KR102679873B1 - Cell operation automatic optimization method and system thereof based traffic demand in radio access network - Google Patents

Abstract

The present invention relates to a method and system for automatically optimizing cell operation according to traffic demand in a wireless access network. According to the present invention, in order to overcome the disadvantage of maintaining the cell configuration in a fixed form in the existing radio access network (RAN), a flexible cell configuration method between DU and RU is provided considering traffic demand, thereby improving traffic offloading and power consumption. Effects such as savings, provision of low-latency services, and response to failures can be expected.

Description

Method and system for automatically optimizing cell operation according to traffic demand in a wireless access network {CELL OPERATION AUTOMATIC OPTIMIZATION METHOD AND SYSTEM THEREOF BASED TRAFFIC DEMAND IN RADIO ACCESS NETWORK}

The present invention relates to a method and system for automatically optimizing cell operation according to traffic demand in a wireless access network.

Figure 1 is a diagram showing the general 4G and 5G network structure and interface. In general, base station equipment for mobile communication services such as 4G (LTE) and 5G (NR) is connected to a backhaul and includes a DU (Digital Unit) that processes data. It consists of RU (Radio Unit) that transmits and receives wireless signals, and they are linked through the fronthaul interface. RU includes an Active Antenna Unit (AAU). One DU supports one or more cells and can provide services to users through RUs linked to it. DU is connected to RU through different physical ports for each cell.

The CPRI fronthaul interface used in 4G uses its own specifications for each base station manufacturer, and when building a fronthaul, DU and RU are connected 1:1, and multiplexing/demultiplexing is used using different optical wavelengths. ) WDM (Wavelength Division Multiplexing) technology was used. In this way, when laying a 1:1 line between DUs and RUs or configuring a WDM-based fronthaul, there is a disadvantage in that the flexibility of interconnection between DUs and RUs is reduced because operation is only possible for DU-specific cells linked to the corresponding RU/AAU.

On the other hand, in 5G, the eCPRI fronthaul interface based on Ethernet packet frames is standardized and used. In 5G, the use of fronthaul equipment (fronthaul gateway (FHGW)/fronthaul multiplexer (FHM), etc.) that performs functions such as switching in the fronthaul section is being discussed, taking advantage of the fact that the eCPRI interface follows the Ethernet packet frame. there is. It performs the function of multiplexing/demultiplexing Ethernet packets and can perform a switching function to ensure that the appropriate fronthaul signal is transmitted for each port. In other words, the RU is not directly connected to a specific cell port of the DU, but eCPRI packets are aggregated and connected between the DU and the fronthaul equipment, and the fronthaul is branched between the fronthaul equipment and the RU, so the cells between the DU and RU are connected. There is an advantage that the linkage can be changed flexibly. Therefore, there is a need to specify a cell operation optimization plan that utilizes these advantages.

The present invention aims to solve the above-described needs and/or problems.

In addition, in order to overcome the disadvantage of having to maintain a fixed cell configuration in the existing radio access network (RAN), the present invention provides a flexible cell configuration method between DUs and RUs considering traffic demand in a wireless access network that can be implemented to meet traffic demand. The purpose is to provide a method and system for automatically optimizing cell operation.

According to one aspect of a method for automatically optimizing cell operation according to traffic demand in a wireless access network according to the present invention to achieve the above object, a wireless access network including a digital unit (DU), fronthaul equipment, and wireless unit (RU) ( RAN) component equipment periodically transmitting status messages for wireless access network monitoring to the network management system through a management plane (M-Plane); The network management system includes determining whether the digital unit has a failure based on a status message for wireless access network monitoring transmitted from the wireless access network configuration equipment; When a failure of the digital unit is detected, the network management system links a wireless unit that was linked with the digital unit with another digital unit, and when a failure of the digital unit is not detected, determining cell operation mode conversion in consideration of traffic demand. ; And when the network management system determines that a cell configuration change is necessary as a result of determining cell operation mode conversion in consideration of interconnection with other digital units or the traffic demand, it sends a configuration message for changing wireless access network settings to the management plane. It may include transmitting to the wireless access network configuration devices.

In the step of the wireless access network configuration equipment including the digital unit, fronthaul equipment, and wireless unit periodically transmitting a status message for wireless access network monitoring to the network management system through the management plane, the status message for wireless access network monitoring includes PCI (Physical Cell ID), frequency usage indicator indicating the number of resource blocks used, status indicator indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit, fault ID, IP address , Port ID, and cell operation mode information may be included.

