EP2396985A1 - Allocation de ressources radio pour coexistence et co-localisation geran-lte - Google Patents

Allocation de ressources radio pour coexistence et co-localisation geran-lte

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Publication number
EP2396985A1
EP2396985A1 EP09779031A EP09779031A EP2396985A1 EP 2396985 A1 EP2396985 A1 EP 2396985A1 EP 09779031 A EP09779031 A EP 09779031A EP 09779031 A EP09779031 A EP 09779031A EP 2396985 A1 EP2396985 A1 EP 2396985A1
Authority
EP
European Patent Office
Prior art keywords
radio access
access network
lte
frequency
radio
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP09779031A
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German (de)
English (en)
Inventor
Jari Yrjana Hulkkonen
Mikko Saily
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Nokia Solutions and Networks Oy
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Nokia Siemens Networks Oy
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Filing date
Publication date
Application filed by Nokia Siemens Networks Oy filed Critical Nokia Siemens Networks Oy
Publication of EP2396985A1 publication Critical patent/EP2396985A1/fr
Withdrawn legal-status Critical Current

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W16/00Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
    • H04W16/14Spectrum sharing arrangements between different networks
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/16Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]

Definitions

  • the present invention relates to the field of radio resource allocation between fourth-generation Evolved Universal Terrestrial Radio Access Networks (E-UTRANs) and second- generation radio access networks according to the GSM/EDGE standard (herein also referred to as GERANs) . More particularly, the invention proposes a method and mechanism which allows GERAN and LTE radio resource management to share the same spectrum allocation in both co-channels and adjacent channels. Thereby, GERAN scalability and LTE flexibility in time/frequency allocation enables efficient frequency sharing between the systems. This shared portion of the spectrum allocation is driven by a GSM Base Station System (BSS) Mobile Allocation (MA) procedure. Since GSM frequency hopping is a deterministic process, the occupied frequencies in the following frames can be predicted. According to the invention, LTE utilizes this information from GSM in the shared frequency area and thus avoids allocation of the occupied resource blocks (in frequency domain) during the duration of the next transmit time interval (in time domain) .
  • BSS Base Station System
  • MA Mobile Allocation
  • LTE Long Term Evolution
  • LTE has been designed to meet carrier needs for high-speed data and media transport as well as high-capacity voice support well into the next decade. It encompasses high-speed data, multimedia unicast and multimedia broadcast services.
  • LTE provides for an uplink speed of up to 50 megabits per second (Mbps) and a downlink speed of up to 100 Mbps .
  • Mbps megabits per second
  • Mbps downlink speed
  • Bandwidth will be scalable from 1.25 MHz to 20 MHz. This will suit the needs of different network operators that have different bandwidth allocations, and also allow operators to provide different services based on spectrum.
  • LTE is also expected to improve spectral efficiency in 3G networks, allowing carriers to provide more data and voice services over a given bandwidth.
  • E-UTRAN systems (sometimes also referred to as UTRAN LTE systems) aim at further reducing operator and end-user costs and improving service provisioning. Possible ways of reaching this target are to study ways to achieve reduced latency, to achieve higher user data rates, and to improve the system capacity and coverage.
  • One of the main novelties introduced for E-UTRAN in order to achieve these targets is the introduction of a new physical layer which applies Orthogonal Frequency Division Multiplexing (OFDM) for the downlink, thus allowing data to be directed to or from multiple users on a subcarrier-by-subcarrier basis for a specified number of symbol periods, and Single Carrier - Frequency Division Multiple Access (SC-FDMA) for the uplink.
  • OFDM Orthogonal Frequency Division Multiplexing
  • SC-FDMA Single Carrier - Frequency Division Multiple Access
  • An Evolved UTRAN system may either apply the frequency-division duplex (FDD) transmission mode or the time-division duplex (TDD) transmission mode.
  • FDD frequency-division duplex
  • TDD time-division duplex
  • the evolved UTRAN uses the same frequency band for both uplink and downlink communication. Thus, some time slots are reserved for the uplink while others are reserved for the downlink.
