WO2015027811A1 - 多载波组网的移动测量方法、网络侧设备和用户设备 - Google Patents

多载波组网的移动测量方法、网络侧设备和用户设备 Download PDF

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Publication number
WO2015027811A1
WO2015027811A1 PCT/CN2014/084005 CN2014084005W WO2015027811A1 WO 2015027811 A1 WO2015027811 A1 WO 2015027811A1 CN 2014084005 W CN2014084005 W CN 2014084005W WO 2015027811 A1 WO2015027811 A1 WO 2015027811A1
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Prior art keywords
carrier
frequency measurement
event
set corresponding
monitoring
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PCT/CN2014/084005
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English (en)
French (fr)
Inventor
杨毅
周涵
花梦
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华为技术有限公司
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Publication of WO2015027811A1 publication Critical patent/WO2015027811A1/zh

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports

Definitions

  • the present invention relates to communications technologies, and in particular, to a mobile measurement method, a network side device, and a user equipment of a multi-carrier networking. Background technique
  • FIG. 1 is a schematic diagram of the structure of a heterogeneous network.
  • the network includes a macro station (Macro Node B) and a small coverage station (Pico Node B), and the downlink coverage of the cell is determined by the downlink transmission power of the cell.
  • the coverage of the macro station is represented by F2
  • the coverage of the micro station is represented by F1
  • the coverage of the macro station and the micro station overlap.
  • the area where the user equipment (User Equipment, UE for short) is located is obtained by using the mobile measurement to configure an optimal serving cell.
  • User Equipment User Equipment
  • a multi-carrier networking may be adopted, and both a macro cell and a micro cell are configured with a downlink dual carrier, which is called a primary carrier and a secondary carrier.
  • a primary carrier and a secondary carrier a downlink dual carrier
  • an active set is established on the downlink primary carrier and the secondary carrier respectively, and the UE performs the same-frequency measurement according to the two active sets, and reports the same-frequency measurement event.
  • the active set (abbreviated as active set) is a set of cells, and a radio link (Radio Link, RL for short) exists between the cell in the active set and the UE, and the RL includes an uplink (uplink) and a downlink (referred to as uplink). Downl ink).
  • a first aspect of the present invention provides a mobile measurement method for multi-carrier networking to solve the defects in the prior art and reduce network complexity.
  • Another aspect of the present invention is to provide a network side device and a user equipment to solve the defects in the prior art and reduce network complexity.
  • a first aspect of the present invention provides a mobile measurement method for multi-carrier networking, including: a network side device performing a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration on a user equipment UE, so that the Obtaining, by the UE, the monitoring set corresponding to the first carrier according to the first carrier co-frequency measurement configuration, acquiring the monitoring set corresponding to the second carrier according to the second carrier co-frequency measurement configuration, and starting monitoring for the first carrier And collecting, by the same carrier, the first carrier of the active set corresponding to the preset first carrier, and generating a first carrier intra-frequency measurement event, and starting a second set of cells for the monitoring set corresponding to the second carrier The carrier is measured in the same frequency to generate a second carrier intra-frequency measurement event; wherein, the UE has a radio link connection with each cell in the active set, and no radio link is connected to each cell in the monitoring set;
  • the network side device acquires a first carrier intra-frequency measurement event and a second carrier co-frequency measurement event reported by the UE on the first carrier.
  • the foregoing aspect and any possible implementation manner further provide an implementation manner, where the network side device performs the first carrier co-frequency measurement configuration and the second carrier co-frequency measurement configuration on the UE, including:
  • the network side device performs a first carrier on-frequency measurement configuration on the UE, so that the UE starts, according to the first carrier intra-frequency measurement configuration, a monitoring set corresponding to the first carrier and a preset first carrier.
  • the first carrier of the corresponding active set of cells is measured in the same frequency;
  • the network-side device After acquiring the first carrier intra-frequency measurement event reported by the UE, the network-side device performs a second carrier-on-frequency measurement configuration on the UE, so that the UE starts according to the second carrier co-frequency measurement configuration.
  • a second carrier intra-frequency measurement is performed on a set of cells including a monitoring set corresponding to the second carrier.
  • the foregoing aspect and any possible implementation manner further provide an implementation manner, where the network side device performs the first carrier co-frequency measurement configuration and the second carrier co-frequency measurement configuration on the UE, including:
  • the network side device performs a first carrier on-frequency measurement configuration on the UE, so that the UE starts the monitoring set and the preset corresponding to the first carrier according to the first carrier intra-frequency measurement configuration.
  • the first carrier of the cell set of the active set corresponding to one carrier is measured in the same frequency;
  • the network side device performs a second carrier intra-frequency measurement configuration on the UE before acquiring the first carrier intra-frequency measurement event reported by the UE, so that the UE starts when reporting the first carrier intra-frequency measurement event.
  • the first carrier intra-frequency measurement configuration includes: the network side device sends the measurement control information of the first carrier and the monitoring set corresponding to the first carrier to the UE, where the measurement control information of the first carrier includes the first The reporting condition of the carrier frequency measurement event;
  • the network side device performs the second carrier co-frequency measurement configuration on the UE, where the network side device sends the second carrier measurement control information and the second carrier corresponding monitoring set to the UE, the second The measurement control information of the carrier includes a reporting condition of the second carrier co-frequency measurement event.
  • first carrier is a primary carrier
  • second carrier is a secondary carrier
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: la event, lb At least one of an event, an lc event, an Id event, a le event, and an If event.
  • Another aspect of the present invention provides a mobile measurement method for a multi-carrier networking, including: receiving, by a user equipment UE, a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration from a network-side device;
  • the UE starts the first carrier intra-frequency measurement for the cell set including the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and generates a first carrier intra-frequency measurement event, and starts to include the Generating the second carrier co-frequency measurement event of the second set of the cell set of the monitoring set corresponding to the second carrier, where the second carrier co-frequency measurement event is generated, where the UE has a radio link connection with each cell in the active set, and There is no wireless link connection in each cell in the monitoring set;
  • the UE reports the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event to the network side device on the first carrier.
  • the UE starts a first carrier intra-frequency measurement for a cell set that includes a monitoring set corresponding to the first carrier and an active set corresponding to the preset first carrier, and generates a first carrier intra-frequency measurement event, and the The second carrier of the monitoring set of the second carrier corresponds to the second carrier, and the second carrier of the same frequency measurement event includes:
  • the UE After receiving the first carrier intra-frequency measurement configuration from the network side device, the UE starts, according to the first carrier intra-frequency measurement configuration, a monitoring set corresponding to the first carrier and a preset first carrier. A first carrier of the set of cells of the active set is measured in the same frequency to generate a first carrier intra-frequency measurement event;
  • the second carrier Receiving, by the network side device, the first carrier intra-frequency measurement event, the second carrier receiving the same-frequency measurement configuration from the network-side device, and starting, according to the second carrier, the same-frequency measurement configuration
  • the second carrier of the set of cells of the monitoring set corresponding to the second carrier is measured in the same frequency to generate a second carrier intra-frequency measurement event.
  • the UE starts a cell set for an active set that includes a monitoring set corresponding to the first carrier and a preset first carrier.
  • the first carrier co-frequency measurement event is generated, and the first carrier co-frequency measurement event is generated, and the second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started, and the generating the second carrier co-frequency measurement event includes:
  • the UE After receiving the first carrier intra-frequency measurement configuration from the network side device, the UE starts, according to the first carrier intra-frequency measurement configuration, a monitoring set corresponding to the first carrier and a preset first carrier. A first carrier of the set of cells of the active set is measured in the same frequency to generate a first carrier intra-frequency measurement event;
  • the UE receives the second carrier co-frequency measurement configuration from the network side device before reporting the first carrier intra-frequency measurement event to the network side device, and starts to report the first carrier co-frequency measurement event
  • the second carrier of the set of cells of the monitoring set corresponding to the two carriers is measured in the same frequency to generate a second carrier intra-frequency measurement event.
  • the UE receiving the first carrier intra-frequency measurement configuration from the network side device includes: receiving, by the UE, the network side device The measurement control information of the first carrier and the monitoring set corresponding to the first carrier, the measurement control information of the first carrier includes a reporting condition of a first carrier intra-frequency measurement event;
  • the two carrier intra-frequency measurement configuration includes: the UE receiving The measurement control information of the second carrier delivered by the network side device and the monitoring set corresponding to the second carrier, and the measurement control information of the second carrier includes a reporting condition of the second carrier intra-frequency measurement event.
  • first carrier is a primary carrier
  • second carrier is a secondary carrier
  • the initiating the second carrier intra-frequency measurement for the cell set including the monitoring set corresponding to the second carrier includes:
  • the UE initiates a cell set for the monitoring set corresponding to the second carrier.
  • the second carrier is measured in the same frequency.
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: la event, lb At least one of an event, an lc event, an Id event, a le event, and an If event.
  • a network side device including:
  • a configuration unit configured to perform a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration on the user equipment UE, so that the UE acquires a monitoring set corresponding to the first carrier according to the first carrier intra-frequency measurement configuration, Obtaining, according to the second carrier co-frequency measurement configuration, a monitoring set corresponding to the second carrier, and starting a first carrier that is a set of cells that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier.
  • Frequency measurement generating a first carrier co-frequency measurement event, starting a second carrier co-frequency measurement for a cell set including a monitoring set corresponding to the second carrier, generating a second carrier co-frequency measurement event; wherein, the UE and the UE Each cell in the active set has a radio link connection, and there is no radio link connection with each cell in the monitoring set;
  • an acquiring unit configured to acquire a first carrier intra-frequency measurement event and a second carrier co-frequency measurement event reported by the UE on the first carrier.
  • the configuration unit is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE is configured according to the first carrier
  • the intra-frequency measurement configuration starts the first carrier intra-frequency measurement for the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and is specifically configured to acquire the After the first carrier intra-frequency measurement event reported by the UE, performing a second carrier intra-frequency measurement configuration on the UE, so that the UE starts the pair according to the second carrier co-frequency measurement configuration.
  • the second carrier is measured in the same frequency as the set of cells including the monitoring set corresponding to the second carrier.
  • the configuration unit is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE is configured according to the first carrier
  • the intra-frequency measurement configuration starts the first carrier intra-frequency measurement for the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and is specifically configured to acquire the Performing a second carrier co-frequency measurement configuration on the UE before the first carrier intra-frequency measurement event reported by the UE, so that the UE starts to correspond to the second carrier when reporting the first carrier co-frequency measurement event
  • the second carrier of the set of cells of the set is monitored in the same frequency.
  • the configuration unit is specifically configured to send, to the UE, measurement control information of a first carrier and monitoring corresponding to the first carrier
  • the measurement control information of the first carrier includes a reporting condition of the first carrier co-frequency measurement event, and is specifically configured to send, to the UE, measurement control information of the second carrier and a monitoring set corresponding to the second carrier.
  • the measurement control information of the second carrier includes a reporting condition of the second carrier intra-frequency measurement event.
  • first carrier is a primary carrier
  • second carrier is a secondary carrier
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: la event, lb At least one of an event, an lc event, an Id event, a le event, and an If event.
  • a further aspect of the present invention provides a user equipment UE, including:
  • a receiving unit configured to receive a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration from the network side device;
  • An acquiring unit configured to acquire a monitoring set corresponding to the first carrier according to the first carrier co-frequency measurement configuration, and acquire a monitoring set corresponding to the second carrier according to the second carrier intra-frequency measurement configuration;
  • a measuring unit configured to start a first carrier intra-frequency measurement for a cell set that includes a monitoring set corresponding to the first carrier and an active set corresponding to a preset first carrier, generate a first carrier co-frequency measurement event, and start a second carrier co-frequency measurement event is generated by the second carrier of the cell set of the monitoring set corresponding to the second carrier, where the second carrier co-frequency measurement event is generated, where the UE has a radio link connection with each cell in the active set, and Each cell in the monitoring set has no wireless link connection;
  • a reporting unit configured to report, by using the first carrier, the same carrier frequency on the first carrier The measurement event and the second carrier co-frequency measurement event.
  • the measuring unit is specifically configured to: after the receiving unit receives the first carrier intra-frequency measurement configuration from the network side device, according to the The first carrier co-frequency measurement configuration starts the first carrier co-frequency measurement for the cell set including the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and generates a first carrier co-frequency measurement event. ;
  • the receiving unit is configured to: after the reporting unit reports the first carrier co-frequency measurement event to the network side device, receive a second carrier co-frequency measurement configuration from the network side device, where the measuring unit is specifically used And generating, according to the second carrier co-frequency measurement configuration, a second carrier co-frequency measurement for a cell set including a monitoring set corresponding to the second carrier, to generate a second carrier co-frequency measurement event.
  • the measuring unit is specifically configured to: after the receiving unit receives the first carrier intra-frequency measurement configuration from the network side device, according to the The first carrier co-frequency measurement configuration starts the first carrier co-frequency measurement for the cell set including the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and generates a first carrier co-frequency measurement event. ;
  • the receiving unit is configured to: before the reporting unit reports the first carrier intra-frequency measurement event to the network side device, receive a second carrier intra-frequency measurement configuration from the network-side device, and report the first to the reporting unit.
  • the second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started, and the second carrier co-frequency measurement event is generated.
  • the receiving unit is specifically configured to receive measurement control information of the first carrier delivered by the network side device, and the first carrier Corresponding monitoring set, the measurement control information of the first carrier includes a reporting condition of a first carrier co-frequency measurement event, and is specifically configured to receive measurement control information of the second carrier delivered by the network side device, and the The monitoring set corresponding to the second carrier, the measurement control information of the second carrier includes a reporting condition of the second carrier co-frequency measurement event.
  • first carrier is a primary carrier
  • second carrier is a secondary carrier
  • the measurement unit is specifically configured to be in a cell of the second carrier at a serving station where a current serving cell is located The coverage is different from the cell coverage of the first carrier, and the second carrier intra-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started.
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: la event, lb At least one of an event, an lc event, an Id event, a le event, and an If event.
  • a network side device including:
  • a transmitter configured to perform a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration on the user equipment UE, so that the UE acquires a monitoring set corresponding to the first carrier according to the first carrier intra-frequency measurement configuration, Obtaining, according to the second carrier co-frequency measurement configuration, a monitoring set corresponding to the second carrier, and starting a first carrier that is a set of cells that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier.