When a failure of the digital unit is detected, the network management system links a wireless unit that was linked with the digital unit with another digital unit, and when a failure of the digital unit is not detected, determining cell operation mode conversion in consideration of traffic demand. In this case, the network management system converts the digital unit, fronthaul equipment, and wireless unit settings to single cell mode when the traffic for each digital unit exceeds a preset specific upper limit standard (H), and the traffic for each digital unit converts the digital unit to a preset specific upper limit standard (H). If it is below the lower limit standard (L), the digital unit, fronthaul equipment, and wireless unit settings can be converted to the same cell mode.

If the network management system determines that a cell configuration change is necessary as a result of determining cell operation mode conversion in consideration of interconnection with other digital units or the traffic demand, it sends a configuration message for changing wireless access network settings through the management plane. In the step of transmitting to the wireless access network configuration devices, the configuration message for changing the wireless access network settings includes a PCI (Physical Cell ID), a status setting indicator indicating active mode or standby mode for the digital unit, fronthaul equipment, and wireless unit. , a cell mode setting indicator indicating single cell mode or same cell mode, IP address, and port ID information may be included.

The network management system may further include turning off or switching to standby mode a digital unit that does not need to be linked to a wireless unit according to the conversion to the same cell mode.

Meanwhile, according to one aspect of the system for automatically optimizing cell operation according to traffic demand in a wireless access network according to the present invention to achieve the above object, status messages for wireless access network monitoring are periodically sent through the management plane (M-Plane). Radio access network (RAN) configuration equipment including a transmitting digital unit (DU), fronthaul equipment, and radio unit (RU); and a network management system that determines whether or not there is a failure of the digital unit based on a status message for monitoring the wireless access network transmitted from the wireless access network configuration equipment, wherein the network management system detects a failure of the digital unit. The wireless unit that was linked with the digital unit is linked with another digital unit, and if a failure of the digital unit is not detected, the cell operation mode conversion is determined considering the traffic demand, and the cell operation mode conversion is determined by considering the linkage with the other digital unit or the traffic demand. If it is determined that a cell configuration change is necessary according to the result of deciding to change the cell operation mode, a configuration message for changing the wireless access network settings may be transmitted to the wireless access network configuration devices through the management plane.

Status messages for monitoring the wireless access network include PCI (Physical Cell ID), a frequency usage indicator indicating the number of resource blocks used, and a status indicator indicating the active mode or standby mode of the digital unit, fronthaul equipment, and wireless unit. , Fault ID, IP address, Port ID, and cell operation mode information may be included.

The network management system converts the digital unit, fronthaul equipment, and wireless unit settings to single cell mode when the traffic for each digital unit exceeds a certain preset upper limit standard (H), and the traffic for each digital unit is based on a certain preset lower limit standard. In cases below (L), the digital unit, fronthaul equipment, and wireless unit settings can be converted to the same cell mode.

The configuration message for changing the wireless access network settings includes PCI (Physical Cell ID), a status setting indicator indicating active mode or standby mode for the digital unit, fronthaul equipment, and wireless unit, and a cell mode indicating single cell mode or same cell mode. At least one of a configuration indicator, IP address, and port ID information may be included.

According to the conversion to the same cell mode, the network management system can switch the digital unit that does not need to be linked with the wireless unit to power off (OFF) or standby mode.

According to another aspect of the method for automatically optimizing cell operation according to traffic demand in a wireless access network according to the present invention to achieve the above object, a wireless access network including a digital unit (DU), fronthaul equipment, and wireless unit (RU) RAN) component equipment periodically transmitting status messages for wireless access network monitoring to a service management coordinator (SMO) through the O1 interface; Non-real time RIC of the service management coordinator determining a policy for cell optimization based on information collected in the service management coordinator through an O1 interface; The non-real-time controller transmitting a message for the determined cell optimization policy to a near-real time controller (Near-Real time RIC) through the A1 interface; the close real-time controller determining cell optimization parameters according to a policy determined by the non-real-time controller; And the proximity real-time controller may include transmitting a configuration message for cell configuration change to the wireless access network configuration devices through the E2 interface.

In the step where the wireless access network configuration equipment including the digital unit, fronthaul equipment, and wireless unit periodically transmits a status message for wireless access network monitoring to the service management coordinator through the O1 interface, the status message for wireless access network monitoring includes PCI (Physical Cell ID), frequency usage indicator indicating the number of resource blocks used, status indicator indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit, fault ID, IP address , Port ID, and cell operation mode information may be included.

In the step of determining a policy for cell optimization based on information collected by the service management coordinator through the O1 interface, the non-real-time controller of the service management coordinator determines the traffic for each digital unit. If the traffic for each digital unit is below the specific upper limit standard (H) set, the digital unit, fronthaul equipment, and wireless unit settings are converted to single cell mode. If the traffic for each digital unit is below the certain preset lower limit standard (L), the digital unit and fronthaul equipment and wireless unit settings are converted to single cell mode. Equipment and wireless unit settings can be converted to same cell mode.