  • One time slot is assigned mandatory for the downlink, e.g. the first time slot in a radio frame. By reading control information in this time slot, the user equipment (UE) then knows the configuration of the other time slots, uplink or downlink .
  • High-level E-UTRAN systems shall be able to support two distinct deployment scenarios: standalone deployment scenarios and integrated scenarios together with coexisting GERAN networks.
  • the operator is having GERAN coverage in the same geographical area. It may thereby be the case that both networks and thus the network services and data traffic to be transferred via these networks are assigned adjacent carriers (see Fig. Ia) or even that allocated GERAN carriers are used for transferring LTE traffic in case an LTE service is requested (see Fig. Ib) .
  • E-UTRA operates on a flexible spectrum with a useable bandwidth of 1.25 MHz, 2.5 MHz, 5 MHz, 10 MHz, 15 MHz or 20 MHz, both in the uplink and downlink and in a paired and unpaired spectrum.
  • a useable bandwidth of 1.6 MHz is intended.
  • E-UTRA thereby supports co-existence (and co-location) with GERAN on adjacent channels, co-existence between operators on adjacent channels and co-existence on overlapping and/or adjacent spectrum at country borders. Thereby, all frequency bands should be allowed following release-independent frequency band principles.
  • Evolved Universal Terrestrial Radio Access which is the air interface of 3GPP' s LTE upgrade path for mobile networks and represents the successor to High-Speed Downlink Packet Access (HSDPA) and High-Speed Uplink Packet Access (HSUPA) technologies specified in 3GPP releases 5, 6 and 7, operates on a flexible spectrum in 1.25 MHz, 2.5 MHz, 5 MHz, 10 MHz, 15 MHz and 20 MHz in both the uplink and downlink as well as in paired and unpaired spectrum.
  • HSDPA High-Speed Downlink Packet Access
  • HSUPA High-Speed Uplink Packet Access
  • the DL synchronization signals are transmitted on sub-carriers, which are centred with respect to the BCH sub-carrier (see 3GPP TS 36.211 V8.4.0 (2008-09) Technical Specification, E-UTRAN, Physical Channels and Modulation, Release 8) .
  • GERAN on the other hand, which is an abbreviation for "GSM/EDGE Radio Access Network", is the radio part of GSM/EDGE together with the network that joins the base stations and base station controllers.
  • the standards for GERAN are maintained by the 3GPP (Third Generation Partnership Project) .
  • GERAN is a key part of GSM, and also of combined UMTS/GSM networks.
  • the network represents the core of a GSM network through which phone calls and packet data are routed from and to the public switched telephone network (PSTN) and Internet to and from subscriber handsets.
  • PSTN public switched telephone network
  • a mobile phone operator's network is comprised of one or more GERANs, coupled with UTRANs in the case of a UMTS/GSM network.
  • GERAN networks can be operated on 200 kHz resolution, and minimum resource allocation in LTE is 180 kHz.
  • Typical minimum frequency band allocation requirement to operate practical GERAN network is 5.0 to 7.5 MHz (or even 10 MHz), which at 5 MHz yields 12 carriers for the broadcast control channel BCCH (i.e., a BCCH reuse of 12) and 13 frequency hopping traffic carriers.
  • BCCH broadcast control channel
  • a severe problem consists in the fact that LTE specifies the co-existence and co-location with GERAN systems on adjacent channels (cf. 3GPP TR 25.913 V7.3.0 (2006-03) Technical Report, Requirements for Evolved UTRA (E-UTRA) and Evolved UTRAN (E-UTRAN), Release I) 1 which limits the inter-system capacity maximization and load balancing between GERAN and LTE (see Figs, la-c) .
  • QoS Quality of Service
  • LTE must be introduced to the same bandwidth with GERAN (see Fig. Ib) .
  • a significant capacity loss is seen on the GERAN side. In practice, this is not acceptable, and in most of the cases the majority of the traffic (especially voice) will remain in the GERAN network until the LTE user equipment penetration is high .