  • Frequency measurement generating a first carrier co-frequency measurement event, starting a second carrier co-frequency measurement for a cell set including a monitoring set corresponding to the second carrier, generating a second carrier co-frequency measurement event; wherein, the UE and the UE Each cell in the active set has a radio link connection, and there is no radio link connection with each cell in the monitoring set;
  • a receiver configured to acquire a first carrier intra-frequency measurement event and a second carrier co-frequency measurement event reported by the UE on the first carrier;
  • a bus is coupled to the transmitter and the receiver for data exchange between the transmitter and the receiver.
  • the transmitter is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE is configured according to the first carrier
  • the intra-frequency measurement configuration starts the first carrier intra-frequency measurement for the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and is specifically configured to acquire the
  • the second carrier-on-frequency measurement configuration is performed on the UE, so that the UE starts to correspond to the second carrier according to the second carrier co-frequency measurement configuration.
  • the second carrier of the set of cells of the set is monitored in the same frequency.
  • the transmitter is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE is configured according to the first carrier
  • the intra-frequency measurement configuration starts the first carrier intra-frequency measurement for the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and is specifically configured to acquire the Before the first carrier co-frequency measurement event reported by the UE, performing second on the UE
  • the carrier co-frequency measurement is configured to enable the UE to initiate a second carrier intra-frequency measurement for a cell set including the monitoring set corresponding to the second carrier when reporting the first carrier intra-frequency measurement event.
  • the transmitter is specifically configured to send, to the UE, measurement control information of a first carrier and monitoring corresponding to the first carrier
  • the measurement control information of the first carrier includes a reporting condition of the first carrier co-frequency measurement event, and is specifically configured to send, to the UE, measurement control information of the second carrier and a monitoring set corresponding to the second carrier.
  • the measurement control information of the second carrier includes a reporting condition of the second carrier intra-frequency measurement event.
  • first carrier is a primary carrier
  • second carrier is a secondary carrier
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: la event, lb At least one of an event, an lc event, an Id event, a le event, and an If event.
  • a further aspect of the present invention provides a user equipment UE, including:
  • a receiver configured to receive a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration from a network side device
  • a first processor configured to acquire a monitoring set corresponding to the first carrier according to the first carrier co-frequency measurement configuration, and acquire a monitoring set corresponding to the second carrier according to the second carrier intra-frequency measurement configuration;
  • a second processor configured to start a first carrier intra-frequency measurement for a cell set that includes a monitoring set corresponding to the first carrier and an active set corresponding to a preset first carrier, to generate a first carrier intra-frequency measurement event, And a second carrier co-frequency measurement event is generated for the second carrier-synchronous measurement of the cell set that includes the monitoring set corresponding to the second carrier, where the UE has a radio link connection with each cell in the active set. , having no wireless link connection with each cell in the monitoring set;
  • a transmitter configured to report, on the first carrier, a first carrier co-frequency measurement event and a second carrier co-frequency measurement event to the network side device;
  • a bus connected to the receiver, the first processor, the second processor, and the transmitter, for the receiver, the first processor, the second processor, and the Data exchange between the transmitters.
  • the second processor is specifically configured to receive, at the receiver, a first carrier from a network side device After the same frequency measurement configuration, the first carrier co-frequency measurement for the cell set including the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier is started according to the first carrier intra-frequency measurement configuration, Generating a first carrier intra-frequency measurement event;
  • the receiver is specifically configured to: after the transmitter reports the first carrier co-frequency measurement event to the network side device, receive a second carrier co-frequency measurement configuration from the network side device, where the second processor Specifically, the second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started according to the second carrier co-frequency measurement configuration, and the second carrier co-frequency measurement event is generated.
  • the second processor is specifically configured to: after the receiver receives the first carrier intra-frequency measurement configuration from the network side device, And performing, according to the first carrier co-frequency measurement configuration, a first carrier co-frequency measurement for a cell set that includes a monitoring set corresponding to the first carrier and an active set corresponding to a preset first carrier, and generates a first carrier co-frequency Measuring events;
  • the receiver is configured to receive a second carrier co-frequency measurement configuration from the network side device, and report the first on the transmitter, before the transmitter reports the first carrier co-frequency measurement event to the network side device.
  • the carrier is the same frequency measurement event
  • the second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started, and the second carrier co-frequency measurement event is generated.
  • the receiver is specifically configured to receive measurement control information of the first carrier delivered by the network side device, and the first carrier Corresponding monitoring set, the measurement control information of the first carrier includes a reporting condition of a first carrier co-frequency measurement event, and is specifically configured to receive measurement control information of the second carrier delivered by the network side device, and the The monitoring set corresponding to the second carrier, the measurement control information of the second carrier includes a reporting condition of the second carrier co-frequency measurement event.
  • first carrier is a primary carrier
  • second carrier is a secondary carrier
  • the foregoing aspect and any possible implementation manner further provide an implementation manner, where the second processor is specifically configured to: at a serving site where a current serving cell is located, a cell coverage of the second carrier When the cell coverage of the first carrier is different, the second carrier intra-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started.
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes at least one of a la event, a lb event, an lc event, an Id event, a le event, and an If event.
  • the network side device performs the first carrier co-frequency measurement configuration and the second carrier co-frequency measurement configuration on the UE, and the UE performs the first carrier with the monitoring set corresponding to the first carrier and the active set corresponding to the first carrier. Frequency measurement, performing the second carrier intra-frequency measurement on the monitoring set corresponding to the second carrier, and reporting the same-frequency measurement events for the first carrier and the second carrier, respectively.
  • the uplink carrier corresponding to the second carrier does not need to be set, and the UE only A unique uplink carrier needs to be set, and the first carrier co-frequency measurement event and the second carrier co-frequency measurement event are reported on the uplink carrier, thereby reducing network complexity.
  • 1 is a schematic structural view of a heterogeneous network
  • FIG. 2a is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 1 of the present invention
  • FIG. 2B is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 2 of the present invention
  • FIG. 4 is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 4 of the present invention.
  • FIG. 5 is a schematic structural diagram of a network side device according to Embodiment 5 of the present invention.
  • FIG. 6 is a schematic structural diagram of a user equipment according to Embodiment 6 of the present invention.
  • FIG. 7 is a schematic structural diagram of a network side device according to Embodiment 7 of the present invention.
  • FIG. 8 is a schematic structural diagram of a user equipment according to Embodiment 8 of the present invention.
  • the technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. example. Based on the embodiments of the present invention, those of ordinary skill in the art are not doing All other embodiments obtained under the premise of creative labor are within the scope of the invention.
  • two downlink carriers are deployed in the communication system networking.
  • the SP a first carrier and a second carrier, and the two downlink carriers are associated with one uplink carrier.
  • the first serving station forms a first cell when operating on the first carrier, and the UE communicates with the first serving site through the first cell.
  • the first carrier may be a primary carrier
  • the second carrier may be a secondary carrier.
  • FIG. 2a is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 1 of the present invention. As shown in Figure 1, the method includes the following process.
  • Step 101 The network side device performs a primary carrier co-frequency measurement configuration and a secondary carrier co-frequency measurement configuration on the UE.
  • the network side device performs a primary carrier co-frequency measurement configuration and a secondary carrier co-frequency measurement configuration on the UE, so that the UE acquires a monitoring set corresponding to the primary carrier according to the primary carrier intra-frequency measurement configuration, according to the
  • the secondary carrier equal-frequency measurement configuration acquires a monitoring set corresponding to the secondary carrier, and starts a primary carrier co-frequency measurement for the cell set including the monitoring set corresponding to the primary carrier and the active set corresponding to the preset primary carrier, and generates a primary carrier.
  • the frequency measurement event starts a secondary carrier intra-frequency measurement for a set of cells including the monitoring set corresponding to the secondary carrier, and generates a secondary carrier intra-frequency measurement event.
  • an active set (abbreviated as active set) is a set of cells, and an RL exists between the active set cell and the UE, and the RL includes an uplink and a downlink.
  • the monitoring set is a list of cells continuously measured by the UE.
  • the received signal code power (Received Signal Code Power, RSCP) or the average chip energy (Ec/NO) value of the monitored cell pilot is not yet strong enough to be activated. set.
  • the monitoring set corresponding to the primary carrier and the monitoring set corresponding to the secondary carrier are independent of each other.
  • Step 102 The network side device acquires a primary carrier co-frequency measurement event and a secondary carrier co-frequency measurement event reported by the UE on the primary carrier.
  • the network side device acquires the primary carrier co-frequency measurement event and the secondary carrier co-frequency measurement event reported by the UE, so that the network side device can be in the multi-carrier group according to the event reported by the UE.
  • the UE is mobility managed under the network.
  • the intra-frequency measurement event may include at least one of the following events: la event, lb event, lc event, Id event, le event, If event.
  • the la event is used to add an active set cell, and the measured value of the cell outside an active set is better than the report. Report the range, triggering the la event.
  • the lb event is used to delete the active set cell. When the measured value of the cell in an active set is worse than the reporting range, the lb event is triggered.
  • the lc event is used to replace the active out-of-set cell with the active set cell. When the measured value of an active set-out cell is better than that of an active set, the lc event is triggered.
  • the Id event is used to update the active set optimal cell, and when the optimal cell changes, the Id event is triggered.
  • a le event is triggered, wherein the absolute threshold can be specified by the network side. If the measured value of a cell is worse than an absolute threshold, an If event is triggered, wherein the absolute threshold can be specified by the network side.
  • the network side device performs the primary carrier co-frequency measurement configuration and the secondary carrier co-frequency measurement configuration on the UE, so that the monitoring set corresponding to the primary carrier and the active set corresponding to the preset primary carrier are configured by the UE.
  • the primary carrier is measured at the same frequency
  • the secondary carrier is measured on the secondary carrier corresponding to the secondary carrier, and the same frequency measurement event for the primary carrier and the secondary carrier is reported separately. Since only the active set is configured on the primary carrier, and only the monitoring set is used on the secondary carrier, and the cell in the monitoring set does not need to establish an RL connection with the UE, the uplink carrier corresponding to the secondary carrier does not need to be set, and the UE only needs to be uniquely set.
  • the uplink carrier, the primary carrier co-frequency measurement event and the secondary carrier co-frequency measurement event are reported on the uplink carrier, thereby reducing the complexity of the network.
  • FIG. 2b is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 2 of the present invention. As shown in Figure 2, the method includes the following process.
  • Step 201 The UE receives a primary carrier co-frequency measurement configuration and a secondary carrier co-frequency measurement configuration from a network side device.
  • Step 202 The UE acquires a monitoring set corresponding to the primary carrier according to the primary carrier intra-frequency measurement configuration, and acquires a monitoring set corresponding to the secondary carrier according to the secondary carrier same-frequency measurement configuration.
  • Step 203 The UE starts a primary carrier intra-frequency measurement for a cell set that includes a monitoring set corresponding to the primary carrier and a preset active primary carrier, and generates a primary carrier intra-frequency measurement event, and starts to include The secondary carrier co-frequency measurement of the cell set of the monitoring set corresponding to the secondary carrier generates a secondary carrier intra-frequency measurement event.
  • Step 204 The UE reports a primary carrier co-frequency measurement event and a secondary carrier co-frequency measurement event to the network side device on the primary carrier.
  • the UE reports a primary carrier co-frequency measurement event and a secondary carrier co-frequency measurement event to the network-side device, so that the network-side device can perform multi-carrier networking according to the event reported by the UE.
  • the UE is mobility managed.
  • the UE receives the primary carrier co-frequency measurement configuration and the secondary carrier co-frequency measurement configuration from the network side device, and starts the main group of the cell set that includes the monitoring set corresponding to the primary carrier and the active set corresponding to the primary carrier.
  • the carrier co-frequency measurement starts the co-frequency measurement of the secondary carrier for the cell set including the monitoring set corresponding to the secondary carrier, and reports the primary carrier co-frequency measurement event and the secondary carrier co-frequency measurement event to the network-side device.
  • the uplink carrier corresponding to the secondary carrier does not need to be set, and the UE only needs to be uniquely set.
  • the uplink carrier, the primary carrier co-frequency measurement event and the secondary carrier co-frequency measurement event are reported on the uplink carrier, thereby reducing the complexity of the network.
  • FIG. 3 is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 3 of the present invention. As shown in Figure 3, the method includes the following process.
  • Step 301 The network side device performs primary carrier co-frequency measurement configuration on the UE.
  • the network side device performs primary carrier co-frequency measurement configuration on the UE.
  • the configuration includes the measurement control information of the primary carrier and the monitoring set corresponding to the primary carrier.
  • the network side device completes the configuration process by transmitting measurement control information of the primary carrier to the UE and a monitoring set corresponding to the primary carrier.
  • the measurement control information of the primary carrier includes at least a reporting condition of a primary carrier intra-frequency measurement event.
  • the measurement control information may also include a lot of other information, for example, indicating whether the measurement is RSCP or Ec/N0, indicating an event reporting period, indicating which primary carrier co-frequency events are measured, and the like.
  • the network side device enables the UE to enable intra-frequency measurement for the primary carrier, and configures the UE to obtain the reporting condition of the primary carrier intra-frequency measurement event.
  • the primary carrier intra-frequency measurement event may include, but is not limited to, any one or combination of the following events: la event, lb event, lc event, Id event, le event, If event.
  • the reporting condition of the above-mentioned primary carrier intra-frequency measurement event is not limited, and the network-side device can be flexibly set according to the needs of the actual application.
  • the network side device When the network side device performs the primary carrier intra-frequency measurement configuration on the UE, the network side device sends a list of cells of the monitoring set corresponding to the primary carrier to the UE. The UE acquires a monitoring set corresponding to the primary carrier according to the configuration of the network side device.
  • the network side device may be a radio network controller (Radio Network Controller, RNC for short).
  • Step 302 The UE performs the same-frequency measurement on the primary carrier and reports the primary carrier intra-frequency measurement event to the network-side device.
  • the UE starts the intra-frequency measurement of the primary carrier for the cell set that includes the monitoring set corresponding to the primary carrier and the active set corresponding to the preset primary carrier, according to the primary carrier delivered by the network-side device. And measuring the control information, and the active set and the monitoring set corresponding to the primary carrier, performing the same frequency measurement on the primary carrier, and reporting the primary carrier to the network side device when the measurement result satisfies the reporting condition of the primary carrier co-frequency measurement event Frequency measurement events.
  • the monitoring set corresponding to the primary carrier is obtained by the UE in step 301; the active set corresponding to the primary carrier is obtained in advance by the UE.
  • the network side device sends the activation set update message to the UE, so that the UE obtains the active set corresponding to the primary carrier; the network side device reports the same frequency of the primary carrier and the event report by the UE, and the current primary of the UE.