In the step of transmitting a message for the determined cell optimization policy to the adjacent real-time controller through the A1 interface, the non-real-time controller includes digital unit traffic for cell mode conversion of single cell mode or same cell mode. Upper and lower limit standards, PCI (Physical Cell ID) for each wireless access network equipment and port, frequency usage indicator indicating the number of resource blocks used, status indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit. At least one of an indicator, fault ID, IP address, port ID, and cell operation mode information may be included.

In the step of determining cell optimization parameters, the close real-time controller determines cell optimization parameters according to the policy determined by the non-real-time controller. ID) and cell operation mode, at least one cell optimization parameter may be determined.

In the step of transmitting a configuration message for cell configuration change to the wireless access network configuration equipment through the E2 interface, the close real-time controller transmits a configuration message for cell configuration change, including PCI (Physical Cell ID), digital unit, and fronthaul. At least one of the following information may be included: a status setting indicator indicating active mode or standby mode for equipment and wireless units, a cell mode setting indicator indicating single cell mode or same cell mode, IP address, and port ID information. .

The non-real-time controller of the service management coordinator may further include a step of turning off or switching to standby mode a digital unit that does not need to be linked with a wireless unit according to the conversion to the same cell mode.

Meanwhile, according to another aspect of the system for automatically optimizing cell operation according to traffic demand in a wireless access network according to the present invention to achieve the above object, the service management coordinator (SMO) periodically sends status messages for wireless access network monitoring through the O1 interface. ) Radio access network (RAN) configuration equipment including a digital unit (DU), fronthaul equipment, and radio unit (RU) that transmits to ); A non-real-time controller of the service management coordinator that determines a policy for cell optimization based on the information collected in the service management coordinator through the O1 interface and transmits a message for the determined cell optimization policy through the A1 interface. time RIC); and receives a message for a cell optimization policy transmitted from the non-real-time controller, determines cell optimization parameters according to the policy determined by the non-real-time controller, and sends a configuration message for cell configuration change to the wireless access network configuration equipment through the E2 interface. It may include a Near-Real time RIC that transmits to .

Status messages for monitoring the wireless access network include PCI (Physical Cell ID), a frequency usage indicator indicating the number of resource blocks used, and a status indicator indicating the active mode or standby mode of the digital unit, fronthaul equipment, and wireless unit. , Fault ID, IP address, Port ID, and cell operation mode information may be included.

The non-real-time controller of the service management coordinator converts the digital unit, fronthaul equipment, and wireless unit settings to single cell mode when the traffic for each digital unit is higher than a certain preset upper limit standard (H), and the traffic for each digital unit is preset. If it is below a certain lower limit standard (L), the digital unit, fronthaul equipment, and wireless unit settings can be converted to the same cell mode.

The message for the cell optimization policy includes digital unit traffic upper and lower limit standards for cell mode conversion of single cell mode or same cell mode, PCI (Physical Cell ID) for each wireless access network equipment and port, and number of resource blocks used. At least one of a frequency usage indicator indicating a frequency usage indicator, a status indicator indicating the active mode or standby mode of the digital unit, fronthaul equipment, and wireless unit, a fault ID, an IP address, a port ID, and cell operation mode information. Information may be included.

The proximity real-time controller may determine at least one cell optimization parameter among the wireless access network configuration equipment, PCI (Physical Cell ID) for each port, and cell operation mode according to the policy determined by the non-real-time controller.

The configuration message for changing the cell configuration includes PCI (Physical Cell ID), a status setting indicator indicating active mode or standby mode for the digital unit, fronthaul equipment, and wireless unit, and a cell mode setting indicating single cell mode or same cell mode. At least one of indicator, IP address, and port ID information may be included.

The non-real-time controller of the service management coordinator may switch the digital unit that does not need to be linked with the wireless unit to power off or standby mode according to the conversion to the same cell mode.

The effect according to an embodiment of the present invention will be described as follows.

According to the present invention, in order to overcome the disadvantage of maintaining the cell configuration in a fixed form in the existing radio access network (RAN), a flexible cell configuration method between DU and RU is provided considering traffic demand, thereby improving traffic offloading and power consumption. Effects such as savings, provision of low-latency services, and response to failures can be expected.

The accompanying drawings, which are included as part of the detailed description to aid understanding of the present invention, provide embodiments of the present invention, and together with the detailed description, explain technical features of the present invention.
Figure 1 is a diagram showing a general 4G and 5G network structure and interface.
Figure 2 is a diagram showing the equipment configuration of a radio access network (RAN) according to an embodiment of the present invention.
Figure 3 is a diagram showing an example of a cell configuration change process according to an embodiment of the present invention.
Figure 4 is a diagram showing an example of O-RAN or OpenRAN architecture according to another embodiment of the present invention.
Figure 5 is a diagram showing an example of a cell configuration change process in O-RAN architecture according to another embodiment of the present invention.