  • WCDMA will be also difficult to pair with LTE in limited operator spectrum allocations due to fixed 5 MHz spectrum allocation.
  • more than one radio access network e.g. GERAN and E-UTRAN
  • a first exemplary embodiment of the present application refers to a method for allocating requested radio resources for at least two coexisting and co- located radio access networks sharing the same frequency spectrum in an active radio cell.
  • said method comprises the steps of predicting a deterministic frequency occupancy for the allocated frequency spectrum of at least one first radio access network for several frames in advance and allocating at least one frequency band from the residual, unoccupied parts of the shared frequency spectrum for at least one second radio access network according to bandwidth requirements of said at least one second radio access network.
  • said at least one first radio access network may be given by a second-generation radio access network which operates based on the GSM/EDGE standard, and said at least one second radio access network may e.g. be a fourth- generation radio access network which operates based on the E-UTRAN standard.
  • the claimed method may thereby begin with the steps of entering a channel request and controlling the active radio cell such as to avoid co-channel interference between the at least two co-existing and co-located radio access networks. It may further be provided that the at least one first radio access network executes a resource block allocation procedure for allocating those radio resources which are requested by said first radio access network, wherein carrier allocation is adaptively changed based on a deterministic frequency hopping scheme. According to the present invention, the at least one second radio access network then calculates the frequency occupancy for the allocated frequency spectrum of the at least one first radio access network for several frames in advance. In case a channel resource request is received from the at least one second radio access network, said method may then be continued with the step of performing a channel selection and activation based upon the predicted frequency occupancy for the allocated frequency spectrum of the at least one first radio access network.
  • the channel resource request When the channel resource request is received from the at least one second radio access network, it is looked for available active channels in the shared frequency spectrum and the resource allocation of the at least one first radio access network is predicted by calculating the deterministic frequency occupancy for the allocated frequency spectrum of said at least one first radio access network for several frames in advance.
  • the shared resource pool as given by the shared frequency spectrum is updated by indicating new occupied and restricted channels of said at least one first radio access network before a set of resources as requested by said at least one second radio access network is allocated.
  • a traffic channel using the allocated set of resources as requested by said at least one second radio access network can be activated.
  • a second exemplary embodiment of the present application relates to a base transceiver station for allocating requested radio resources for at least two coexisting and co- located radio access networks sharing the same frequency spectrum in an active radio cell.
  • said base transceiver station may be configured for calculating a deterministic frequency occupancy for the allocated frequency spectrum of at least one first radio access network for several frames in advance and allocating at least one frequency band from the residual, unoccupied parts of the shared frequency spectrum for at least one second radio access network according to bandwidth requirements of said at least one second radio access network.
  • a third exemplary embodiment of the present application is directed to a computer program for executing a method as described above with reference to said first exemplary embodiment when being implemented and running on a base transceiver station as disclosed with reference to said second exemplary embodiment.
  • Figs, la-c show three schematic diagrams which illustrate three example of resource allocation between an LTE system and a GERAN system when introducing LTE services
  • Fig. 2 shows the LTE time and frequency domain structure for the downlink and uplink case
  • Fig. 3 shows the principle of a shared frequency resource area
  • Fig. 4 shows a schematic diagram for illustrating GERAN-LTE coexistence using shared resources
  • Fig. 5 shows a schematic diagram for illustrating GERAN-LTE coexistence in the downlink
  • Fig. 6 shows a schematic diagram for illustrating GERAN-LTE coexistence in the uplink
  • Fig. 7 shows a schematic diagram for illustrating GERAN-LTE interference control in a shared spectrum
  • Fig. shows the compatibility of GSM-LTE coexistence for the example of an LTE cell search
  • Figs. 9a+b show two schematic diagrams for exemplarily illustrating GSM-LTE coexistence based on variable, non-overlapping bandwidths
  • Figs. 10a+b show two schematic diagrams for exemplarily illustrating GSM-LTE coexistence based on shared bandwidths with LTE variable bandwidths using GSM resources.