  • the active set corresponding to the carrier is maintained, that is, the cell is added or deleted in the active set corresponding to the current primary carrier of the UE.
  • a radio link (Radio Link, RL for short) exists between the cell in the active set and the UE.
  • the RL includes an uplink (uplink) and a downlink (downlink).
  • the UE reports a primary carrier intra-frequency measurement event to the network side device, so that the network-side device can move the UE under the multi-carrier networking according to the event reported by the UE.
  • Sexual management
  • Step 303 The network side device performs a secondary carrier co-frequency measurement configuration on the UE.
  • the network side device performs the secondary carrier co-frequency measurement configuration on the UE after obtaining the primary carrier intra-frequency measurement event reported by the UE.
  • the primary carrier intra-frequency measurement event that triggers the network side device to perform secondary carrier co-frequency measurement configuration on the UE may include, but is not limited to, any one or combination of the following events: la event, lb event, lc event, Id event, le Events, If events.
  • the network side device completes the configuration process by transmitting the measurement control information of the secondary carrier to the UE and the monitoring set corresponding to the secondary carrier, where the measurement control information of the secondary carrier includes a reporting condition of the secondary carrier intra-frequency measurement event.
  • the network side device enables the UE to enable intra-frequency measurement for the secondary carrier, and enables the UE to obtain the reporting condition of the secondary carrier intra-frequency measurement event.
  • the secondary carrier intra-frequency measurement event may include, but is not limited to, any one or combination of the following events: la event, lb event, lc event, Id event, le event, If event.
  • the reporting condition of the above-mentioned secondary carrier intra-frequency measurement event is not limited, and the network-side device can be flexibly set according to the needs of the actual application.
  • the UE When the network side device performs the secondary carrier co-frequency measurement configuration on the UE, the UE sends the cell list of the monitoring set corresponding to the secondary carrier to the UE.
  • the UE acquires a monitoring set corresponding to the secondary carrier according to the secondary carrier intra-frequency measurement configuration.
  • the monitoring set is a list of cells that the UE continuously measures, and monitors the received signal code power (Received Signal Code Power, RSCP for short) or the average chip energy (simplified)
  • RSCP Receiveived Signal Code Power
  • the value of Ec/NO is not yet strong enough to be added to the activation set.
  • Step 304 The UE performs intra-frequency measurement on the secondary carrier and reports the secondary carrier intra-frequency measurement event to the network-side device.
  • the UE starts the co-frequency measurement of the secondary carrier for the cell set including the monitoring set corresponding to the secondary carrier, performs the same-frequency measurement on the secondary carrier according to the monitoring set corresponding to the secondary carrier, and When the result meets the reporting condition of the secondary carrier co-frequency measurement event, the secondary carrier co-frequency measurement event is reported to the network side device.
  • the UE reports a secondary carrier co-frequency measurement event to the network side device, so that the network side device can move the UE under the multi-carrier networking according to the event reported by the UE.
  • Sexual management the UE reports a secondary carrier co-frequency measurement event to the network side device, so that the network side device can move the UE under the multi-carrier networking according to the event reported by the UE.
  • the UE reports the same-frequency measurement event for the primary carrier and the secondary carrier, so that the network-side device can perform mobility management on the UE, and according to the same-frequency measurement reported by the UE for the primary carrier and the secondary carrier respectively.
  • Event switching the serving cell of the UE, and configuring the UE to the optimal mode.
  • the network-side device can configure the UE as the DF-DC mode.
  • the uplink carrier corresponding to the secondary carrier does not need to be set.
  • the UE only needs to set a unique uplink carrier, and the primary carrier co-frequency measurement event and the secondary carrier co-frequency measurement event are reported on the uplink carrier, thereby reducing network complexity.
  • the technical solution of the third embodiment of the present invention can not only implement the mobility management of the UE under the multi-carrier networking, but also reduce the measurement and reporting of the UE, thereby reducing the power consumption of the UE and the uplink signaling overhead.
  • FIG. 4 is a flowchart of a mobile measurement method for a multi-carrier networking according to Embodiment 4 of the present invention. As shown in Figure 4, the method includes the following process.
  • Step 401 The network side device performs primary carrier co-frequency measurement configuration and secondary carrier co-frequency measurement configuration on the UE.
  • the network side device performs primary carrier co-frequency measurement configuration on the UE. Specifically, the network side device completes the configuration process by transmitting measurement control information of the primary carrier and the monitoring set corresponding to the primary carrier to the UE, where the measurement control information of the primary carrier includes a reporting condition of the primary carrier intra-frequency measurement event. .
  • the network side device enables the UE to enable intra-frequency measurement for the primary carrier, and configures the UE to obtain the reporting condition of the primary carrier intra-frequency measurement event.
  • the primary carrier is measured at the same frequency
  • the quantity event may include, but is not limited to, any one or combination of the following events: la event, lb event, lc event, Id event, le event, If event.
  • the reporting condition of the primary carrier intra-frequency measurement event is not limited, and the network-side device can be flexibly set according to the needs of the actual application.
  • the network side device sends a list of cells in the monitoring set corresponding to the primary carrier to the UE when performing the primary carrier intra-frequency measurement configuration on the UE.
  • the UE acquires a monitoring set corresponding to the primary carrier according to the configuration of the network side device.
  • the network side device further performs a secondary carrier co-frequency measurement configuration on the UE. Specifically, the network side device completes the configuration process by transmitting the measurement control information of the secondary carrier to the UE and the monitoring set corresponding to the secondary carrier, where the measurement control information of the secondary carrier includes a reporting condition of the secondary carrier intra-frequency measurement event. Through the configuration process, the network side device enables the UE to obtain the reporting condition of the secondary carrier intra-frequency measurement event.
  • the secondary carrier intra-frequency measurement event may include, but is not limited to, any one or a combination of the following events: la event, lb event, lc event, Id event, le event, If event.
  • the reporting condition of the above-mentioned secondary carrier intra-frequency measurement event is not limited, and the network-side device can be flexibly set according to the needs of the actual application.
  • the network side device performs the secondary carrier co-frequency measurement configuration on the UE
  • the cell list of the monitoring set corresponding to the secondary carrier is sent to the UE.
  • the UE acquires a monitoring set corresponding to the secondary carrier according to the secondary carrier intra-frequency measurement configuration.
  • the monitoring set is a cell list in which the UE continuously measures, and the RSCP or Ec/NO value of the monitored cell pilot is not yet strong enough to be added to the active set.
  • Step 402 The UE performs intra-frequency measurement on the primary carrier and reports a primary carrier intra-frequency measurement event to the network-side device.
  • the UE starts the intra-frequency measurement of the primary carrier for the cell set that includes the monitoring set corresponding to the primary carrier and the active set corresponding to the preset primary carrier, according to the primary carrier delivered by the network-side device.
  • Measure control information perform intra-frequency measurement on the primary carrier in the range of the active set corresponding to the primary carrier, and report the primary to the network-side device when the measurement result meets the reporting condition of the primary carrier co-frequency measurement event Carrier frequency measurement events.
  • the monitoring set corresponding to the primary carrier is obtained by the UE in step 401; the active set corresponding to the primary carrier is obtained in advance by the UE.
  • the network side device sends the active set maintenance message to the UE, so that the UE obtains the active set corresponding to the primary carrier.
  • the network side device can also report the same frequency measurement and event reporting of the primary carrier by the UE.
  • the active set corresponding to the primary carrier is maintained, that is, the cell is added or deleted in the active set corresponding to the current primary carrier of the UE.
  • the network side device acquires a primary carrier intra-frequency measurement event reported by the UE, so that the network side device can perform the UE on the multi-carrier networking according to the event reported by the UE. Mobility management.
  • step 404 may be directly performed, or step 403 may be performed first. If the determination result of step 403 is no, the process is further performed. 404.
  • the UE performs the same-frequency measurement on the secondary carrier according to the triggering of the primary carrier intra-frequency measurement event, where the primary carrier intra-frequency measurement event that triggers the UE to perform the secondary carrier-frequency measurement may include but is not limited to the following events. Any combination of one or several: la event, lb event, lc event, Id event, le event, If event.
  • Step 403 The UE determines whether the coverage of the current serving base station on the secondary carrier is the same as the coverage on the primary carrier.
  • step 404 If yes, end the process. If no, perform step 404.
  • the network side device may inform the UE of the following information by means of broadcast or signaling: the transmit power of the macro base station and the micro base station on the primary carrier and the transmit power of the macro base station and the micro base station on the secondary carrier.
  • the UE determines whether the current serving base station is a macro base station or a micro base station. Specifically, the base station to which the current serving cell belongs, that is, the current serving base station, determines whether the current serving cell belongs to the macro base station or the micro base station.
  • the UE compares the transmit power of the macro base station on the primary carrier with the transmit power on the secondary carrier; if the current serving base station is a micro base station, the UE compares the micro base station with the primary carrier. If the comparison between the transmit power and the transmit power on the secondary carrier is different, the UE determines that the coverage of the current serving base station on the secondary carrier is different from the coverage on the primary carrier.
  • Step 404 The UE performs intra-frequency measurement on the secondary carrier and reports the secondary carrier intra-frequency measurement event to the network-side device.
  • the UE starts the co-frequency measurement of the secondary carrier for the cell set including the monitoring set corresponding to the secondary carrier, performs the same-frequency measurement on the secondary carrier according to the monitoring set corresponding to the secondary carrier, and When the result meets the reporting condition of the secondary carrier co-frequency measurement event, the secondary carrier co-frequency measurement event is reported to the network side device.
  • the network side device acquires the secondary carrier intra-frequency measurement event reported by the UE, so that the network side device can perform the UE on the multi-carrier networking according to the event reported by the UE. Mobility management.
  • the UE reports the same-frequency measurement event for the primary carrier and the secondary carrier, so that the network-side device can perform mobility management on the UE, according to the same-frequency measurement reported by the UE for the primary carrier and the secondary carrier respectively. Event, switching the serving cell of the UE, and configuring the UE to the optimal mode. For example, if the UE supports the DF-DC mode, the network side device can configure the UE to the DF-DC mode.
  • the method of the fourth embodiment of the present invention only the active set on the primary carrier is established, and only the monitoring set is used on the secondary carrier. Since the monitored centralized cell does not need to establish an RL connection with the UE, it is not necessary to set the uplink carrier corresponding to the secondary carrier. The UE only needs to set a unique uplink carrier, and the primary carrier co-frequency measurement event and the secondary carrier co-frequency measurement event are reported on the uplink carrier, thereby reducing network complexity.
  • the technical solution of the fourth embodiment of the present invention can not only implement the mobility management of the UE under the multi-carrier networking, but also reduce the measurement and reporting of the UE, thereby reducing the power consumption of the UE and the uplink signaling overhead.
  • FIG. 5 is a schematic structural diagram of a network side device according to Embodiment 5 of the present invention. As shown in FIG. 5, the device includes at least: a configuration unit 51 and an acquisition unit 52.
  • the configuration unit 51 is configured to perform a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration on the UE, so that the UE acquires a monitoring set corresponding to the first carrier according to the first carrier intra-frequency measurement configuration.
  • Frequency measurement generating a first carrier co-frequency measurement event, starting a second carrier co-frequency measurement for a cell set including the monitoring set corresponding to the second carrier, and generating a second carrier co-frequency measurement event.
  • the UE has a radio link connection with each cell in the active set, and has no radio link connection with each cell in the monitoring set.
  • the obtaining unit 52 is configured to acquire a first carrier intra-frequency measurement event and a second carrier co-frequency measurement event reported by the UE on the first carrier.
  • the configuration unit 51 is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE starts to perform according to the first carrier co-frequency measurement configuration.
  • the first carrier corresponding to the measurement set of the first carrier and the first carrier of the active set corresponding to the preset first carrier are measured in the same frequency, and are specifically used to obtain the first carrier reported by the UE in the acquiring unit 52.
  • performing a second carrier co-frequency measurement configuration on the UE so that the UE starts, according to the second carrier co-frequency measurement configuration, a cell set that includes a monitoring set corresponding to the second carrier. Two carrier frequency measurement.
  • the configuration unit 51 is specifically configured to enter the UE. Performing a first carrier on-frequency measurement configuration, so that the UE starts a cell set for the active set corresponding to the monitoring set corresponding to the first carrier and the preset first carrier according to the first carrier intra-frequency measurement configuration
  • the first carrier is measured in the same frequency, and is specifically configured to perform the second carrier co-frequency measurement configuration on the UE before the acquiring unit 52 acquires the first carrier intra-frequency measurement event reported by the UE, so that the When reporting the first carrier intra-frequency measurement event, the UE starts a second carrier intra-frequency measurement for the cell set including the monitoring set corresponding to the second carrier.
  • the configuration unit 51 is specifically configured to send, to the UE, measurement control information of a first carrier and a monitoring set corresponding to the first carrier, where the first carrier is
  • the measurement control information includes a reporting condition of the first carrier intra-frequency measurement event, and is specifically configured to send, to the UE, measurement control information of the second carrier and a monitoring set corresponding to the second carrier, where the second carrier is measured.
  • the control information includes a reporting condition of the second carrier co-frequency measurement event.
  • the first carrier is a primary carrier
  • the second carrier is a secondary carrier
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: a la event, a lb event, an lc event, an Id event, and le At least one of an event and an If event.
  • the network side device of the fifth embodiment of the present invention can be used to perform the mobile measurement method of the multi-carrier networking according to the fourth embodiment of the present invention.
  • the specific implementation process and technical effects can be referred to the first embodiment of the present invention.
  • Embodiment 4 of the invention which is not described herein again.
  • FIG. 6 is a schematic structural diagram of a user equipment according to Embodiment 6 of the present invention.
  • the user equipment at least includes: a receiving unit 61, an obtaining unit 62, a measuring unit 63, and a reporting unit 64.
  • the receiving unit 61 is configured to receive a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration from the network side device.
  • the obtaining unit 62 is configured to acquire a monitoring set corresponding to the first carrier according to the first carrier co-frequency measurement configuration, and acquire a monitoring set corresponding to the second carrier according to the second carrier intra-frequency measurement configuration.
  • the measuring unit 63 is configured to start a first carrier intra-frequency measurement for the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and generate a first carrier intra-frequency measurement event, and start And transmitting, by the second carrier of the cell set of the monitoring set corresponding to the second carrier, a second carrier co-frequency measurement event.
  • the UE and each cell in the active set There is a wireless link connection, and there is no wireless link connection with each cell in the monitoring set.
  • the reporting unit 64 is configured to report the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event to the network side device on the first carrier.