Hereinafter, embodiments disclosed in the present invention will be described in detail with reference to the attached drawings. However, identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted. The suffixes “module” and “part” for components used in the following description are given or used interchangeably only for the ease of preparing the specification, and do not have distinct meanings or roles in themselves. Additionally, in describing the embodiments disclosed in the present invention, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in the present invention, the detailed descriptions will be omitted. In addition, the attached drawings are only for easy understanding of the embodiments disclosed in the present invention, and the technical idea disclosed in the present invention is not limited by the attached drawings, and all changes included in the spirit and technical scope of the present invention are not limited. , should be understood to include equivalents or substitutes.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Figure 2 is a diagram showing the equipment configuration of a radio access network (RAN) according to an embodiment of the present invention.

As shown, in the radio access network (RAN) equipment configuration for explaining the operating method of the present invention, a plurality of digital units (DU) may exist in a digital unit pool (DU pool 100). Each DU is connected to an aggregation switch to multiplex/demultiplex the fronthaul signal, which passes through the fronthaul equipment (fronthaul gateway (FHGW)/fronthaul multiplexer (FHM)) 200 to the wireless unit (RU, It can be connected to Radio Unit (300). In the fronthaul equipment 200, fronthaul signals are also multiplexed/demultiplexed so that fronthaul signals can be exchanged with each RU. In addition, there is a network management system 400 for managing radio access network (RAN) equipment such as DU, RU, and fronthaul equipment, which performs monitoring and setting functions such as performance/failure of the radio access network (RAN) equipment. You can. The network management system 400 may have a radio access network (RAN) controller for RAN optimization settings based on the collected information, or a radio access network (RAN) controller separate from the network management system 400. It may exist.

The present invention proposes a flexible cell interworking method according to traffic demand, and the operation method for this will be described in detail with reference to the attached FIG. 3.

Figure 3 is a diagram showing an example of a cell configuration change process according to an embodiment of the present invention.

As shown, radio access network (RAN) components such as RU/fronthaul equipment/DU can transmit status messages to the network management system periodically or when an event (failure, etc.) occurs through the management plane (M-Plane). . Management plane (M-Plane) messages for radio access network (RAN) monitoring include PCI (Physical Cell ID), frequency usage indicator (number of resource blocks used), and status indicator (Active/Standby) for DU/fronthaul equipment/RU. mode), Fault ID, IP address, Port ID, cell operation mode, etc. may be included. In addition, the management plane (M-Plane) message for radio access network (RAN) monitoring can be directly transmitted to the network management system by each RU, fronthaul device, and DU device, or through RU→Fronthaul device→DU cascade transmission. You can also pass it on.

Subsequently, if a DU failure is detected in the network management system, the RU that was linked to the corresponding DU can be linked to another DU. However, if a DU failure is not detected in the network management system, the cell operation mode can be converted considering traffic demand. That is, if the traffic for each DU is above a certain upper limit standard (H), the DU, fronthaul equipment, and RU settings can be converted to single cell mode. On the other hand, if the traffic for each DU is below a certain lower limit standard (L), the DU, fronthaul equipment, and RU settings can be converted to the same cell mode. Here, the single cell mode is a mode in which a RU uses a cell exclusively and requires handover between RUs in other cells, and the same cell mode is a mode in which two or more RUs use the same cell and handover between RUs within the same cell is unnecessary. It can mean.

Next, the network management system can determine a cell interconnection optimization configuration plan considering DU failure status and traffic demand. That is, if it is determined that a cell configuration change is not necessary, the current status can be maintained, and if a cell configuration change is necessary, a DU change/single cell mode change/same cell mode change, etc. can be decided.

Subsequently, if the network management system determines that a cell configuration change is necessary, a configuration message to perform this change can be delivered to the DU/fronthaul equipment/RU through the management plane (M-Plane). Here, the management plane (M-Plane) message for changing radio access network (RAN) settings includes PCI (Physical Cell ID), status setting indicator for DU/fronthaul equipment/RU (Active/Standby mode), and cell mode setting indicator. (Single cell mode/same cell mode), IP address, Port ID, etc. may be included.

In addition, the management plane (M-Plane) message for changing radio access network (RAN) settings can be directly delivered by the network management system to each RU, fronthaul device, and DU device, and is transmitted in a cascade from DU → fronthaul device → RU. It can also be delivered through . And, depending on the same cell mode operation, DUs that do not need interworking with the RU may be turned off or switched to standby mode.

