O-DU High Overview
O-DU High Architecture
O-DU implements the functional blocks of L2 layer of a 5G NR protocol stack in SA(StandAlone) mode. These layers primarily include NR MAC, NR Scheduler and NR RLC layers.
O-DU modules are developed as shown in the below diagram.
O-DU High Thread Architecture
As shown in Figure 1, there are multiple entities within O-DU High. Modules sharing a given color belong to one thread. O-DU architecture can be defined at a thread level as follows:
Thread 1: O-DU thread
Thread 2: DU APP inclusive of Config Handler, DU Manager, UE Manager, and ASN.1 Codecs
Thread 3: 5G NR RLC DL and MAC (inclusive of 5G NR SCH and Lower MAC)
Thread 4: 5G NR RLC UL
Thread 5: SCTP Handler
Thread 6: Lower MAC Handler
Thread 7: EGTP Handler
Thread 8: O1
O-DU High Modules
DU APP
This module configures and manages all the operations of O-DU. It interfaces with external entities as follows:
OAM: DU APP interacts with OAM on the O1 interface for configuration, alarms and performance management.
O-CU: DU APP interacts with O-CU for RAN functionalities over the F1 interface which is built on SCTP. Control messages are exchanged on the F1-C interface and data messages on the F1-U interface.
RIC: DU APP interacts with RIC on E2 interface over SCTP.
DU App submodules are as follows:
Config Handler manages the configurations received on O1 interfaces and stores them within DU APP context.
DU Manager handles all cell operations at the DU APP.
UE Manager handles UE contexts at the DU APP.
SCTP handler is responsible for establishing SCTP connections with O-CU, RIC on the F1AP and E2AP interfaces respectively.
EGTP handler is responsible for establishing EGTP connection with O-CU for data message exchange on the F1-U interface.
ASN.1 Codecs contain ASN.1 encode/decode functions which are used for System information, F1AP and E2AP messages.
5G NR RLC
This module provides services for transferring the control and data messages between MAC layer and O-CU (via DU App).
5G NR RLC UL and 5G NR RLC DL are the sub modules of this module that implement uplink and downlink functionality respectively.
5G NR MAC
This module uses the services of the NR physical layer to send and receive data on the various logical channels. Functions of the 5G NR MAC module are as follows:
5G NR MAC is responsible for multiplexing and de-multiplexing of the data on various logical channels.
Lower MAC interfaces between the MAC and the O-DU Low. It implements all the messages of FAPI specification. It has a receiver thread to handle messages from L1.
5G NR SCH
This module is completely encapuslated withing 5G NR MAC i.e. all interactions of the 5G NR SCH is via the 5G NR MAC.
Schedules resources in UL and DL for cell and UE based procedures.
SCH framework design supports plugging-in new scheduling algorithm easily. Refer to section “Scheduler Framework with plug-in support” in Developer-Guide document for details.
O-DU Utility and Common Functions
These modules contain platform specific files and support O-DU High functionality and message exchanges.
O1 Module
As shown in figure 2 the O1 module runs as a thread in O-DU High. Alarm communication happens over a Unix socket between the O1 and O-DU threads. O1 module uses API calls for interacting with the Netconf server(Netopeer) and datastore(sysrepo) for providing the Netconf interface.
O1 architecture has following components:
Netconf Session Handler: Subscribe to Netconf YANG modules and events. Register callback handler methods.
VES Agent : Sends the VES events to SMO
Alarm Manager: Stores and manages(add/updated/delete) alarms.
Alarm Interface : Provides an interface to O-DU High threads for sending the alarm messages to O1 module over Unix socket.
Config Interface : Interface to handle the configurations sent from SMO to the stack
Netopeer server: Serves the northbound SMO/OAM Netconf requests.
O-DU High Interfaces
This section describes the other modules that O-DU High interfaces with, as shown in below diagram.
As shown in Figure 3, O-DU High interfaces with the following modules:
O-CU: O-DU High communicates with O-CU on the F1AP interface. The control message exchanges are on F1-C while data message exchanges are on F1-U interfaces. The below F1AP messages on F1-C are implemented, as per 3GPP 38.473-f60 v15.3:
Interface Management
F1 Setup
gNB-DU Configuration Update
F1 Reset
PAGING
UE Context Management
UE Context Setup
UE Context Modification
UE Context Release
RRC Message Transfer
Initial UL RRC Message Transfer
DL RRC Message Transfer
UL RRC Message Transfer
RRC Delivery Report
Near RT RIC: O-DU High communicates with Near RT RIC on the E2 interface. The below E2AP messages are implemented, as per O-RAN.WG3.E2GAP-R003-v03.00 and O-RAN.WG3.E2AP-R003-v03.00.