  • the measuring unit 63 is specifically configured to perform the same carrier frequency measurement according to the first carrier after the receiving unit 61 receives the first carrier intra-frequency measurement configuration from the network side device.
  • the configuration starts to generate a first carrier intra-frequency measurement event for the first carrier intra-frequency measurement of the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier.
  • the receiving unit 61 is configured to: after the reporting unit 64 reports the first carrier intra-frequency measurement event to the network side device, receive the second carrier co-frequency measurement configuration from the network side device, where The measuring unit 63 is specifically configured to start, according to the second carrier co-frequency measurement configuration, a second carrier co-frequency measurement for a cell set including a monitoring set corresponding to the second carrier, to generate a second carrier co-frequency measurement event.
  • the measuring unit 63 is specifically configured to perform the same carrier frequency measurement according to the first carrier after the receiving unit 61 receives the first carrier intra-frequency measurement configuration from the network side device.
  • the configuration starts to generate a first carrier intra-frequency measurement event for the first carrier intra-frequency measurement of the cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier.
  • the receiving unit 61 is configured to: before the reporting unit 64 reports the first carrier intra-frequency measurement event to the network side device, receive a second carrier co-frequency measurement configuration from the network side device, where When the reporting unit 64 reports the first carrier intra-frequency measurement event, the second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started, and the second carrier intra-frequency measurement event is generated.
  • the receiving unit 61 is configured to receive, by the network side device, measurement control information of a first carrier and a monitoring set corresponding to the first carrier, where
  • the measurement control information of a carrier includes a reporting condition of the first carrier co-frequency measurement event, and is specifically configured to receive measurement control information of the second carrier delivered by the network side device and a monitoring set corresponding to the second carrier, where
  • the measurement control information of the second carrier includes a reporting condition of the second carrier intra-frequency measurement event.
  • the first carrier is a primary carrier
  • the second carrier is a secondary carrier
  • the measuring unit 63 is specifically used for the current
  • the serving station of the serving cell starts the second carrier with the cell set of the monitoring set corresponding to the second carrier. Frequency measurement.
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: a la event, a lb event, an lc event, an Id event, and le At least one of an event and an If event.
  • the user equipment of the sixth embodiment of the present invention can be used to perform the mobile measurement method of the multi-carrier networking according to the fourth embodiment of the present invention.
  • the specific implementation process and technical effects can be referred to the first embodiment of the present invention.
  • the fourth embodiment is not described here.
  • the specific functions performed by each unit in the user equipment corresponding to FIG. 6 can be referred to the description in the previous method embodiment.
  • FIG. 7 is a schematic structural diagram of a network side device according to Embodiment 7 of the present invention. As shown in FIG. 7, the network side device includes at least: a transmitter 71, a receiver 72, and a bus 70.
  • the transmitter 71 is configured to perform a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration on the user equipment UE, so that the UE acquires the first carrier corresponding to the monitoring according to the first carrier intra-frequency measurement configuration. And acquiring, according to the second carrier co-frequency measurement configuration, a monitoring set corresponding to the second carrier, and starting a first set of cells that includes an active set corresponding to the monitoring set corresponding to the first carrier and the preset first carrier
  • the carrier co-frequency measurement generates a first carrier co-frequency measurement event, and starts a second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier, to generate a second carrier co-frequency measurement event.
  • the UE has a radio link connection with each cell in the active set, and no radio link is connected to each cell in the monitoring set.
  • the receiver 72 is configured to acquire a first carrier intra-frequency measurement event and a second carrier co-frequency measurement event reported by the UE on the first carrier.
  • the bus 70 is connected to a transmitter 71 and a receiver 72 for data exchange between the transmitter 71 and the receiver 72.
  • the transmitter 71 is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE starts to perform according to the first carrier co-frequency measurement configuration.
  • the first carrier corresponding to the measurement set of the first carrier and the first carrier of the active set corresponding to the preset first carrier are measured in the same frequency, and are specifically used to acquire the first carrier reported by the UE at the receiver 72.
  • performing a second carrier on-frequency measurement configuration on the UE so that the UE starts, according to the second carrier co-frequency measurement configuration, a monitoring set corresponding to the second carrier.
  • the second carrier of the set of cells is measured in the same frequency.
  • the transmitter 71 is specifically configured to perform a first carrier intra-frequency measurement configuration on the UE, so that the UE starts to perform according to the first carrier co-frequency measurement configuration.
  • the first carrier corresponding to the measurement set of the first carrier and the first carrier of the active set corresponding to the preset first carrier are measured in the same frequency, and are specifically used to acquire the first carrier reported by the UE at the receiver 72.
  • performing a second carrier on-frequency measurement configuration on the UE so that when the UE reports the first carrier intra-frequency measurement event, the UE starts the cell set that includes the monitoring set corresponding to the second carrier. Two carrier frequency measurement.
  • the transmitter 71 is specifically configured to send, to the UE, measurement control information of a first carrier and a monitoring set corresponding to the first carrier, where the first carrier is
  • the measurement control information includes a reporting condition of the first carrier co-frequency measurement event, and is specifically used to
  • the UE sends the measurement control information of the second carrier and the monitoring set corresponding to the second carrier, where the measurement control information of the second carrier includes a reporting condition of the second carrier intra-frequency measurement event.
  • the first carrier is a primary carrier
  • the second carrier is a secondary carrier
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: a la event, a lb event, an lc event, an Id event, and le At least one of an event and an If event.
  • the network side device of the seventh embodiment of the present invention can be used to perform the mobile measurement method of the multi-carrier networking according to the fourth embodiment of the present invention.
  • the specific implementation process and technical effects can be referred to the first embodiment of the present invention.
  • Embodiment 4 of the invention which is not described herein again.
  • the specific functions performed by the transmitter 71 and the receiver 72 in this embodiment can be referred to the description of the previous method embodiments.
  • FIG. 8 is a schematic structural diagram of a user equipment according to Embodiment 8 of the present invention.
  • the user equipment includes at least a receiver 81, a first processor 82, a second processor 83, a transmitter 84, and a bus 80.
  • the receiver 81 is configured to receive a first carrier co-frequency measurement configuration and a second carrier co-frequency measurement configuration from the network side device.
  • the first processor 82 is configured to acquire a monitoring set corresponding to the first carrier according to the first carrier co-frequency measurement configuration, and acquire a monitoring set corresponding to the second carrier according to the second carrier intra-frequency measurement configuration;
  • the second processor 83 is configured to start a first carrier intra-frequency measurement for a cell set that includes the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier, and generate a first carrier co-frequency measurement. a second carrier co-frequency measurement for generating a second carrier-synchronous measurement event for the cell set that includes the monitoring set corresponding to the second carrier, where the UE and the cells in the active set have wireless a link connection, having no wireless link connection with each cell in the monitoring set;
  • the transmitter 84 is configured to report, on the first carrier, a first carrier co-frequency measurement event and a second carrier co-frequency measurement event to the network side device.