The present invention configured in this way can be applied to O-RAN or OpenRAN architecture, and its description is as follows.

Figure 4 is a diagram showing an example of O-RAN or OpenRAN architecture according to another embodiment of the present invention.

As shown, the O-RAN or OpenRAN architecture is being standardized in the O-RAN Alliance and its main features include virtualization (cloudization), open interface, and RAN intelligent controller. In the O-RAN architecture, the Service Management and Orchestration (SMO) framework is responsible for faults, configuration, accounting, performance, etc. of radio access network (RAN) equipment. Monitoring and management functions such as security can be performed. This can be implemented through each radio access network (RAN) equipment (DU/fronthaul equipment/RU) and O1 interface.

The Non-Real time RIC (RAN Intelligent Controller) can establish policies for optimized network configuration based on radio access network (RAN) monitoring results.

The Near-Real time RIC can be linked with the Non-Real time RIC through the A1 interface, and is connected to the actual wireless access network based on the policy established by the Non-Real time RIC. It can play a role in controlling (RAN) equipment, and this can be done through the E2 interface.

Embodiments of the present invention applicable to the O-RAN architecture are as follows, and will be described in detail with reference to the attached FIG. 5.

Figure 5 is a diagram showing an example of a cell configuration change process in O-RAN architecture according to another embodiment of the present invention.

As shown, radio access network (RAN) components such as RU/fronthaul equipment/DU can transmit status messages to the service management coordinator (SMO) periodically or when an event (failure, etc.) occurs through the O1 interface. Here, the O1 message for radio access network (RAN) monitoring includes PCI (Physical Cell ID), frequency usage indicator (number of resource blocks used), status indicator for DU/fronthaul equipment/RU (Active/Standby mode), and Fault. Information such as ID, IP address, Port ID, and cell operation mode may be included. The O1 message may be transmitted directly to the service management coordinator (SMO) by each RU, fronthaul device, and DU device, or RU → fronthaul device. →It can also be transmitted through DU cascade transmission.

Subsequently, the non-real time controller (Non-Real time RIC) can establish a policy for cell optimization based on the information collected by the Service Management Orchestrator (SMO) through the O1 interface. In other words, it is possible to set upper and lower limits for DU traffic for cell mode (single cell mode/same cell mode) conversion. If the traffic for each DU is above a certain upper limit standard (H), the DU, fronthaul equipment, and RU settings can be converted to single cell mode. However, if the traffic for each DU is below a certain lower limit standard (L), the DU, fronthaul equipment, and RU settings can be converted to the same cell mode.

Subsequently, the cell optimization policy determined by the Non-Real time RIC can be transmitted to the Near-Real time RIC through the A1 interface. Here, the message transmitted through the A1 interface includes DU traffic upper and lower limit standards for cell mode (single cell mode/same cell mode) conversion, radio access network (RAN) equipment and PCI (Physical Cell ID) for each port, and frequency usage indicator ( Number of Resource Blocks used), status indicator for DU/fronthaul equipment/RU (Active/Standby mode), Fault ID, IP address, Port ID, cell operation mode, etc. may be included.

Next, cell optimization parameters can be determined in a near-real time RIC. In other words, the Near-Real time RIC operates PCI and cells for each radio access network (RAN) equipment (RU/fronthaul equipment/DU) and port according to the policy determined by the Non-Real time RIC. You can decide the mode.

Subsequently, the near-real time controller (Near-Real time RIC) can transmit a configuration message for changing the cell configuration to the radio access network (RAN) equipment (RU/fronthaul equipment/DU) through the E2 interface. Here, the E2 message for changing radio access network (RAN) settings includes PCI (Physical Cell ID), status setting indicator for DU/fronthaul equipment/RU (Active/Standby mode), and cell mode setting indicator (single cell mode/same Cell mode), IP address, Port ID, etc. may be included.

In addition, the E2 message for changing radio access network (RAN) settings can be directly transmitted by the near-real time RIC to each RU, fronthaul device, and DU device, and is transmitted in cascade from DU → fronthaul equipment → RU. It can also be delivered through . Additionally, DUs that do not need interworking with RUs may be switched off or switched to standby mode according to same-cell mode operation.

As described above, the present invention can provide a flexible cell configuration method between DUs and RUs, and the cell configuration between DUs and RUs can be changed to single cell mode or same cell mode. That is, when traffic demand is high, RUs can be operated in single cell mode, and when traffic demand is low, RUs can be operated in same cell mode. Additionally, when a specific DU failure occurs, it can be replaced with another DU and linked with fronthaul equipment and RU.

