other base station, and compare a priority of the base station with a priority of the other base station;
c 共存信令发送控制装置, 用于在所述预约信号中包含的优先级 大于所述其他预约信号中包含的优先级的情况下, 在所述预留时间窗 口之后的共存信令发送时间段发送共存信令消息, 否则, 暂停所述共 存信令消息的发送。 a coexistence signaling transmission control apparatus, configured to: during a case where the priority included in the reservation signal is greater than a priority included in the other reservation signal, a coexistence signaling transmission period after the reserved time window The coexistence signaling message is sent, otherwise, the transmission of the coexistence signaling message is suspended.
9. 根据权利要求 8所述的基站,其中所述优先级比较装置进一步 被配置为通过扫描所述其它基站选择的预留时间窗口的功率电平以获 得所述其它基站的优先级。 9. The base station of claim 8, wherein the prioritization comparing means is further configured to obtain a priority of the other base station by scanning a power level of a reserved time window selected by the other base station.
10. 根据权利要求 8或 9所述的基站, 进一步包括预约信号发送 控制装置, 该装置被配置为: 在所述基站选择的时间窗口内, 如果所 级, 则所述基站发送所述预约信号, 如果所述基站的优先级小于所述 其它基站的优先级, 则所述基站暂緩发送所述预约信号, 并相应增加 其优先级. 10. The base station according to claim 8 or 9, further comprising a reservation signal transmission control device, the device being configured to: in a time window selected by the base station, if the level is, the base station transmits the reservation signal If the priority of the base station is less than the priority of the other base station, the base station suspends transmitting the reservation signal and increases its priority accordingly.
11. 根据权利要求 8或 9所述的基站, 其中, 所述基站的优先级 取决于该基站已经经历的共存信令消息的数量, 或者取决于该基站的 特定通信要求, 所述特定通信要求包括军事、 医疗或紧急通信要求中 的至少一个。 The base station according to claim 8 or 9, wherein the priority of the base station depends on the number of coexistence signaling messages that the base station has experienced, or depends on a specific communication requirement of the base station, the specific communication requirement Including military, medical or emergency communications requirements At least one of them.
12. 一种计算机程序产品,其中存储有用于执行权利要求 1-7任 一项的步骤的计算机指令。 12. A computer program product storing computer instructions for performing the steps of any of claims 1-7.
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