Global Procedures
E2 Setup
E2 Node Configuration Update
RIC Service Update
E2 Connection Update
E2 Removal
E2 Reset
Error Indication
Near RT RIC Functional Procedures
RIC Subscription
RIC Subscription Modification
RIC Subscription Modification Required
RIC Subscription Delete
RIC Subscription Delete Required
RIC Indication
O-DU Low: O-DU High communicates with O-DU Low on the FAPI interface. The below FAPI messages are supported, as per FAPI interface files shared by Intel:
P5 messages - PHY mode control interface
PARAM.request/PARAM.response
CONFIG.request/CONFIG.response
START.request
STOP.request
STOP.indication
P7 messages - Main data path interface
DL_TTI.request
UL_TTI.request
SLOT.indication
UL_DCI.request
TX_Data.request
RX_Data.indication
CRC.indication
UCI.indication
RACH.indication
OAM: O-DU High communicates with OAM on the O1 interface.
O-DU High functionality
Cell Up and Broadcast Procedure
This section describes the cell-up procedure within O-DU High.
As seen in the Figure 4, - If O1 interface is enabled, SMO sends cell configuration to DU APP. DU APP stores the configurations in its local database.
If O1 interface is disabled, DU APP module uses static configuration.
The DU APP module of O-DU High sends F1 Setup Request to O-CU. This message contains a list of cells that the O-DU High has been configured with.
The O-CU responds with F1 Setup Response. This message contains a list of cells which must be activated.
The O-DU High scans the list of cells received and sends corresponding cell configurations to 5G NR MAC.
5G NR MAC, in-turn configures the 5G NR SCH. It also configures the O-DU Low via the Lower MAC module.
On receiving the cell config response, DU APP sends a gNB DU Config Update towards the O-CU. The O-CU responds with gNB DU Config Update ACK towards the O-DU High.
The DU APP now exchanges F1 Reset message with the O-CU to initialize the UE contexts.
DU APP sends Cell Start Req towards 5G NR MAC. This message is translated by the Lower MAC into the FAPI message START.request towards the O-DU Low.
On receiving START.request, O-DU Low begins to send slot indications towards 5G NR MAC via the lower MAC. The frequency of these slot indications is determined by the numerology(Mu) supported. 5G NR MAC forwards these slot indications to the 5G NR SCH and DU APP modules.
When the first slot indication reaches the DU APP, cell is marked as up. If O1 is enabled, DU APP triggers an alarm to SMO to indicate the CELL is UP.
The 5G NR SCH, keeps tracking the SSB and SIB1 ocassions on receiving regular slot indications. On detecting the relevant ocassion, 5G NR SCH schedules SSB/SIB1 and forwards the DL Scheduling Information to 5G NR MAC.
The 5G NR MAC mutiplexes the PDU and sends SSB/SIB1 packets towards the O-DU Low through the Lower MAC.
Closed Loop Automation Procedure
This section describes the closed loop automation procedure within O-DU High.
SMO commands ODU-High to bring the cell down via O1 interface.
DU-APP module of ODU-High sends GNB-DU configuration update message to O-CU. It contains the details of cell to be deleted. O-CU acknowledges this message by sending GNB-DU configuration update acknowledgment.
For each UE, DU APP sends UE Context Release Request to O-CU with information about the to be released. O-CU responds with UE Context Release request. It contains the RRC release message. O-DU high sends this RRC Release message to UE.
DU APP then sends UE delete request to MAC and RLC. Once a confirmation is received from both MAC and RLC, DU APP deletes UE from its own database as well.
Once all UEs are released, O-DU High sends STOP.Request to L1. L1 responds with stop indication.
Once cell has stopped, DU APP sends cell delete request to MAC. On receiving confimation from MAC, DU APP deletes cell information from its own database as well and sends UE Context Release Complete.
On receiving cell bring up command from SMO, the complete Cell bring up and UE attach procedure will be repeated (as explained in above sections)
O1 Netconf get-alarm list procedure
This section describes the Health Status Retrieval scenario of O-DU High health-check. It enables a northbound client(SMO) to retrieve the health of the O-DU High based on the last self-check performed. The alarm-list is provided as the response to the request via O1 Netconf interface.