  • the bus 80 is connected to the receiver 81, the first processor 82, the second processor 83, and the transmitter 84 for the receiver 81, the first processor 82, and the Data exchange is performed between the second processor 83 and the transmitter 84.
  • the second processor 83 is specifically configured to: after the receiver 81 receives the first carrier intra-frequency measurement configuration from the network side device, according to the first carrier The frequency measurement configuration starts to generate a first carrier intra-frequency measurement event for the first carrier intra-frequency measurement of the cell set including the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier.
  • the receiver 81 is configured to: after the transmitter 84 reports the first carrier intra-frequency measurement event to the network side device, receive the second carrier co-frequency measurement configuration from the network side device, where
  • the second processor 83 is configured to start, according to the second carrier co-frequency measurement configuration, a second carrier co-frequency measurement for a cell set that includes the monitoring set corresponding to the second carrier, to generate a second carrier co-frequency measurement event. .
  • the second processor 83 is specifically configured to: after the receiver 81 receives the first carrier intra-frequency measurement configuration from the network side device, according to the first carrier The frequency measurement configuration starts to generate a first carrier intra-frequency measurement event for the first carrier intra-frequency measurement of the cell set including the monitoring set corresponding to the first carrier and the active set corresponding to the preset first carrier.
  • the receiver 81 is configured to receive a second carrier co-frequency measurement configuration from the network side device before the transmitter 84 reports the first carrier intra-frequency measurement event to the network side device, where When the transmitter 84 reports the first carrier intra-frequency measurement event, the second carrier co-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started, and the second carrier co-frequency measurement event is generated.
  • the receiver 81 is specifically configured to receive measurement control information of a first carrier that is sent by the network side device, and a monitoring set corresponding to the first carrier, where
  • the measurement control information of a carrier includes a reporting condition of the first carrier co-frequency measurement event, and is specifically configured to receive measurement control information of the second carrier delivered by the network side device, and the second carrier Corresponding monitoring set, the measurement control information of the second carrier includes a reporting condition of the second carrier co-frequency measurement event.
  • the first carrier is a primary carrier
  • the second carrier is a secondary carrier
  • the second processor 83 is specifically configured to cover the cell coverage of the second carrier and the cell coverage of the first carrier at a serving station where the current serving cell is located.
  • the second carrier intra-frequency measurement for the cell set including the monitoring set corresponding to the second carrier is started.
  • At least one of the first carrier intra-frequency measurement event and the second carrier co-frequency measurement event includes: a la event, a lb event, an lc event, an Id event, and le At least one of an event and an If event.
  • the network side device of the eighth embodiment of the present invention can be used to perform the mobile measurement method of the multi-carrier networking according to the fourth embodiment of the present invention.
  • the specific implementation process and technical effects can be referred to the first embodiment of the present invention.
  • Embodiment 4 of the invention which is not described herein again.
  • the functions performed by the receiver 81, the first processor 82, the second processor 83, and the transmitter 84 in this embodiment can be referred to the description of the previous method embodiment, which is not described in this embodiment.
  • the aforementioned program can be stored in a computer readable storage medium.
  • the program when executed, performs the steps including the foregoing method embodiments; and the foregoing storage medium includes: a medium that can store program codes, such as ROM, RAM, disk or optical disk.

Abstract

一种多载波组网的移动测量方法、网络侧设备和用户设备。网络侧设备对用户设备UE进行第一载波同频测量配置和第二载波同频测量配置,以使UE根据第一载波同频测量配置获取第一载波对应的监测集,根据第二载波同频测量配置获取第二载波对应的监测集,启动对于包含第一载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同频测量,生成第一载波同频测量事件,启动对于包含第二载波对应的监测集的小区集合的第二载波同频测量,生成第二载波同频测量事件;网络侧设备获取UE在第一载波上报的第一载波同频测量事件和第二载波同频测量事件。采用本发明提供的方法和设备,能够降低网络复杂度。

Description

多栽波组网的移动测量方法、 网络側设备和用户设备
本申请要求于 2013 年 9 月 2 日提交中国专利局、 申请号为 201310392980.X, 发明名称为"多载波组网的移动测量方法、 网络侧设备和用 户设备"的中国专利申请的优先权, 其全部内容通过引用结合在本申请中。
技术领域 本发明涉及通信技术, 尤其涉及一种多载波组网的移动测量方法、 网络 侧设备和用户设备。 背景技术
在宽带码分多址 (Wide-band Code Division Multiple Access, WCDMA) 系统中, 可以采用异构网 (Heterogeneous, 简称 Hetnet )。 图 1为异构网的 结构示意图。 如图 1所示, 网络中包括覆盖范围大的宏站 (Macro Node B) 和覆盖小的微站 (Pico Node B), 小区的下行覆盖范围由小区的下行发射功 率决定, 在图 1中, 宏站的覆盖范围用 F2表示, 微站的覆盖范围用 F1表示, 宏站与微站的覆盖范围具有重叠的区域。 在异构网中, 需要通过移动测量获 知用户设备 (User Equipment , 简称 UE) 所处的区域, 以便为其配置最优的 服务小区。
在异构网中, 可以采用多载波组网, 宏小区和微小区都配置下行双载波, 称为主载波和辅载波。 在进行移动测量时, 在下行的主载波和辅载波上分别 建立激活集, UE根据两个激活集分别进行同频测量, 上报同频测量事件。 其 中, 激活集 (简称 active set ) 是一个小区集合, 激活集中的小区与 UE之间 存在无线链路 (Radio Link, 简称 RL) , 该 RL包括上行链路 (简称 uplink) 和下行链路 (简称 downl ink) 。
采用上述现有的多载波组网的移动测量方法, 由于建立了两个激活集, 因此, 主载波的激活集中的小区与辅载波的激活集中的小区需要相互独立的 下行链路和上行链路, 该方案所需上行载波的数量多, 网络复杂度高。 发明内容 本发明的第一个方面是提供一种多载波组网的移动测量方法, 用以解决 现有技术中的缺陷, 降低网络复杂度。
本发明的另一个方面是提供一种网络侧设备和用户设备, 用以解决现有 技术中的缺陷, 降低网络复杂度。
本发明的第一个方面是提供一种多载波组网的移动测量方法, 包括: 网络侧设备对用户设备 UE进行第一载波同频测量配置和第二载波同频测 量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应的监 测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启动对 于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区集 合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所述第 二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测 量事件; 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所述监 测集中的各小区没有无线链路连接;
所述网络侧设备获取所述 UE在所述第一载波上报的第一载波同频测量事 件和第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述网络侧设备对 UE进行第一载波同频测量配置和第二载波同频测量配置包 括:
所述网络侧设备对 UE进行第一载波同频测量配置, 以使所述 UE根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量;
所述网络侧设备在获取所述 UE上报的第一载波同频测量事件之后, 对所 述 UE进行第二载波同频测量配置, 以使所述 UE根据所述第二载波同频测量配 置启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测 量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述网络侧设备对 UE进行第一载波同频测量配置和第二载波同频测量配置包 括:
所述网络侧设备对 UE进行第一载波同频测量配置, 以使所述 UE根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量;
所述网络侧设备在获取所述 UE上报的第一载波同频测量事件之前, 对所 述 UE进行第二载波同频测量配置, 以使所述 UE在上报第一载波同频测量事件 时启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测 如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述网络侧设备对 UE进行第一载波同频测量配置包括: 所述网络侧设备 向所述 UE下发第一载波的测量控制信息和所述第一载波对应的监测集, 所述 第一载波的测量控制信息包括第一载波同频测量事件的上报条件;
所述网络侧设备对 UE进行第二载波同频测量配置包括: 所述网络侧设备 向所述 UE下发第二载波的测量控制信息和所述第二载波对应的监测集, 所述 第二载波的测量控制信息包括第二载波同频测量事件的上报条件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波为主载波, 所述第二载波为辅载波。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。 本发明的另一个方面是提供一种多载波组网的移动测量方法, 包括: 用户设备 UE接收来自网络侧设备的第一载波同频测量配置和第二载波同 频测量配置;
所述 UE根据所述第一载波同频测量配置获取第一载波对应的监测集, 根 据所述第二载波同频测量配置获取第二载波对应的监测集;
所述 UE启动对于包含所述第一载波对应的监测集和预设的第一载波对应 的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量事件, 启 动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生 成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小区有无线链 路连接, 与所述监测集中的各小区没有无线链路连接;
所述 UE在所述第一载波上向所述网络侧设备上报第一载波同频测量事件 和第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述 UE启动对于包含所述第一载波对应的监测集和预设的第一载波对应的激活 集的小区集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于 包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二 载波同频测量事件包括:
所述 UE在接收来自网络侧设备的第一载波同频测量配置之后, 根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件;
所述 UE在向所述网络侧设备上报第一载波同频测量事件之后, 接收来自 所述网络侧设备的第二载波同频测量配置, 根据所述第二载波同频测量配置 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述 UE启动对于包含所述第一载波对应的监测集和预设的第一载波对应的激活 集的小区集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于 包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二 载波同频测量事件包括:
所述 UE在接收来自网络侧设备的第一载波同频测量配置之后, 根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件;
所述 UE在向所述网络侧设备上报第一载波同频测量事件之前, 接收来自 网络侧设备的第二载波同频测量配置, 在上报第一载波同频测量事件时启动 对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成 第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述 UE接收来自网络侧设备的第一载波同频测量配置包括: 所述 UE接收 所述网络侧设备下发的第一载波的测量控制信息和所述第一载波对应的监测 集, 所述第一载波的测量控制信息包括第一载波同频测量事件的上报条件; 所述 UE接收来自网络侧设备的第二载波同频测量配置包括: 所述 UE接收 所述网络侧设备下发的第二载波的测量控制信息和所述第二载波对应的监测 集, 所述第二载波的测量控制信息包括第二载波同频测量事件的上报条件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波为主载波, 所述第二载波为辅载波。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量 包括:
若当前服务小区所在的服务站点在所述第二载波的小区覆盖范围与在所 述第一载波的小区覆盖范围不同, 则所述 UE启动对于包含所述第二载波对应 的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。 本发明的又一个方面是提供一种网络侧设备, 包括:
配置单元, 用于对用户设备 UE进行第一载波同频测量配置和第二载波同 频测量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应 的监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启 动对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小 区集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所 述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同 频测量事件; 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所 述监测集中的各小区没有无线链路连接;