  • Figs, la-c illustrate the above-mentioned problems concerning resource allocation between co-existing LTE- and co-located GERAN-based networks for an example with original 5.0 MHz allocation .
  • Fig. Ia a radio resource allocation scheme is shown where LTE-based services are assigned an additional frequency band (A) having a bandwidth of 2.5 MHz adjacent to a frequency band of 5.0 MHz which is provided for GERAN traffic with said 5.0 MHz band being sub-divided into 12 BCCH traffic carriers (referred to as "12 ARFN”) and 13 other carriers (referred to as "13 ARFN”) which can be used for frequency hopping purposes .
  • 12 ARFN BCCH traffic carriers
  • 13 ARFN 13 other carriers
  • FIG. Ib Another radio resource allocation scheme where only roaming GSM users using dedicated frequency bands for LTE-based services and GERAN traffic within said 5.0 MHz band are supported (scenario B) is shown in Fig. Ib.
  • scenario B Another radio resource allocation scheme where only roaming GSM users using dedicated frequency bands for LTE-based services and GERAN traffic within said 5.0 MHz band are supported (scenario B) is shown in Fig. Ib.
  • GERAN interference diversity is lost (as there is no dedicated hopping layer) , which means that the GERAN network is limited to the BCCH traffic.
  • a shared frequency band (C) for LTE-based services and GERAN traffic can be provided such as illustrated by the radio resource allocation scheme shown in Fig. Ic. Both systems implement mandatory common control channels.
  • a balanced traffic load can only be achieved by using a flexible shared spectrum (such as proposed by the present invention) .
  • FIG. 2 A schematic diagram showing the LTE time and frequency domain structure for the downlink and uplink case is depicted in Fig. 2.
  • LTE resource blocks having a size of 1.0 ms X 180 kHz are used.
  • LTE services partial radio frame allocation on GSM carriers would thus be possible.
  • the present invention proposes a method and mechanism which allows GERAN and LTE radio resource management to share the same spectrum allocation (see Figs. 3 and 4) in both co-channels and adjacent channels (see Figs. 5 and 6) .
  • other coexistence strategies for GERAN and LTE systems using the same band may be foreseen. It may e.g. be provided that GSM drives slow radio resource allocation on a TDMA frame basis.
  • both systems may have a common radio resource management (CRRM) - also referred to as "inter-system RRM” - by using an inter-system DFCA (dynamic frequency and channel allocation) .
  • CRRM radio resource management
  • inter-system RRM inter-system DFCA
  • Another coexistence strategy may be given by dynamic BCH offset assignment and dynamic BCH/BCCH allocation.
  • GERAN and LTE may be allocated to the same operator frequency bandwidth, e.g. to a bandwidth between 5 MHz and 10 MHz.
  • a common shared portion of the overall spectrum is configured and available for the traffic channels.
  • Both systems may thereby be provided with practical minimum dedicated bandwidth allocation for the broadcast control channel (BCCH) and the broadcast channel (BCH) .
  • This shared portion of the spectrum allocation is driven by a GSM Base Station System (BSS) Mobile Allocation (MA) procedure. Since GSM frequency hopping is a deterministic process, the occupied frequencies in the following frames can be predicted.
  • LTE utilizes this information from GSM in the shared frequency area and avoids allocation of the occupied resource blocks (in frequency domain) during the duration of the next transmit time interval (in time domain) .
  • an inter-system interference control may be provided which may be configured as an extension to the scaled inter-cell interference values of a common background interference matrix (BIM) .
  • BIM background interference matrix
  • FIG. 7 shows the shared spectrum between LTE and GERAN and illustrates an example for inter-cell interference management for a total bandwidth of 10 MHz where in two radio cells (cells 100 and 101) a bandwidth of 7.5 MHz is allocated to the GERAN system and a bandwidth of 2.5 MHz is allocated to the LTE system, whereas in two other radio cells (cells 110 and 111) a bandwidth of 5.0 MHz is allocated to the GERAN system and a bandwidth of 5.0 MHz is allocated to the LTE system.