As seen in the Figure 7,
On the cell state change from de-active to activate, DU APP module raises a cell up alarm message and sends it over the Unix socket using the Alarm Interface API.
On other side a Unix socket server, running as a thread, in O1 module receives the cell up alarm message and it passes on the alarm information to the Alarm Manager.
Alarm Manager stores the alarm data in a list.
Whenever SMO/OAM requires the current alarm list, it sends a Netconf get request. The request is received by the Netopeer Server and a callback method, registered with the Session Handler, is invoked.
The callback function fetches the alarm list from Alarm Manager and sends it back to the client (SMO/OAM) via Netconf interface.
Network Slicing procedure
This section describes the Network Slicing feature within O-DU High.
As seen in the Figure 8,
Once the Cell is UP, Slice Configuration received from O1 to O-DU is processed. DU APP forwards the Slice Configuration Request towards MAC which is further forwarded to Scheduler.
Scheduler stores the Slice Configuration in DB and sends the Slice Configuration Response for each Slice to MAC and further towards DU APP. Slice Configuration Procedure completes.
Once a UE attaches and PDU session is established then RLC will periodically calculate the Slice Performance Metrics(UL and DL Throughput) for slices configured during UE Context Setup/Modification procedure.
RLC sends the Consolidated Slice Metrics to DU APP at every 60 sec duration. This is further forwarded towards SMO/Non-RT RIC.
SMO/Non-RT RIC analyses these metrics and may optimize the slice configuration(RRM Policies) for dedicated slice. This is received at MAC and Scheduler as Slice Reconfiguration Request from DU APP.
Scheduler updates the received Slice Configuration in its DB and sends back the Slice Reconfiguration Response to MAC and further MAC forwards it to DU APP. Scheduler applies the optimized RRM policies for the dedicated slice.
Idle Mode Paging procedure
This section describes the Idle Mode Paging procedure within O-DU High.
As seen in the Figure 9,
When a Paging is received from O-CU and the Cell to be Paged is UP then DU APP will calculate Paging Frame(PF) and i_s(Index of Paging Ocassion/Slot) and groups the Paging of UEs falling on same PF/SFN together and stores in its Cell’s Databse.
When a Slot Indication for SFN is received then DU APP extracts the Paging of all UEs whose PF is ahead by PAGING_DELTA and builds Paging RRC PDU. DU APP sends the same via DL PCCH Indication to MAC.
MAC forwards to SCH as PAGING INDICATION.
SCH stores the Page Message in its DB and when the SLOT_INDICATION for that SFN arrives, SCH performs scheduling and resource allocation for PDCCH (alongwith DCI 1_0 format) and PDSCH channels and sends to MAC through DL PAGING ALLOCATION message.
MAC forwards the PAGE to PHY in TX_Data.Request.
Inter-DU Handover within O-CU
This section describes the handling of inter-DU handover of a UE within O-DU High.
Assumption: UE is RRC connected with DU and PDU data session is active.
The UE sends Measurement Report message to the source O-DU. This message is sent from O-DU to O-CU in the UL RRC MESSAGE TRANSFER message over F1AP interface.
Based on UE Measurement Report, O-CU makes a handover decision to another cell belonging to the target O-DU.
The O-CU sends a UE CONTEXT MODIFICATION REQUEST message to source O-DU to query the latest configuration.
The DU APP in source O-DU responds with a UE CONTEXT MODIFICATION RESPONSE message that includes latest full configuration information.
The O-CU sends a UE CONTEXT SETUP REQUEST message to the target O-DU to create an UE context and setup one or more data bearers. The UE CONTEXT SETUP REQUEST message includes Hand-overPreparationInformation. At target O-DU, DU APP sends UE Create Request to MAC and RLC layers to create the UE context with radio resources and receives UE Create Response from the respective protocol layers.
The target O-DU responds with a UE CONTEXT SETUP RESPONSE message if the target O-DU can admit resources for the handover.
The O-CU sends a UE CONTEXT MODIFICATION REQUEST message to the source O-DU, which includes RRCReconfiguration message towards the UE. The O-CU also indicates the source O-DU to stop the data transmission for the UE.
The source O-DU forwards the received RRCReconfiguration message to the UE and then sends the UE Reconfiguration Request to MAC/Scheduler and RLC layer and get the UE Reconfiguration Response from the respective protocol layers.