获取单元, 用于获取所述 UE在所述第一载波上报的第一载波同频测量事 件和第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述配置单元具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根 据所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预 设的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在 所述获取单元获取所述 UE上报的第一载波同频测量事件之后, 对所述 UE进行 第二载波同频测量配置, 以使所述 UE根据所述第二载波同频测量配置启动对 于包含所述第二载波对应的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述配置单元具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根 据所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预 设的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在 所述获取单元获取所述 UE上报的第一载波同频测量事件之前, 对所述 UE进行 第二载波同频测量配置, 以使所述 UE在上报第一载波同频测量事件时启动对 于包含所述第二载波对应的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述配置单元具体用于向所述 UE下发第一载波的测量控制信息和所述第 一载波对应的监测集, 所述第一载波的测量控制信息包括第一载波同频测量 事件的上报条件, 并具体用于向所述 UE下发第二载波的测量控制信息和所述 第二载波对应的监测集, 所述第二载波的测量控制信息包括第二载波同频测 量事件的上报条件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波为主载波, 所述第二载波为辅载波。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。 本发明的又一个方面是提供一种用户设备 UE, 包括:
接收单元, 用于接收来自网络侧设备的第一载波同频测量配置和第二载 波同频测量配置;
获取单元, 用于根据所述第一载波同频测量配置获取第一载波对应的监 测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集;
测量单元, 用于启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件, 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频 测量, 生成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小区 有无线链路连接, 与所述监测集中的各小区没有无线链路连接;
上报单元, 用于在所述第一载波上向所述网络侧设备上报第一载波同频 测量事件和第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述测量单元具体用于在所述接收单元接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收单元具体用于在所述上报单元向所述网络侧设备上报第一载波 同频测量事件之后, 接收来自所述网络侧设备的第二载波同频测量配置, 所 述测量单元具体用于根据所述第二载波同频测量配置启动对于包含所述第二 载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量 事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述测量单元具体用于在所述接收单元接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收单元具体用于在所述上报单元向所述网络侧设备上报第一载波 同频测量事件之前, 接收来自网络侧设备的第二载波同频测量配置, 在所述 上报单元上报第一载波同频测量事件时启动对于包含所述第二载波对应的监 测集的小区集合的第二载波同频测量, 生成第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述接收单元具体用于接收所述网络侧设备下发的第一载波的测量控制 信息和所述第一载波对应的监测集, 所述第一载波的测量控制信息包括第一 载波同频测量事件的上报条件, 并具体用于接收所述网络侧设备下发的第二 载波的测量控制信息和所述第二载波对应的监测集, 所述第二载波的测量控 制信息包括第二载波同频测量事件的上报条件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波为主载波, 所述第二载波为辅载波。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述测量单元具体用于在当前服务小区所在的服务站点在所述第二载波的小区 覆盖范围与在所述第一载波的小区覆盖范围不同时, 启动对于包含所述第二 载波对应的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。 本发明的又一个方面是提供一种网络侧设备, 包括:
发送器, 用于对用户设备 UE进行第一载波同频测量配置和第二载波同频 测量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应的 监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启动 对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区 集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所述 第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频 测量事件; 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所述 监测集中的各小区没有无线链路连接;
接收器, 用于获取所述 UE在所述第一载波上报的第一载波同频测量事件 和第二载波同频测量事件;
总线, 连接所述发送器和所述接收器, 用于在所述发送器和所述接收器 之间进行数据交换。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述发送器具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根据 所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设 的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在所 述接收器获取所述 UE上报的第一载波同频测量事件之后, 对所述 UE进行第二 载波同频测量配置, 以使所述 UE根据所述第二载波同频测量配置启动对于包 含所述第二载波对应的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述发送器具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根据 所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设 的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在所 述接收器获取所述 UE上报的第一载波同频测量事件之前, 对所述 UE进行第二 载波同频测量配置, 以使所述 UE在上报第一载波同频测量事件时启动对于包 含所述第二载波对应的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述发送器具体用于向所述 UE下发第一载波的测量控制信息和所述第一 载波对应的监测集, 所述第一载波的测量控制信息包括第一载波同频测量事 件的上报条件, 并具体用于向所述 UE下发第二载波的测量控制信息和所述第 二载波对应的监测集, 所述第二载波的测量控制信息包括第二载波同频测量 事件的上报条件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波为主载波, 所述第二载波为辅载波。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。 本发明的又一个方面是提供一种用户设备 UE, 包括:
接收器, 用于接收来自网络侧设备的第一载波同频测量配置和第二载波 同频测量配置;
第一处理器, 用于根据所述第一载波同频测量配置获取第一载波对应的 监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集;
第二处理器, 用于启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件, 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同 频测量, 生成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小 区有无线链路连接, 与所述监测集中的各小区没有无线链路连接;
发送器, 用于在所述第一载波上向所述网络侧设备上报第一载波同频测 量事件和第二载波同频测量事件;
总线, 连接所述接收器、 所述第一处理器、 所述第二处理器和所述发送 器, 用于在所述接收器、 所述第一处理器、 所述第二处理器和所述发送器之 间进行数据交换。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述第二处理器具体用于在所述接收器接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收器具体用于在所述发送器向所述网络侧设备上报第一载波同频 测量事件之后, 接收来自所述网络侧设备的第二载波同频测量配置, 所述第 二处理器具体用于根据所述第二载波同频测量配置启动对于包含所述第二载 波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量事 件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述第二处理器具体用于在所述接收器接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收器具体用于在所述发送器向所述网络侧设备上报第一载波同频 测量事件之前, 接收来自网络侧设备的第二载波同频测量配置, 在所述发送 器上报第一载波同频测量事件时启动对于包含所述第二载波对应的监测集的 小区集合的第二载波同频测量, 生成第二载波同频测量事件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所述接收器具体用于接收所述网络侧设备下发的第一载波的测量控制信 息和所述第一载波对应的监测集, 所述第一载波的测量控制信息包括第一载 波同频测量事件的上报条件, 并具体用于接收所述网络侧设备下发的第二载 波的测量控制信息和所述第二载波对应的监测集, 所述第二载波的测量控制 信息包括第二载波同频测量事件的上报条件。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波为主载波, 所述第二载波为辅载波。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第二处理器具体用于在当前服务小区所在的服务站点在所述第二载波的小 区覆盖范围与在所述第一载波的小区覆盖范围不同时, 启动对于包含所述第 二载波对应的监测集的小区集合的第二载波同频测量。
如上所述的方面和任一可能的实现方式, 进一歩提供一种实现方式, 所 述第一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。 由上述发明内容可见, 网络侧设备对 UE进行第一载波同频测量配置和第 二载波同频测量配置, UE对第一载波对应的监测集和第一载波对应的激活集 进行第一载波同频测量, 对第二载波对应的监测集进行第二载波同频测量, 分别上报针对第一载波和第二载波的同频测量事件。 由于只建立第一载波上 的激活集, 而第二载波上只使用监测集, 并且由于监测集中的小区无需与 UE 建立 RL连接, 因此不需要设置第二载波对应的上行载波, 所述 UE只需要设置 唯一的上行载波, 第一载波同频测量事件与第二载波同频测量事件均在该上 行载波上上报, 从而降低了网络的复杂度。 附图说明 为了更清楚地说明本发明实施例或现有技术中的技术方案, 下面将对实 施例或现有技术描述中所需要使用的附图作简单地介绍, 显而易见地, 下面 描述中的附图仅仅是本发明的一些实施例, 对于本领域普通技术人员来讲, 在不付出创造性劳动的前提下, 还可以根据这些附图获得其他的附图。
图 1为异构网的结构示意图;
图 2a为本发明实施例一的多载波组网的移动测量方法的流程图; 图 2b为本发明实施例二的多载波组网的移动测量方法的流程图; 图 3为本发明实施例三的多载波组网的移动测量方法的流程图;
图 4为本发明实施例四的多载波组网的移动测量方法的流程图;
图 5为本发明实施例五的网络侧设备的结构示意图;
图 6为本发明实施例六的用户设备的结构示意图;
图 7为本发明实施例七的网络侧设备的结构示意图;
图 8为本发明实施例八的用户设备的结构示意图。 具体实施方式 下面将结合本发明实施例中的附图, 对本发明实施例中的技术方案进行 清楚、 完整地描述, 显然, 所描述的实施例仅仅是本发明一部分实施例, 而 不是全部的实施例。 基于本发明中的实施例, 本领域普通技术人员在没有做 出创造性劳动前提下所获得的所有其他实施例, 都属于本发明保护的范围。 在本发明下述的各个实施例中, 通信系统组网中部署了两个下行载波,
SP : 第一载波和第二载波, 并且, 上述两个下行载波跟一个上行载波相关联。 第一服务站点在工作于第一载波时形成第一小区, UE通过第一小区与第一服 务站点通信。 在一种实现方式中, 第一载波可以为主载波, 第二载波可以为 辅载波。
图 2a为本发明实施例一的多载波组网的移动测量方法的流程图。 如图 1 所示, 该方法包括以下过程。
歩骤 101:网络侧设备对 UE进行主载波同频测量配置和辅载波同频测量配 置。
在本歩骤中, 网络侧设备对 UE进行主载波同频测量配置和辅载波同频测 量配置, 以使所述 UE根据所述主载波同频测量配置获取主载波对应的监测集, 根据所述辅载波同频测量配置获取辅载波对应的监测集, 启动对于包含所述 主载波对应的监测集和预设的主载波对应的激活集的小区集合的主载波同频 测量, 生成主载波同频测量事件, 启动对于包含所述辅载波对应的监测集的 小区集合的辅载波同频测量, 生成辅载波同频测量事件。
在本发明实施例一以及下述的各个实施例中, 激活集 (简称 active set) 是一个小区集合, 激活集中的小区与 UE之间存在 RL, 该 RL包括上行链路和下 行链路。 监测集是 UE连续不断进行测量的小区清单, 监测集中的小区导频的 接收信号码功率 (Received Signal Code Power, 简称 RSCP) 或者码片平均 能量(简称 Ec/NO)值尚未强到可以加入激活集。 主载波对应的监测集与辅载 波对应的监测集是相互独立的。
歩骤 102:所述网络侧设备获取所述 UE在所述主载波上报的主载波同频测 量事件和辅载波同频测量事件。
在本歩骤中, 所述网络侧设备获取所述 UE上报的主载波同频测量事件和 辅载波同频测量事件, 从而所述网络侧设备能够根据所述 UE上报的上述事件 在多载波组网下对所述 UE进行移动性管理。
在本发明实施例一以及下述的各个实施例中, 同频测量事件可以包括以 下事件中的至少一项: la事件、 lb事件、 lc事件、 Id事件、 le事件、 If事件。 具体地, la事件用来添加激活集小区, 当一个激活集外小区的测量值好于报 告范围, 触发 la事件。 lb事件用来删除激活集小区, 当一个激活集内小区的 测量值差于报告范围, 触发 lb事件。 lc事件用来将激活集外小区替换激活集 内小区, 当一个激活集外小区的测量值好于一个激活集内小区, 触发 lc事件。
Id事件用来更新激活集最优小区, 当最优小区发生改变时, 触发 Id事件。 当 一个小区的测量值好于一个绝对阈值时, 触发 le事件, 其中, 该绝对阈值可 以由网侧规定。 当一个小区的测量值差于一个绝对阈值时, 触发 If事件, 其 中, 该绝对阈值可以由网侧规定。
在本发明实施例一中, 网络侧设备对 UE进行主载波同频测量配置和辅载 波同频测量配置, 以使所述 UE对主载波对应的监测集和预设的主载波对应的 激活集进行主载波同频测量, 对辅载波对应的监测集进行辅载波同频测量, 分别上报针对主载波和辅载波的同频测量事件。 由于只建立主载波上的激活 集, 而辅载波上只使用监测集, 并且由于监测集中的小区无需与 UE建立 RL连 接, 因此不需要设置辅载波对应的上行载波, 所述 UE只需要设置唯一的上行 载波, 主载波同频测量事件与辅载波同频测量事件均在该上行载波上上报, 从而降低了网络的复杂度。
图 2b为本发明实施例二的多载波组网的移动测量方法的流程图。 如图 2 所示, 该方法包括以下过程。
歩骤 201: UE接收来自网络侧设备的主载波同频测量配置和辅载波同频测 量配置。
歩骤 202: 所述 UE根据所述主载波同频测量配置获取主载波对应的监测 集, 根据所述辅载波同频测量配置获取辅载波对应的监测集。
歩骤 203:所述 UE启动对于包含所述主载波对应的监测集和预设的主载波 对应的激活集的小区集合的主载波同频测量, 生成主载波同频测量事件, 启 动对于包含所述辅载波对应的监测集的小区集合的辅载波同频测量, 生成辅 载波同频测量事件。
歩骤 204:所述 UE在所述主载波上向所述网络侧设备上报主载波同频测量 事件和辅载波同频测量事件。
在本歩骤中, 所述 UE向所述网络侧设备上报主载波同频测量事件和辅载 波同频测量事件, 从而所述网络侧设备能够根据所述 UE上报的上述事件在多 载波组网下对所述 UE进行移动性管理。 在本发明实施例二中, UE接收来自网络侧设备的主载波同频测量配置和 辅载波同频测量配置, 启动对于包含主载波对应的监测集和主载波对应的激 活集的小区集合的主载波同频测量, 启动对于包含辅载波对应的监测集的小 区集合的辅载波同频测量, 向网络侧设备上报主载波同频测量事件和辅载波 同频测量事件。 由于只建立主载波上的激活集, 而辅载波上只使用监测集, 并且由于监测集中的小区无需与 UE建立 RL连接, 因此不需要设置辅载波对应 的上行载波, 所述 UE只需要设置唯一的上行载波, 主载波同频测量事件与辅 载波同频测量事件均在该上行载波上上报, 从而降低了网络的复杂度。
图 3为本发明实施例三的多载波组网的移动测量方法的流程图。 如图 3所 示, 该方法包括以下过程。
歩骤 301: 网络侧设备对 UE进行主载波同频测量配置。
在本歩骤中, 网络侧设备对 UE进行主载波同频测量配置。 该配置中包括 主载波的测量控制信息和所述主载波对应的监测集, 具体地, 网络侧设备通 过向 UE下发主载波的测量控制信息和所述主载波对应的监测集完成该配置过 程。 其中, 该主载波的测量控制信息至少包括主载波同频测量事件的上报条 件。 并且, 测量控制信息还可以包括很多其它信息, 例如, 指示测量是 RSCP 还是 Ec/N0、 指示事件上报周期、 指示测量哪些主载波同频事件等等。 在测量 控制信息中, 还可以包括针对各个主载波同频测量事件的参数, 包括小区的 加权系数, 报告范围等。 网络侧设备通过该配置过程, 使 UE开启对于主载波 的同频测量, 并且通过配置使 UE获得主载波同频测量事件的上报条件。其中, 上述主载波同频测量事件可以包括但不限于以下事件的任意一种或几种的组 合: la事件、 lb事件、 lc事件、 Id事件、 le事件、 If事件。 在本发明实施例 中, 对上述主载波同频测量事件的上报条件不做限制, 网络侧设备可以根据 实际应用的需要灵活设置。
网络侧设备在对所述 UE进行主载波同频测量配置时, 向 UE下发主载波对 应的监测集的小区的列表。 所述 UE根据网络侧设备的配置获取主载波对应的 监测集。 在本发明实施例一以及以下各个实施例中, 网络侧设备可以是无线 网络控制器 (Radio Network Controller, 简称 RNC) 。
歩骤 302:所述 UE对主载波进行同频测量并向所述网络侧设备上报主载波 同频测量事件。 在本歩骤中, 所述 UE启动对于包含所述主载波对应的监测集和预设的主 载波对应的激活集的小区集合的主载波同频测量, 根据网络侧设备下发的主 载波的测量控制信息, 以及主载波对应的激活集和监测集, 对主载波进行同 频测量, 并且, 在测量结果满足主载波同频测量事件的上报条件时, 向所述 网络侧设备上报主载波同频测量事件。 在本步骤中, 主载波对应的监测集是 UE在歩骤 301中获得的;主载波对应的激活集是 UE预先获得的。在本歩骤之前, 网络侧设备通过向 UE下发激活集更新消息, 使 UE获得主载波对应的激活集; 网络侧设备通过 UE对主载波的同频测量和事件上报, 对 UE当前的主载波对应 的激活集进行维护, 也就是在 UE当前的主载波对应的激活集中增加小区或者 删除小区。 激活集中的小区与 UE之间存在无线链路 (Radio Link, 简称 RL) , 其中, RL包括上行链路 (简称 uplink) 和下行链路 (简称 downlink) 。
在本歩骤中, 所述 UE向所述网络侧设备上报主载波同频测量事件, 从而 所述网络侧设备能够根据所述 UE上报的上述事件在多载波组网下对所述 UE进 行移动性管理。
歩骤 303: 所述网络侧设备对 UE进行辅载波同频测量配置。
在本歩骤中, 网络侧设备在获得 UE上报的主载波同频测量事件之后, 对 UE进行辅载波同频测量配置。 触发网络侧设备对 UE进行辅载波同频测量配置 的主载波同频测量事件可以包括但不限于以下事件的任意一种或几种的组 合: la事件、 lb事件、 lc事件、 Id事件、 le事件、 If事件。 具体地, 网络侧 设备通过向 UE下发辅载波的测量控制信息和所述辅载波对应的监测集完成该 配置过程, 该辅载波的测量控制信息包括辅载波同频测量事件的上报条件。 网络侧设备通过该配置过程, 使 UE开启对于辅载波的同频测量, 并且使 UE获 得辅载波同频测量事件的上报条件。 其中, 辅载波同频测量事件可以包括但 不限于以下事件的任意一种或几种的组合: la事件、 lb事件、 lc事件、 Id事 件、 le事件、 If事件。 在本发明实施例中, 对上述辅载波同频测量事件的上 报条件不做限制, 网络侧设备可以根据实际应用的需要灵活设置。