  • this scenario requires the use of a shared spectrum and an effective inter-cell interference management between these two systems such as proposed in the scope of the present application.
  • Fig. 8 shows the compatibility of GSM-LTE coexistence for the example of an LTE cell search in a scenario where a 10-MHz user equipment (UE) is located in a 20-MHz cell site with mandatory BCH and SCH common control channels occupying an SCH (synchronization channel) bandwidth of 1.25 MHz and a BCH (broadcast channel) bandwidth of 1.25 MHz.
  • said radio resource is multiplexed in frequency domain. While spectrum assignment comes from the GSM system, the LTE system has the freedom to allocate resources outside the current active GSM MA lists.
  • a cell search (step a) is initiated using a synchronization channel SCH.
  • a BCH signal is received.
  • the UE shifts to the center carrier frequency assigned by the system and initiates a data transmission (step c) .
  • Figs. 9a+b two schematic diagrams for exemplarily illustrating GSM-LTE coexistence based on variable, non- overlapping bandwidths are shown. If GSM voice quality is good, only GSM carriers 1 to 8 are used for frequency hopping (FH) . The remaining carriers of the spectrum can be used for LTE traffic. As can be seen from Fig.
  • GSM data are allocated to the BCCH, and GSM voice data are allocated to the BCCH and GSM frequency hopping layer.
  • GSM radio resource management thereby minimizes the usage of hopping frequencies.
  • There are several ways to control the hopping list in GSM e.g. by means of a DFCA algorithm or by using MAIO (mobile allocation index offset) parameters.
  • MAIO mobile allocation index offset
  • FIGs. 10a+b Two schematic diagrams for exemplarily illustrating GSM-LTE coexistence based on shared bandwidths with LTE variable bandwidths using GSM resources are shown in Figs. 10a+b.
  • GSM data are allocated to the BCCH
  • GSM voice data are allocated to the BCCH and GSM frequency hopping layer such as in the scenario of Fig. 9a.
  • LTE band is variable, all free resources from GSM can be used by LTE.
  • Fig. 10b it can be taken that LTE uses the carriers inside the GSM spectrum. If there is a free GSM carrier inside the GSM hopping list, LTE can use this resource (see Fig. 10b) .
  • LTE For GSM-LTE coexistence there are spectrum deployment requirements for LTE, which comprise co-existence in the same geographical area and co-location with GERAN/3G on adjacent channels. When these adjacent channels are part of the GSM bandwidth, it will be possible to also allocated co-channels. As a result, it will be possible to co-exist and co-site GSM and LTE transceivers which share the same bandwidth and are allocated on co-channel and adjacent carriers.
  • the network load for each system is monitored using RRM tools or key performance indicators. For example, average reception quality for wireless speech connections can indicate that the network on the GERAN side is not heavily loaded and less frequency resources are needed for GERAN such that LTE can gain more resources.
  • Radio Resource Allocation baseline procedure is based on the following baseline requirements: 1. GSM allocation and frequency reuse configured and available, 2. LTE bandwidth allocation excludes GSM BCCH, 3. LTE BCH bandwidth is dedicated to LTE, and 4. shared spectrum configured and available. Optionally, an inter-system interference control is configured and available.
  • channel allocation and assignment may be carried out as follows: When a channel request is entered to the system (step Sl), free resource blocks in a shared area in frequency domain are available for both (GERAN- and LTE- based) systems. An inter-System Radio Resource allocation process then controls the own cell and avoids co-channel interference between co-locating systems (step S2) . After that, the GSM system drives the resource block allocation. Thereby, GSM channel activation or deactivation changes the mobile allocation adaptively depending on the load, quality and available resources (step S3) . The LTE system then calculates the GSM frequency occupancy for several frames in advance, and therefore avoids the carriers being occupied by GSM traffic channels in the own cell (step S4) .
  • step S5 a channel selection and activation (step S5) when channel resource request is received.
  • a resource is requested for the GSM system
  • a normal resource allocation is carried out (step S5a (i) ) , e.g. by physical layer parameters for mobile allocation.