In addition, the management plane (M-plane) message/O1 message delivered from the DU/fronthaul gateway/RU to the network management system (or RAN controller) for traffic and failure monitoring purposes includes PCI (Physical Cell ID) and frequency usage indicator ( Number of Resource Blocks used), status indicator for DU/fronthaul equipment/RU (Active/Standby mode), Fault ID, IP address, Port ID, cell operation mode, etc. may be included.

In addition, the O1 message for radio access network (RAN) monitoring includes PCI (Physical Cell ID), frequency usage indicator (number of resource blocks used), status indicator for DU/fronthaul equipment/RU (Active/Standby mode), and Fault. Information such as ID, IP address, Port ID, and cell operation mode may be included.

In addition, the management plane (M-plane) message sent from the network management system (or RAN controller) to the DU/fronthall gateway/RU to change radio access network (RAN) settings includes PCI (Physical Cell ID), DU/fronthall, etc. Information such as status setting indicator (Active/Standby mode) for hall equipment/RU, cell mode setting indicator (single cell mode/same cell mode), IP address, Port ID, etc. may be included.

In addition, the A1 message transmitted from the Non-Real time RIC to the Near-Real time RIC includes the DU traffic upper and lower limit standards for cell mode (single cell mode/same cell mode) conversion, wireless PCI (Physical Cell ID) for each access network (RAN) equipment and port, frequency usage indicator (number of resource blocks used), status indicator for DU/fronthall equipment/RU (Active/Standby mode), Fault ID, IP address, Information such as Port ID and cell operation mode may be included.

In addition, the E2 message for changing radio access network (RAN) settings includes PCI (Physical Cell ID), status setting indicator for DU/fronthaul equipment/RU (Active/Standby mode), and cell mode setting indicator (single cell mode/same Cell mode), IP address, Port ID, etc. may be included.

In addition, when a surplus DU is generated according to the same cell mode operation by changing the cell settings, the surplus DU can be turned off or switched to standby mode to reduce unnecessary power consumption.

Of course, the present invention is not limited to 5G and can be used in other networks that can implement the operating method of the present invention. For example, in a 4G network, the fronthaul can be configured by multiplexing/demultiplexing, as in the network configuration considered in the present invention, and the cell operation modes can be varied in the DU and fronthaul equipment. In addition, even if fronthaul multiplexing/demultiplexing is not performed using fronthaul equipment (DU, RU 1:1 line construction), the cell mode can be changed for each fronthaul port within a single DU. In other words, in a situation where there are multiple physical ports for fronthaul interworking within a single DU and each port is configured with a 1:1 fronthaul line with each RU, the cell operation mode between RUs connected to it within a single DU is You can change it.

The network management system monitors traffic to determine the optimized cell configuration, and changes the settings of radio access network (RAN) configuration equipment such as DU, fronthaul equipment, and RU through the management plane (M-plane) to configure the corresponding cell. You can. In other words, in the network management system, the settings of DU, fronthaul equipment, and RU can be individually changed through the management plane (M-plane), or in the network management system, the DU can be changed through the management plane (M-plane) and the settings can be changed through the DU. Fronthaul equipment and RU settings can be changed (Cascade method). In addition, the E2 message for changing radio access network (RAN) settings can be directly transmitted by the near-real time RIC to each RU, fronthaul device, and DU device, and is transmitted in cascade from DU → fronthaul equipment → RU. It can also be delivered through .

According to the above-described configuration, the present invention provides a flexible cell configuration method between DU and RU in consideration of traffic demand, and through this, the following effects are expected to be achieved, such as traffic offloading, power consumption reduction, low-latency service provision, and failure response. You can.

As an effect of traffic offloading, when traffic demand is high, each RU can be set as an independent cell to distribute traffic to multiple cells and improve overall cell capacity.

In addition, as an effect of reducing power consumption, when traffic demand is low, unnecessary power consumption can be reduced by setting several RUs to the same cell and turning unnecessary DUs to power OFF or change to standby mode.

In addition, as an effect of minimizing handover (providing low-delay services), service interruption or delay through minimizing handover can be prevented by expanding the coverage of a single cell by setting multiple RUs to the same cell.

In addition, as a failure response effect, when a failure occurs in a specific DU, the service can be provided by replacing the RU linked to it with another DU configured with a fronthaul.