网络侧设备对 UE进行辅载波同频测量配置时, 向 UE下发辅载波对应的监 测集的小区列表。 UE根据所述辅载波同频测量配置获取辅载波对应的监测集。 监测集是 UE连续不断进行测量的小区清单, 监测集中的小区导频的接收信号 码功率 (Received Signal Code Power, 简称 RSCP) 或者码片平均能量 (简 称 Ec/NO ) 值尚未强到可以加入激活集。
歩骤 304:所述 UE对辅载波进行同频测量并向所述网络侧设备上报辅载波 同频测量事件。
在本歩骤中, 所述 UE启动对于包含所述辅载波对应的监测集的小区集合 的辅载波同频测量, 根据辅载波对应的监测集, 对辅载波进行同频测量, 并 且, 在测量结果满足辅载波同频测量事件的上报条件时, 向所述网络侧设备 上报辅载波同频测量事件。
在本歩骤中, 所述 UE向所述网络侧设备上报辅载波同频测量事件, 从而 所述网络侧设备能够根据所述 UE上报的上述事件在多载波组网下对所述 UE进 行移动性管理。
在本发明实施例三中, UE分别上报针对主载波和辅载波的同频测量事件, 从而网络侧设备能够对 UE进行移动性管理, 根据 UE上报的分别针对主载波和 辅载波的同频测量事件, 切换 UE的服务小区, 并将 UE配置为最优的模式。 例 如, 如果 UE支持双频双小区(Dual-Frequency Dual-Cel l , 简称 DF-DC)模式, 则网络侧设备可以将该 UE配置为 DF-DC模式。采用本发明实施例三的方法, 只 建立主载波上的激活集, 而辅载波上只使用监测集, 由于监测集中的小区无 需与 UE建立 RL连接, 因此不需要设置辅载波对应的上行载波, 所述 UE只需要 设置唯一的上行载波, 主载波同频测量事件与辅载波同频测量事件均在该上 行载波上上报, 从而降低了网络的复杂度。 并且, 采用本发明实施例三的技 术方案, 既可以实现在多载波组网下对 UE的移动性管理, 又可以减少 UE的测 量及上报, 从而减小 UE功耗及上行信令开销。
图 4为本发明实施例四的多载波组网的移动测量方法的流程图。 如图 4所 示, 该方法包括以下过程。
歩骤 401 :网络侧设备对 UE进行主载波同频测量配置和辅载波同频测量配 置。
在本歩骤中, 网络侧设备对 UE进行主载波同频测量配置。 具体地, 网络 侧设备通过向 UE下发主载波的测量控制信息和所述主载波对应的监测集完成 该配置过程, 其中, 该主载波的测量控制信息包括主载波同频测量事件的上 报条件。 网络侧设备通过该配置过程, 使 UE开启对于主载波的同频测量, 并 且通过配置使 UE获得主载波同频测量事件的上报条件。 其中, 主载波同频测 量事件可以包括但不限于以下事件的任意一种或几种的组合: la事件、 lb事 件、 lc事件、 Id事件、 le事件、 If事件。 在本发明实施例中, 对上述主载波 同频测量事件的上报条件不做限制, 网络侧设备可以根据实际应用的需要灵 活设置。 网络侧设备在对所述 UE进行主载波同频测量配置时, 向 UE下发主载 波对应的监测集中的小区的列表。 所述 UE根据网络侧设备的配置获取主载波 对应的监测集。
并且, 在本歩骤中, 网络侧设备还对 UE进行辅载波同频测量配置。 具体 地, 网络侧设备通过向 UE下发辅载波的测量控制信息和所述辅载波对应的监 测集完成该配置过程, 该辅载波的测量控制信息包括辅载波同频测量事件的 上报条件。 网络侧设备通过该配置过程, 使 UE获得辅载波同频测量事件的上 报条件。 其中, 辅载波同频测量事件可以包括但不限于以下事件的任意一种 或几种的组合: la事件、 lb事件、 lc事件、 Id事件、 le事件、 If事件。 在本 发明实施例中, 对上述辅载波同频测量事件的上报条件不做限制, 网络侧设 备可以根据实际应用的需要灵活设置。 网络侧设备对 UE进行辅载波同频测量 配置时, 向 UE下发辅载波对应的监测集的小区列表。 UE根据所述辅载波同频 测量配置获取辅载波对应的监测集。 监测集是 UE连续不断进行测量的小区清 单, 监测集中的小区导频的 RSCP或者 Ec/NO值尚未强到可以加入激活集。
歩骤 402:所述 UE对主载波进行同频测量并向所述网络侧设备上报主载波 同频测量事件。
在本歩骤中, 所述 UE启动对于包含所述主载波对应的监测集和预设的主 载波对应的激活集的小区集合的主载波同频测量, 根据网络侧设备下发的主 载波的测量控制信息, 在所述主载波对应的激活集的范围内, 对主载波进行 同频测量, 并且, 在测量结果满足主载波同频测量事件的上报条件时, 向所 述网络侧设备上报主载波同频测量事件。 在本歩骤中, 主载波对应的监测集 是 UE在歩骤 401中获得的; 主载波对应的激活集是 UE预先获得的。在本歩骤之 前, 网络侧设备通过向 UE下发激活集维护消息, 使 UE获得主载波对应的激活 集; 网络侧设备还可以通过 UE对主载波的同频测量和事件上报, 对 UE当前的 主载波对应的激活集进行维护, 也就是在 UE当前的主载波对应的激活集中增 加小区或者删除小区。 激活集中的小区与 UE之间存在无线链路 (Radio Link, 简称 RL),其中, RL包括上行链路(简称 uplink)和下行链路(简称 downlink)。 在本歩骤中, 所述网络侧设备获取所述 UE上报的主载波同频测量事件, 从而所述网络侧设备能够根据所述 UE上报的上述事件在多载波组网下对所述 UE进行移动性管理。
在所述 UE向所述网络侧设备上报主载波同频测量事件之后, 可以直接执 行歩骤 404, 或者, 也可以先执行歩骤 403, 如果歩骤 403的判断结果为否, 再 执行歩骤 404。 在歩骤 404中, UE根据主载波同频测量事件的触发, 对辅载波 进行同频测量, 其中, 触发 UE进行辅载波同频测量的主载波同频测量事件可 以包括但不限于以下事件的任意一种或几种的组合: la事件、 lb事件、 lc事 件、 Id事件、 le事件、 If事件。
歩骤 403:所述 UE判断当前服务基站在辅载波上的覆盖范围是否与在主载 波上的覆盖范围相同。
如果是, 结束流程。 如果否, 执行歩骤 404。
网络侧设备可以预先通过广播或者下发信令的方式向告知 UE如下信息: 宏基站和微基站在主载波上的发射功率以及宏基站和微基站在辅载波上的发 射功率。 在本歩骤中, 所述 UE判断当前服务基站是宏基站还是微基站, 具体 地, 当前服务小区所属的基站即当前服务基站, UE判断当前服务小区属于宏 基站还是微基站。 如果当前服务基站是宏基站, 则所述 UE比较宏基站在主载 波上的发射功率与在辅载波上的发射功率; 如果当前服务基站是微基站, 则 所述 UE比较微基站在主载波上的发射功率与在辅载波上的发射功率如果比较 结果为不同, 则 UE判断当前服务基站在辅载波上的覆盖范围与在主载波上的 覆盖范围不同。
歩骤 404:所述 UE对辅载波进行同频测量并向所述网络侧设备上报辅载波 同频测量事件。
在本歩骤中, 所述 UE启动对于包含所述辅载波对应的监测集的小区集合 的辅载波同频测量, 根据辅载波对应的监测集, 对辅载波进行同频测量, 并 且, 在测量结果满足辅载波同频测量事件的上报条件时, 向所述网络侧设备 上报辅载波同频测量事件。
在本歩骤中, 所述网络侧设备获取所述 UE上报的辅载波同频测量事件, 从而所述网络侧设备能够根据所述 UE上报的上述事件在多载波组网下对所述 UE进行移动性管理。 在本发明实施例四中, UE分别上报针对主载波和辅载波的同频测量事件, 从而网络侧设备能够对 UE进行移动性管理, 根据 UE上报的分别针对主载波和 辅载波的同频测量事件, 切换 UE的服务小区, 并将 UE配置为最优的模式。 例 如, 如果 UE支持 DF-DC模式, 则网络侧设备可以将该 UE配置为 DF-DC模式。 采 用本发明实施例四的方法, 只建立主载波上的激活集, 而辅载波上只使用监 测集, 由于监测集中的小区无需与 UE建立 RL连接, 因此不需要设置辅载波对 应的上行载波, 所述 UE只需要设置唯一的上行载波, 主载波同频测量事件与 辅载波同频测量事件均在该上行载波上上报, 从而降低了网络的复杂度。 并 且, 采用本发明实施例四的技术方案, 既可以实现在多载波组网下对 UE的移 动性管理, 又可以减少 UE的测量及上报, 从而减小 UE功耗及上行信令开销。
图 5为本发明实施例五的网络侧设备的结构示意图。 如图 5所示, 该装置 设备至少包括: 配置单元 51和获取单元 52。
其中, 配置单元 51用于对 UE进行第一载波同频测量配置和第二载波同频 测量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应的 监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启动 对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区 集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所述 第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频 测量事件。 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所述 监测集中的各小区没有无线链路连接。
获取单元 52用于获取所述 UE在所述第一载波上报的第一载波同频测量事 件和第二载波同频测量事件。
在上述技术方案的基础上, 进一歩地, 所述配置单元 51具体用于对 UE进 行第一载波同频测量配置, 以使所述 UE根据所述第一载波同频测量配置启动 对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区 集合的第一载波同频测量, 并具体用于在所述获取单元 52获取所述 UE上报的 第一载波同频测量事件之后, 对所述 UE进行第二载波同频测量配置, 以使所 述 UE根据所述第二载波同频测量配置启动对于包含所述第二载波对应的监测 集的小区集合的第二载波同频测量。
在上述技术方案的基础上, 进一歩地, 所述配置单元 51具体用于对 UE进 行第一载波同频测量配置, 以使所述 UE根据所述第一载波同频测量配置启动 对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区 集合的第一载波同频测量, 并具体用于在所述获取单元 52获取所述 UE上报的 第一载波同频测量事件之前, 对所述 UE进行第二载波同频测量配置, 以使所 述 UE在上报第一载波同频测量事件时启动对于包含所述第二载波对应的监测 集的小区集合的第二载波同频测量。
在上述技术方案的基础上, 进一歩地, 所述配置单元 51具体用于向所述 UE下发第一载波的测量控制信息和所述第一载波对应的监测集, 所述第一载 波的测量控制信息包括第一载波同频测量事件的上报条件, 并具体用于向所 述 UE下发第二载波的测量控制信息和所述第二载波对应的监测集, 所述第二 载波的测量控制信息包括第二载波同频测量事件的上报条件。
在上述技术方案的基础上, 进一歩地, 所述第一载波为主载波, 所述第 二载波为辅载波。
在上述技术方案的基础上, 进一歩地, 所述第一载波同频测量事件和所 述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id 事件、 le事件和 If事件中的至少一项。
本发明实施例五的网络侧设备可以用于执行本发明实施例一至本发明实 施例四所述的多载波组网的移动测量方法, 其具体实现过程和技术效果可以 参照本发明实施例一至本发明实施例四, 此处不再赘述。 图 5对应的网络侧设 备中各单元执行的具体功能可以参见之前方法实施例中的描述。
图 6为本发明实施例六的用户设备的结构示意图。 如图 6所示, 该用户设 备至少包括: 接收单元 61、 获取单元 62、 测量单元 63和上报单元 64。
其中, 接收单元 61用于接收来自网络侧设备的第一载波同频测量配置和 第二载波同频测量配置。
获取单元 62用于根据所述第一载波同频测量配置获取第一载波对应的监 测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集。
测量单元 63用于启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件, 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频 测量, 生成第二载波同频测量事件。 其中, 所述 UE与所述激活集中的各小区 有无线链路连接, 与所述监测集中的各小区没有无线链路连接。
上报单元 64用于在所述第一载波上向所述网络侧设备上报第一载波同频 测量事件和第二载波同频测量事件。
在上述技术方案的基础上, 进一歩地, 所述测量单元 63具体用于在所述 接收单元 61接收来自网络侧设备的第一载波同频测量配置之后, 根据所述第 一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件。 相应地, 所述接收单元 61具体用于在所述上报单元 64向所述网络侧设 备上报第一载波同频测量事件之后, 接收来自所述网络侧设备的第二载波同 频测量配置, 所述测量单元 63具体用于根据所述第二载波同频测量配置启动 对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成 第二载波同频测量事件。
在上述技术方案的基础上, 进一歩地, 所述测量单元 63具体用于在所述 接收单元 61接收来自网络侧设备的第一载波同频测量配置之后, 根据所述第 一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件。 相应地, 所述接收单元 61具体用于在所述上报单元 64向所述网络侧设 备上报第一载波同频测量事件之前, 接收来自网络侧设备的第二载波同频测 量配置, 在所述上报单元 64上报第一载波同频测量事件时启动对于包含所述 第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频 测量事件。
在上述技术方案的基础上, 进一歩地, 所述接收单元 61具体用于接收所 述网络侧设备下发的第一载波的测量控制信息和所述第一载波对应的监测 集, 所述第一载波的测量控制信息包括第一载波同频测量事件的上报条件, 并具体用于接收所述网络侧设备下发的第二载波的测量控制信息和所述第二 载波对应的监测集, 所述第二载波的测量控制信息包括第二载波同频测量事 件的上报条件。
在上述技术方案的基础上, 进一歩地, 所述第一载波为主载波, 所述第 二载波为辅载波。
在上述技术方案的基础上, 进一歩地, 所述测量单元 63具体用于在当前 服务小区所在的服务站点在所述第二载波的小区覆盖范围与在所述第一载波 的小区覆盖范围不同时, 启动对于包含所述第二载波对应的监测集的小区集 合的第二载波同频测量。
在上述技术方案的基础上, 进一歩地, 所述第一载波同频测量事件和所 述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id 事件、 le事件和 If事件中的至少一项。
本发明实施例六的用户设备可以用于执行本发明实施例一至本发明实施 例四所述的多载波组网的移动测量方法, 其具体实现过程和技术效果可以参 照本发明实施例一至本发明实施例四, 此处不再赘述。 图 6对应的用户设备中 各单元执行的具体功能可以参见之前方法实施例中的描述。
图 7为本发明实施例七的网络侧设备的结构示意图。 如图 7所示, 该网络 侧设备至少包括: 发送器 71、 接收器 72和总线 70。
其中, 发送器 71用于对用户设备 UE进行第一载波同频测量配置和第二载 波同频测量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波 对应的监测集,根据所述第二载波同频测量配置获取第二载波对应的监测集, 启动对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的 小区集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含 所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波 同频测量事件。 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与 所述监测集中的各小区没有无线链路连接。
接收器 72用于获取所述 UE在所述第一载波上报的第一载波同频测量事件 和第二载波同频测量事件。
总线 70连接发送器 71和接收器 72, 用于在发送器 71和接收器 72之间进行 数据交换。
在上述技术方案的基础上, 进一歩地, 所述发送器 71具体用于对 UE进行 第一载波同频测量配置, 以使所述 UE根据所述第一载波同频测量配置启动对 于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区集 合的第一载波同频测量, 并具体用于在所述接收器 72获取所述 UE上报的第一 载波同频测量事件之后, 对所述 UE进行第二载波同频测量配置, 以使所述 UE 根据所述第二载波同频测量配置启动对于包含所述第二载波对应的监测集的 小区集合的第二载波同频测量。
在上述技术方案的基础上, 进一歩地, 所述发送器 71具体用于对 UE进行 第一载波同频测量配置, 以使所述 UE根据所述第一载波同频测量配置启动对 于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区集 合的第一载波同频测量, 并具体用于在所述接收器 72获取所述 UE上报的第一 载波同频测量事件之前, 对所述 UE进行第二载波同频测量配置, 以使所述 UE 在上报第一载波同频测量事件时启动对于包含所述第二载波对应的监测集的 小区集合的第二载波同频测量。
在上述技术方案的基础上, 进一歩地, 所述发送器 71具体用于向所述 UE 下发第一载波的测量控制信息和所述第一载波对应的监测集, 所述第一载波 的测量控制信息包括第一载波同频测量事件的上报条件, 并具体用于向所述
UE下发第二载波的测量控制信息和所述第二载波对应的监测集, 所述第二载 波的测量控制信息包括第二载波同频测量事件的上报条件。
在上述技术方案的基础上, 进一歩地, 所述第一载波为主载波, 所述第 二载波为辅载波。
在上述技术方案的基础上, 进一歩地, 所述第一载波同频测量事件和所 述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id 事件、 le事件和 If事件中的至少一项。
本发明实施例七的网络侧设备可以用于执行本发明实施例一至本发明实 施例四所述的多载波组网的移动测量方法, 其具体实现过程和技术效果可以 参照本发明实施例一至本发明实施例四, 此处不再赘述。 本实施例中发送器 71、 接收器 72所执行的具体功能可参见之前方法实施例的描述。
图 8为本发明实施例八的用户设备的结构示意图。 如图 8所示, 该用户设 备至少包括: 接收器 81、 第一处理器 82、 第二处理器 83、 发送器 84和总线 80。
其中, 接收器 81用于接收来自网络侧设备的第一载波同频测量配置和第 二载波同频测量配置。
第一处理器 82用于根据所述第一载波同频测量配置获取第一载波对应的 监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集;
第二处理器 83用于启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件, 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同 频测量, 生成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小 区有无线链路连接, 与所述监测集中的各小区没有无线链路连接;
发送器 84用于在所述第一载波上向所述网络侧设备上报第一载波同频测 量事件和第二载波同频测量事件。
总线 80连接所述接收器 81、 所述第一处理器 82、 所述第二处理器 83和所 述发送器 84, 用于在所述接收器 81、 所述第一处理器 82、 所述第二处理器 83 和所述发送器 84之间进行数据交换。
在上述技术方案的基础上, 进一歩地, 所述第二处理器 83具体用于在所 述接收器 81接收来自网络侧设备的第一载波同频测量配置之后, 根据所述第 一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件。 相应地, 所述接收器 81具体用于在所述发送器 84向所述网络侧设备上 报第一载波同频测量事件之后, 接收来自所述网络侧设备的第二载波同频测 量配置, 所述第二处理器 83具体用于根据所述第二载波同频测量配置启动对 于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第 二载波同频测量事件。
在上述技术方案的基础上, 进一歩地, 所述第二处理器 83具体用于在所 述接收器 81接收来自网络侧设备的第一载波同频测量配置之后, 根据所述第 一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件。 相应地, 所述接收器 81具体用于在所述发送器 84向所述网络侧设备上 报第一载波同频测量事件之前, 接收来自网络侧设备的第二载波同频测量配 置, 在所述发送器 84上报第一载波同频测量事件时启动对于包含所述第二载 波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量事 件。
在上述技术方案的基础上, 进一歩地, 所述接收器 81具体用于接收所述 网络侧设备下发的第一载波的测量控制信息和所述第一载波对应的监测集, 所述第一载波的测量控制信息包括第一载波同频测量事件的上报条件, 并具 体用于接收所述网络侧设备下发的第二载波的测量控制信息和所述第二载波 对应的监测集, 所述第二载波的测量控制信息包括第二载波同频测量事件的 上报条件。
在上述技术方案的基础上, 进一歩地, 所述第一载波为主载波, 所述第 二载波为辅载波。
在上述技术方案的基础上, 进一歩地, 所述第二处理器 83具体用于在当 前服务小区所在的服务站点在所述第二载波的小区覆盖范围与在所述第一载 波的小区覆盖范围不同时, 启动对于包含所述第二载波对应的监测集的小区 集合的第二载波同频测量。