  • GSM data are prioritized on a dedicated BCCH channel.
  • the shared resource pool as given by the shared frequency spectrum is updated by indicating new occupied and restricted channels (step S5a (ii) ) .
  • available active channels are looked for in the shared resource area (step S5b (i) ) .
  • step S5b (ii) GSM Mobile Allocation for the next following transmit time intervals are predicted (step S5b (ii) ) and the shared resource pool indicating new occupied and restricted channels is updated (step S5b (iii) ) .
  • the proposed method is then continued with the steps of allocating the set of resources as requested, e.g. according to quality of service (QoS) requirements (step S6) , Updating the shared resource pool indicating new occupied and restricted channels (step S7) and activating a traffic channel (step S8) .
  • QoS quality of service
  • the operator frequency bandwidth can remain fully occupied after LTE roll-out, thus maximizing the multi- mode spectral efficiency and investment to the network and licensed spectrum.
  • Capacity and traffic mix can be tuned for each sector and site independently, when the systems are co-sited.
  • Capacity and traffic mix can be adaptively modified based on the network load, RRM QoS measurements, busy hour control, or some other criteria.
  • the applied frequency hopping sequence is deterministic and defined at the channel allocation for both base station and mobile station. Therefore, LTE can be aware of the GSM resource allocations on a timeslot/frame basis .
  • the proposed method is compatible with the LTE cell search algorithm and frame structure (both structure in time and frequency) and is also compatible with different LTE frequency band allocations.
  • the proposed method is compatible with the downlink reference signal (s) (channel-quality measurements, channel estimation for coherent demodulation/detection at the UE, cell search and initial acquisition) .
  • s downlink reference signal
  • Antenna line and installation can be shared between the systems, or dedicated antenna and radio equipment can be used.
  • GERAN is flexible, and frequencies can be allocated at 200 kHz accuracy.
  • a service deployment can be configured where GSM is used as a coverage layer, and LTE makes a handover to GSM when there is a coverage problem.
  • the GSM coverage layer can be optimized, while LTE can maintain the best possible Quality of Service, since the bandwidth is not wasted for two adjacent systems.
  • LTE carrier spacing is 180 kHz
  • carrier spacing is 200 kHz. Therefore, LTE is not able to fully utilize free resources in the shared band.
  • This limitation can be overcome partly by sharing only those carriers which match with the different carrier spacing by a common factor (see Fig. 4) .
  • frequency reuse is applied. For example, in case of a reuse factor of 1/3, only every third GSM carrier is used in a cell.
  • usage of GSM radio resources varies based on traffic load and requested quality of service. As exemplarily shown in Fig. 4, a cell may use GSM carriers 1,
  • LTE resource blocks 1, 4, 5, 8 to 18 and 21 to 25 are used resource blocks 1, 4, 5, 8 to 18 and 21 to 25. This means that LTE resource blocks 1, 4,
  • Another disadvantage is that GSM and LTE are not fully compatible in time domain due to different numerology in the frame structures. TDMA frame and radio frame synchronization can not be achieved easily. This limitation can be overcome partly by having a radio resource management which keeps track on both frame structures using a common system clock.

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Mobile Radio Communication Systems (AREA)

Abstract

La présente invention porte sur le domaine de l'allocation de ressource radio entre des réseaux d'accès radio terrestre universel évolué (E-UTRAN) de quatrième génération et des réseaux d'accès radio de deuxième génération conformes à la norme GSM/EDGE (également appelés réseaux GERAN dans l'invention). En particulier, l'invention porte sur un procédé et un mécanisme qui permettent une gestion de ressources radio GERAN et LTE pour partager la même allocation spectrale à la fois dans le même canal et dans des canaux adjacents.
EP09779031A 2009-02-10 2009-02-10 Allocation de ressources radio pour coexistence et co-localisation geran-lte Withdrawn EP2396985A1 (fr)

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CN112996004A (zh) * 2019-12-02 2021-06-18 中兴通讯股份有限公司 资源的确定方法、装置、存储介质及电子装置

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