The present invention described above can be implemented as computer-readable code on a program-recorded medium. Computer-readable media includes all types of recording devices that store data that can be read by a computer system. Examples of computer-readable media include HDD (Hard Disk Drive), SSD (Solid State Disk), SDD (Silicon Disk Drive), ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage device, etc. This also includes those implemented in the form of carrier waves (e.g., transmission via the Internet). Accordingly, the above detailed description should not be construed as restrictive in all respects and should be considered illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

100: digital unit pool
200: Fronthaul equipment
300: wireless unit
400: Network management system

Claims (24)

A method of automatically optimizing cell operation according to the traffic demand of a network management system in a wireless access network,
Periodically receiving status messages for radio access network monitoring from radio access network (RAN) components including a digital unit (DU), fronthaul equipment, and radio unit (RU) through a management plane (M-Plane);
determining whether the digital unit has a failure based on a status message for wireless access network monitoring transmitted from the wireless access network configuration equipment;
When a failure of the digital unit is detected, linking a wireless unit that was linked with the corresponding digital unit with another digital unit;
If a failure of the digital unit is not detected, determining a cell operation mode in consideration of traffic demand; and
When it is determined that a cell configuration change is necessary according to the linkage with the other digital unit and the determined cell operation mode, transmitting a configuration message for changing the wireless access network settings to the wireless access network configuration devices through the management plane; ,
The cell operation mode is,
If the traffic of the digital unit is more than the preset upper limit standard (H), single cell mode is determined in which one wireless unit uses the cell exclusively,
If the traffic of the digital unit is below the preset lower limit standard (L), the same cell mode is determined in which two or more wireless units use the same cell,
When the cell operation mode is determined to be the same cell mode, the digital unit that does not need interworking with the wireless unit is turned off or switched to standby mode,
Method for automatically optimizing cell operation. According to paragraph 1,
The status message for monitoring the wireless access network is,
PCI (Physical Cell ID), frequency usage indicator indicating the number of resource blocks used, status indicator indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit, fault ID, IP address , Port ID, and cell operation mode information, characterized in that it includes at least one of the following information,
Method for automatically optimizing cell operation. delete According to paragraph 1,
The configuration message for changing the wireless access network settings is:
PCI (Physical Cell ID), status setting indicator indicating active mode or standby mode for digital units, fronthaul equipment, and wireless units, cell mode setting indicator indicating single cell mode or same cell mode, IP address, and port Characterized in that at least one of the ID information includes,
Method for automatically optimizing cell operation. delete As a system for automatically optimizing cell operation according to traffic demand in a wireless access network,
Radio access network (RAN) configuration equipment including a digital unit (DU), fronthaul equipment, and radio unit (RU) that periodically transmits status messages for radio access network monitoring through a management plane (M-Plane); and
Comprising a network management system that determines whether or not the digital unit has a failure based on status messages for wireless access network monitoring transmitted from the wireless access network configuration equipment,
The network management system is,
When a failure of the digital unit is detected, the wireless unit that was linked with the digital unit is linked with another digital unit,
If a failure of the digital unit is not detected, the cell operation mode is determined considering the traffic demand,
When it is determined that a change in cell configuration is necessary according to interconnection with other digital units and the determined cell operation mode, transmitting a configuration message for changing wireless access network settings to the wireless access network configuration devices through the management plane,
The cell operation mode is,
If the traffic of the digital unit is more than the preset upper limit standard (H), single cell mode is determined in which one wireless unit uses the cell exclusively,
If the traffic of the digital unit is below the preset lower limit standard (L), the same cell mode is determined in which two or more wireless units use the same cell,
When the cell operation mode is determined to be the same cell mode, the digital unit that does not need interworking with the wireless unit is turned off or switched to standby mode,
Cell operation automatic optimization system. According to clause 6,
The status message for monitoring the wireless access network is,
PCI (Physical Cell ID), frequency usage indicator indicating the number of resource blocks used, status indicator indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit, fault ID, IP address , Port ID, and cell operation mode information, characterized in that it includes at least one of the following information,
Cell operation automatic optimization system. delete According to clause 6,
The configuration message for changing the wireless access network settings is:
PCI (Physical Cell ID), status setting indicator indicating active mode or standby mode for digital units, fronthaul equipment, and wireless units, cell mode setting indicator indicating single cell mode or same cell mode, IP address, and port Characterized in that at least one of the ID information is included,
Cell operation automatic optimization system. delete As a method of automatically optimizing cell operation according to traffic demand in a wireless access network,
A step in which radio access network (RAN) components, including a digital unit (DU), fronthaul equipment, and radio unit (RU), periodically transmit status messages for radio access network monitoring to the service management coordinator (SMO) through the O1 interface. ;
Non-real time RIC of the service management coordinator determining a policy for cell optimization based on information collected in the service management coordinator through an O1 interface;
The non-real-time controller transmitting a message for the determined cell optimization policy to a near-real time controller (Near-Real time RIC) through the A1 interface;