在上述技术方案的基础上, 进一歩地, 所述第一载波同频测量事件和所 述第二载波同频测量事件中的至少一个包括: la事件、 lb事件、 lc事件、 Id 事件、 le事件和 If事件中的至少一项。
本发明实施例八的网络侧设备可以用于执行本发明实施例一至本发明实 施例四所述的多载波组网的移动测量方法, 其具体实现过程和技术效果可以 参照本发明实施例一至本发明实施例四, 此处不再赘述。 本实施例中接收器 81、 第一处理器 82、 第二处理器 83、 发送器 84所执行的功能可参见之前方法 实施例的描述, 本实施例对此不作赘述。
需要说明的是: 对于前述的各方法实施例, 为了简单描述, 故将其都表 述为一系列的动作组合, 但是本领域技术人员应该知悉, 本发明并不受所描 述的动作顺序的限制, 因为依据本发明, 某些歩骤可以采用其他顺序或者同 时进行。 其次, 本领域技术人员也应该知悉, 说明书中所描述的实施例均属 于优选实施例, 所涉及的动作和模块并不一定是本发明所必须的。
在上述实施例中, 对各个实施例的描述都各有侧重, 某个实施例中没有 详述的部分, 可以参见其他实施例的相关描述。
本领域普通技术人员可以理解: 实现上述各方法实施例的全部或部分歩 骤可以通过程序指令相关的硬件来完成。 前述的程序可以存储于一计算机可 读取存储介质中。 该程序在执行时, 执行包括上述各方法实施例的歩骤; 而 前述的存储介质包括: R0M、 RAM, 磁碟或者光盘等各种可以存储程序代码的 介质。
最后应说明的是: 以上各实施例仅用以说明本发明的技术方案, 而非对 其限制; 尽管参照前述各实施例对本发明进行了详细的说明, 本领域的普通 技术人员应当理解:其依然可以对前述各实施例所记载的技术方案进行修改, 或者对其中部分或者全部技术特征进行等同替换; 而这些修改或者替换, 并 不使相应技术方案的本质脱离本发明各实施例技术方案的范围。

Claims

权 利 要 求
1、 一种多载波组网的移动测量方法, 其特征在于, 包括:
网络侧设备对用户设备 UE进行第一载波同频测量配置和第二载波同频测 量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应的监 测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启动对 于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区集 合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所述第 二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测 量事件; 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所述监 测集中的各小区没有无线链路连接;
所述网络侧设备获取所述 UE在所述第一载波上报的第一载波同频测量事 件和第二载波同频测量事件。
2、 根据权利要求 1所述的方法, 其特征在于, 所述网络侧设备对 UE进行 第一载波同频测量配置和第二载波同频测量配置包括:
所述网络侧设备对 UE进行第一载波同频测量配置, 以使所述 UE根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量;
所述网络侧设备在获取所述 UE上报的第一载波同频测量事件之后, 对所 述 UE进行第二载波同频测量配置, 以使所述 UE根据所述第二载波同频测量配 置启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测
3、 根据权利要求 1所述的方法, 其特征在于, 所述网络侧设备对 UE进行 第一载波同频测量配置和第二载波同频测量配置包括:
所述网络侧设备对 UE进行第一载波同频测量配置, 以使所述 UE根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量;
所述网络侧设备在获取所述 UE上报的第一载波同频测量事件之前, 对所 述 UE进行第二载波同频测量配置, 以使所述 UE在上报第一载波同频测量事件 时启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测
4、 根据权利要求 1所述的方法, 其特征在于,
所述网络侧设备对 UE进行第一载波同频测量配置包括: 所述网络侧设备 向所述 UE下发第一载波的测量控制信息和所述第一载波对应的监测集, 所述 第一载波的测量控制信息包括第一载波同频测量事件的上报条件;
所述网络侧设备对 UE进行第二载波同频测量配置包括: 所述网络侧设备 向所述 UE下发第二载波的测量控制信息和所述第二载波对应的监测集, 所述 第二载波的测量控制信息包括第二载波同频测量事件的上报条件。
5、 根据权利要求 1至 4中任意一项所述的方法, 其特征在于,
所述第一载波为主载波, 所述第二载波为辅载波。
6、 根据权利要求 1至 4中任意一项所述的方法, 其特征在于, 所述第一载 波同频测量事件和所述第二载波同频测量事件中的至少一个包括:
la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。
7、 一种多载波组网的移动测量方法, 其特征在于, 包括:
用户设备 UE接收来自网络侧设备的第一载波同频测量配置和第二载波同 频测量配置;
所述 UE根据所述第一载波同频测量配置获取第一载波对应的监测集, 根 据所述第二载波同频测量配置获取第二载波对应的监测集;
所述 UE启动对于包含所述第一载波对应的监测集和预设的第一载波对应 的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量事件, 启 动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生 成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小区有无线链 路连接, 与所述监测集中的各小区没有无线链路连接;
所述 UE在所述第一载波上向所述网络侧设备上报第一载波同频测量事件 和第二载波同频测量事件。
8、 根据权利要求 7所述的方法, 其特征在于, 所述 UE启动对于包含所述 第一载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载 波同频测量, 生成第一载波同频测量事件, 启动对于包含所述第二载波对应 的监测集的小区集合的第二载波同频测量,生成第二载波同频测量事件包括: 所述 UE在接收来自网络侧设备的第一载波同频测量配置之后, 根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件;
所述 UE在向所述网络侧设备上报第一载波同频测量事件之后, 接收来自 所述网络侧设备的第二载波同频测量配置, 根据所述第二载波同频测量配置 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量事件。
9、 根据权利要求 7所述的方法, 其特征在于, 所述 UE启动对于包含所述 第一载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载 波同频测量, 生成第一载波同频测量事件, 启动对于包含所述第二载波对应 的监测集的小区集合的第二载波同频测量,生成第二载波同频测量事件包括: 所述 UE在接收来自网络侧设备的第一载波同频测量配置之后, 根据所述 第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件;
所述 UE在向所述网络侧设备上报第一载波同频测量事件之前, 接收来自 网络侧设备的第二载波同频测量配置, 在上报第一载波同频测量事件时启动 对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量, 生成 第二载波同频测量事件。
10、 根据权利要求 7所述的方法, 其特征在于,
所述 UE接收来自网络侧设备的第一载波同频测量配置包括: 所述 UE接收 所述网络侧设备下发的第一载波的测量控制信息和所述第一载波对应的监测 集, 所述第一载波的测量控制信息包括第一载波同频测量事件的上报条件; 所述 UE接收来自网络侧设备的第二载波同频测量配置包括: 所述 UE接收 所述网络侧设备下发的第二载波的测量控制信息和所述第二载波对应的监测 集, 所述第二载波的测量控制信息包括第二载波同频测量事件的上报条件。
11、 根据权利要求 7至 10中任意一项所述的方法, 其特征在于,
所述第一载波为主载波, 所述第二载波为辅载波。
12、 根据权利要求 7至 10中任意一项所述的方法, 其特征在于, 所述启动 对于包含所述第二载波对应的监测集的小区集合的第二载波同频测量包括: 若当前服务小区所在的服务站点在所述第二载波的小区覆盖范围与在所 述第一载波的小区覆盖范围不同, 则所述 UE启动对于包含所述第二载波对应 的监测集的小区集合的第二载波同频测量。
13、 根据权利要求 7至 10中任意一项所述的方法, 其特征在于, 所述第一 载波同频测量事件和所述第二载波同频测量事件中的至少一个包括:
la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。
14、 一种网络侧设备, 其特征在于, 包括:
配置单元, 用于对用户设备 UE进行第一载波同频测量配置和第二载波同 频测量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应 的监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启 动对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小 区集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所 述第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同 频测量事件; 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所 述监测集中的各小区没有无线链路连接;
获取单元, 用于获取所述 UE在所述第一载波上报的第一载波同频测量事 件和第二载波同频测量事件。
15、 根据权利要求 14所述的设备, 其特征在于,
所述配置单元具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根 据所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预 设的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在 所述获取单元获取所述 UE上报的第一载波同频测量事件之后, 对所述 UE进行 第二载波同频测量配置, 以使所述 UE根据所述第二载波同频测量配置启动对 于包含所述第二载波对应的监测集的小区集合的第二载波同频测量。
16、 根据权利要求 14所述的设备, 其特征在于,
所述配置单元具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根 据所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预 设的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在 所述获取单元获取所述 UE上报的第一载波同频测量事件之前, 对所述 UE进行 第二载波同频测量配置, 以使所述 UE在上报第一载波同频测量事件时启动对 于包含所述第二载波对应的监测集的小区集合的第二载波同频测量。
17、 根据权利要求 14所述的设备, 其特征在于,
所述配置单元具体用于向所述 UE下发第一载波的测量控制信息和所述第 一载波对应的监测集, 所述第一载波的测量控制信息包括第一载波同频测量 事件的上报条件, 并具体用于向所述 UE下发第二载波的测量控制信息和所述 第二载波对应的监测集, 所述第二载波的测量控制信息包括第二载波同频测 量事件的上报条件。
18、 根据权利要求 14至 17中任意一项所述的设备, 其特征在于, 所述第一载波为主载波, 所述第二载波为辅载波。
19、 根据权利要求 14至 17中任意一项所述的设备, 其特征在于, 所述第 一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括:
la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。
20、 一种用户设备 UE, 其特征在于, 包括:
接收单元, 用于接收来自网络侧设备的第一载波同频测量配置和第二载 波同频测量配置;
获取单元, 用于根据所述第一载波同频测量配置获取第一载波对应的监 测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集;
测量单元, 用于启动对于包含所述第一载波对应的监测集和预设的第一 载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测量 事件, 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同频 测量, 生成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小区 有无线链路连接, 与所述监测集中的各小区没有无线链路连接; 上报单元, 用于在所述第一载波上向所述网络侧设备上报第一载波同频测量事件和第二 载波同频测量事件。
21、 根据权利要求 20所述的 UE, 其特征在于,
所述测量单元具体用于在所述接收单元接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收单元具体用于在所述上报单元向所述网络侧设备上报第一载波 同频测量事件之后, 接收来自所述网络侧设备的第二载波同频测量配置, 所 述测量单元具体用于根据所述第二载波同频测量配置启动对于包含所述第二 载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量 事件。
22、 根据权利要求 20所述的 UE, 其特征在于,
所述测量单元具体用于在所述接收单元接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收单元具体用于在所述上报单元向所述网络侧设备上报第一载波 同频测量事件之前, 接收来自网络侧设备的第二载波同频测量配置, 在所述 上报单元上报第一载波同频测量事件时启动对于包含所述第二载波对应的监 测集的小区集合的第二载波同频测量, 生成第二载波同频测量事件。
23、 根据权利要求 20所述的 UE, 其特征在于,
所述接收单元具体用于接收所述网络侧设备下发的第一载波的测量控制 信息和所述第一载波对应的监测集, 所述第一载波的测量控制信息包括第一 载波同频测量事件的上报条件, 并具体用于接收所述网络侧设备下发的第二 载波的测量控制信息和所述第二载波对应的监测集, 所述第二载波的测量控 制信息包括第二载波同频测量事件的上报条件。
24、 根据权利要求 20至 23中任意一项所述的 UE, 其特征在于,
所述第一载波为主载波, 所述第二载波为辅载波。
25、 根据权利要求 20至 23中任意一项所述的 UE, 其特征在于, 所述测量 单元具体用于在当前服务小区所在的服务站点在所述第二载波的小区覆盖范 围与在所述第一载波的小区覆盖范围不同时, 启动对于包含所述第二载波对 应的监测集的小区集合的第二载波同频测量。
26、 根据权利要求 20至 23中任意一项所述的 UE, 其特征在于, 所述第一 载波同频测量事件和所述第二载波同频测量事件中的至少一个包括:
la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。
27、 一种网络侧设备, 其特征在于, 包括:
发送器, 用于对用户设备 UE进行第一载波同频测量配置和第二载波同频 测量配置, 以使所述 UE根据所述第一载波同频测量配置获取第一载波对应的 监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集, 启动 对于包含所述第一载波对应的监测集和预设的第一载波对应的激活集的小区 集合的第一载波同频测量, 生成第一载波同频测量事件, 启动对于包含所述 第二载波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频 测量事件; 其中, 所述 UE与所述激活集中的各小区有无线链路连接, 与所述 监测集中的各小区没有无线链路连接;
接收器, 用于获取所述 UE在所述第一载波上报的第一载波同频测量事件 和第二载波同频测量事件;
总线, 连接所述发送器和所述接收器, 用于在所述发送器和所述接收器 之间进行数据交换。
28、 根据权利要求 27所述的设备, 其特征在于,
所述发送器具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根据 所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设 的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在所 述接收器获取所述 UE上报的第一载波同频测量事件之后, 对所述 UE进行第二 载波同频测量配置, 以使所述 UE根据所述第二载波同频测量配置启动对于包 含所述第二载波对应的监测集的小区集合的第二载波同频测量。
29、 根据权利要求 27所述的设备, 其特征在于,
所述发送器具体用于对 UE进行第一载波同频测量配置, 以使所述 UE根据 所述第一载波同频测量配置启动对于包含所述第一载波对应的监测集和预设 的第一载波对应的激活集的小区集合的第一载波同频测量, 并具体用于在所 述接收器获取所述 UE上报的第一载波同频测量事件之前, 对所述 UE进行第二 载波同频测量配置, 以使所述 UE在上报第一载波同频测量事件时启动对于包 含所述第二载波对应的监测集的小区集合的第二载波同频测量。
30、 根据权利要求 27所述的设备, 其特征在于,
所述发送器具体用于向所述 UE下发第一载波的测量控制信息和所述第一 载波对应的监测集, 所述第一载波的测量控制信息包括第一载波同频测量事 件的上报条件, 并具体用于向所述 UE下发第二载波的测量控制信息和所述第 二载波对应的监测集, 所述第二载波的测量控制信息包括第二载波同频测量 事件的上报条件。
31、 根据权利要求 27至 29中任意一项所述的设备, 其特征在于, 所述第一载波为主载波, 所述第二载波为辅载波。
32、 根据权利要求 27至 29中任意一项所述的设备, 其特征在于, 所述第 一载波同频测量事件和所述第二载波同频测量事件中的至少一个包括:
la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。
33、 一种用户设备 UE, 其特征在于, 包括:
接收器, 用于接收来自网络侧设备的第一载波同频测量配置和第二载波 同频测量配置;
第一处理器, 用于根据所述第一载波同频测量配置获取第一载波对应的 监测集, 根据所述第二载波同频测量配置获取第二载波对应的监测集;
第二处理器, 用于启动对于包含所述第一载波对应的监测集和预设的第 一载波对应的激活集的小区集合的第一载波同频测量, 生成第一载波同频测 量事件, 启动对于包含所述第二载波对应的监测集的小区集合的第二载波同 频测量, 生成第二载波同频测量事件; 其中, 所述 UE与所述激活集中的各小 区有无线链路连接, 与所述监测集中的各小区没有无线链路连接;
发送器, 用于在所述第一载波上向所述网络侧设备上报第一载波同频测 量事件和第二载波同频测量事件;
总线, 连接所述接收器、 所述第一处理器、 所述第二处理器和所述发送 器, 用于在所述接收器、 所述第一处理器、 所述第二处理器和所述发送器之 间进行数据交换。
34、 根据权利要求 33所述的 UE, 其特征在于,
所述第二处理器具体用于在所述接收器接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收器具体用于在所述发送器向所述网络侧设备上报第一载波同频 测量事件之后, 接收来自所述网络侧设备的第二载波同频测量配置, 所述第 二处理器具体用于根据所述第二载波同频测量配置启动对于包含所述第二载 波对应的监测集的小区集合的第二载波同频测量, 生成第二载波同频测量事 件。
35、 根据权利要求 33所述的 UE, 其特征在于,
所述第二处理器具体用于在所述接收器接收来自网络侧设备的第一载波 同频测量配置之后, 根据所述第一载波同频测量配置启动对于包含所述第一 载波对应的监测集和预设的第一载波对应的激活集的小区集合的第一载波同 频测量, 生成第一载波同频测量事件;
所述接收器具体用于在所述发送器向所述网络侧设备上报第一载波同频 测量事件之前, 接收来自网络侧设备的第二载波同频测量配置, 在所述发送 器上报第一载波同频测量事件时启动对于包含所述第二载波对应的监测集的 小区集合的第二载波同频测量, 生成第二载波同频测量事件。
36、 根据权利要求 33所述的 UE, 其特征在于,
所述接收器具体用于接收所述网络侧设备下发的第一载波的测量控制信 息和所述第一载波对应的监测集, 所述第一载波的测量控制信息包括第一载 波同频测量事件的上报条件, 并具体用于接收所述网络侧设备下发的第二载 波的测量控制信息和所述第二载波对应的监测集, 所述第二载波的测量控制 信息包括第二载波同频测量事件的上报条件。
37、 根据权利要求 33至 36中任意一项所述的 UE, 其特征在于,
所述第一载波为主载波, 所述第二载波为辅载波。
38、 根据权利要求 33至 36中任意一项所述的 UE, 其特征在于, 所述第二 处理器具体用于在当前服务小区所在的服务站点在所述第二载波的小区覆盖 范围与在所述第一载波的小区覆盖范围不同时, 启动对于包含所述第二载波 对应的监测集的小区集合的第二载波同频测量。
39、 根据权利要求 33至 36中任意一项所述的 UE, 其特征在于, 所述第一 载波同频测量事件和所述第二载波同频测量事件中的至少一个包括:
la事件、 lb事件、 lc事件、 Id事件、 le事件和 If事件中的至少一项。
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