determining, by the near real-time controller, a cell optimization parameter according to a policy determined by the non-real-time controller; and
The proximity real-time controller includes transmitting a configuration message for cell configuration change to the wireless access network configuration devices through an E2 interface,
The non-real-time controller of the service management coordinator,
If the traffic of the digital unit is higher than a certain upper limit standard (H) set, the cell operation mode is determined to be a single cell mode in which the wireless unit uses the cell exclusively,
If the traffic of the digital unit is below a certain preset lower limit standard (L), the cell operation mode is determined as the same cell mode in which two or more wireless units use the same cell,
When the cell operation mode is determined to be the same cell mode, the digital unit that does not need interworking with the wireless unit is turned off or switched to standby mode,
Method for automatically optimizing cell operation. According to clause 11,
The status message for monitoring the wireless access network is,
PCI (Physical Cell ID), frequency usage indicator indicating the number of resource blocks used, status indicator indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit, fault ID, IP address , Port ID, and cell operation mode information, characterized in that it includes at least one of the following information,
Method for automatically optimizing cell operation. delete According to clause 11,
The message for the cell optimization policy is,
Digital unit traffic upper and lower limit standards for cell mode conversion of single cell mode or same cell mode, PCI (Physical Cell ID) for each wireless access network equipment and port, frequency usage indicator indicating the number of resource blocks used, digital unit and at least one of a status indicator indicating the active mode or standby mode of the fronthaul equipment and the wireless unit, a fault ID, an IP address, a port ID, and cell operation mode information. ,
Method for automatically optimizing cell operation. According to clause 11,
In the step of determining cell optimization parameters, the close real-time controller determines a cell optimization parameter according to the policy determined by the non-real-time controller,
The proximity real-time controller determines at least one cell optimization parameter among the wireless access network configuration equipment and port-specific PCI (Physical Cell ID) and cell operation mode according to the policy determined by the non-real-time controller.
Method for automatically optimizing cell operation. According to clause 11,
The configuration message for changing the cell configuration includes PCI (Physical Cell ID), a status setting indicator indicating active mode or standby mode for the digital unit, fronthaul equipment, and wireless unit, and a cell mode indicating single cell mode or same cell mode. Characterized in that it includes at least one of a setting indicator, IP address, and port ID information,
Method for automatically optimizing cell operation. delete As a system for automatically optimizing cell operation according to traffic demand in a wireless access network,
Radio access network (RAN) configuration equipment including a digital unit (DU), fronthaul equipment, and radio unit (RU) that periodically transmits status messages for radio access network monitoring to the service management coordinator (SMO) through the O1 interface;
A non-real-time controller of the service management coordinator that determines a policy for cell optimization based on the information collected in the service management coordinator through the O1 interface and transmits a message for the determined cell optimization policy through the A1 interface. time RIC); and
Receives a message for cell optimization policy transmitted from the non-real-time controller, determines cell optimization parameters according to the policy determined by the non-real-time controller, and sends a configuration message for cell configuration change to the wireless access network configuration equipment through the E2 interface. Includes a Near-Real time RIC that transmits
The non-real-time controller of the service management coordinator,
If the traffic of the digital unit is higher than a certain upper limit standard (H) set, the cell operation mode is determined to be a single cell mode in which the wireless unit uses the cell exclusively,
If the traffic of the digital unit is below a certain preset lower limit standard (L), the cell operation mode is determined as the same cell mode in which two or more wireless units use the same cell,
When the cell operation mode is determined to be the same cell mode, the digital unit that does not need interworking with the wireless unit is turned off or switched to standby mode,
Cell operation automatic optimization system. According to clause 18,
The status message for monitoring the wireless access network is,
PCI (Physical Cell ID), frequency usage indicator indicating the number of resource blocks used, status indicator indicating active mode or standby mode of digital unit, fronthaul equipment, and wireless unit, fault ID, IP address , Port ID, and cell operation mode information, characterized in that it includes at least one of the following information,
Cell operation automatic optimization system. delete According to clause 18,
The message for the cell optimization policy is,
Digital unit traffic upper and lower limit standards for cell mode conversion of single cell mode or same cell mode, PCI (Physical Cell ID) for each wireless access network equipment and port, frequency usage indicator indicating the number of resource blocks used, digital unit and at least one of a status indicator indicating the active mode or standby mode of the fronthaul equipment and the wireless unit, a fault ID, an IP address, a port ID, and cell operation mode information. ,
Cell operation automatic optimization system. According to clause 18,
The close real-time controller,
Characterized in determining at least one cell optimization parameter among the wireless access network configuration equipment and port-specific PCI (Physical Cell ID) and cell operation mode according to the policy determined by the non-real-time controller,
Cell operation automatic optimization system. According to clause 18,
The setup message for changing the cell configuration is:
PCI (Physical Cell ID), status setting indicator indicating active mode or standby mode for digital units, fronthaul equipment, and wireless units, cell mode setting indicator indicating single cell mode or same cell mode, IP address, and port Characterized in that at least one of the ID information is included,
Cell operation automatic optimization system.
delete