The source O-DU responds to the O-CU with UE CONTEXT MODIFICATION RESPONSE message.
UE triggers Random Access procedure at the target O-DU. This is a contention free random access if UE was informed about its dedicated RACH resources in RRC Reconfiguration message.
Once Random Access procedure with target O-DU is complete, the UE responds to the target O-DU with a RRCReconfigurationComplete message.
The target O-DU sends UL RRC MESSAGE TRANSFER message to O-CU to convey the received RRCReconfigurationComplete message.
The downlink and uplink data packets are sent to/from the UE through the target O-DU.
The O-CU sends UE CONTEXT RELEASE COMMAND message to the source O-DU.
The source O-DU sends UE DELETE REQUEST to MAC/RLC layers to release the UE context and receives UE DELETE RESPONSE message.
The source O-DU responds to O-CU with UE CONTEXT RELEASE COMPLETE message.
Inter-CU Handover (Xn-Based)
This section describes the handling of inter-CU handover of a UE over Xn interface.
Terminology:
Source GNB : GNB to which UE is connected and will be handed over from .
Source GNB DU : O-DU in source GNB
Source GNB CU : O-CU in source GNB
Target GNB : GNB to which UE will be handed over to.
Target GNB DU : O-DU in target GNB
Target GNB CU : O-CU in target GNB
Xn Inteface : Interface between Source GNB CU and Target GNB CU
UE : UE in handover from source GNB to target GNB
Assumptions:
Xn setup is established between the two GNB
UE is RRC connected with DU
PDU data session is active.
Call Flow :
UE sends Measurement Report message to source GNB. This message is sent from O-DU to O-CU in the UL RRC MESSAGE TRANSFER message over F1AP interface.
Based on UE Measurement Report, O-CU makes handover decision to a cell belonging to another GNB. Hereafter, this GNB will be referred to as target GNB.
Before initiating the handover procedure, source GNB CU sends a UE CONTEXT MODIFICATION REQUEST message to source GNB DU to query the latest configurations.
The source GNB DU responds with UE CONTEXT MODIFICATION RESPONSE message that includes latest full configuration information.
To start the handover, source GNB CU sends HANDOVER REQUEST to target GNB CU with UE configuration received from source GNB DU.
Target GNB CU sends a UE CONTEXT SETUP REQUEST message to target GNB DU to create a UE context and setup one or more data bearers. The UE CONTEXT SETUP REQUEST message includes Hand-overPreparationInformation. At DU, DU APP sends UE Create Request to MAC and RLC layers to create the UE context with radio resources and receives UE Create Response from the respective protocol layers.
The target GNB DU responds with UE CONTEXT SETUP RESPONSE message if it can admit resources for the handover.
Consequetively, target GNB CU sends HANDOVER REQUEST ACKNOWLEDGE message to source GNB CU to proceed with handover.
Now source GNB CU sends UE CONTEXT MODIFICATION REQUEST message to source GNB DU, which includes RRCReconfiguration message towards the UE. The CU also indicates the DU to stop the data transmission for the UE.
Source GNB DU forwards received RRCReconfiguration message to the UE and then sends DOWNLINK DATA DELIVERY STATUS message to CU to inform about successful delivery of message to UE.
Source GNB DU also sends UE Reconfiguration Request to MAC/Scheduler and RLC layers to stop data scheduling as requested by CU. Once all layers have responded with UE reconfiguration response, source GNB DU send UE CONTEXT MODIFICATION RESPONSE message to source GNB CU.
Using the information received in RRC Reconfiguration message, UE triggers Random Access procedure towards target GNB DU. This is a contention free random access if UE receives dedicated RACH resources information in RRC Reconfiguration message.
Once Random Access procedure with target GNB is complete, UE responds to target GNB DU with a RRCReconfigurationComplete message.
The target GNB DU sends UL RRC MESSAGE TRANSFER message to CU to convey the received RRCReconfigurationComplete message. This completes the UE attach to target GNB.
The downlink and uplink data packets are now sent to/from the UE through target GNB.
Once UE is successfully handed over to target GNB, its CU sends UE CONTEXT RELEASE message to source GNB CU.
Hence, source GNB CU sends UE CONTEXT RELEASE COMMAND message to the source GNB DU.
DU releases UE context at all layers and responds to source GNB CU with UE CONTEXT RELEASE COMPLETE message.
Discontinuous reception (DRX)
This section describes the Discontinuous reception (DRX) feature within O-DU High.
The connected mode DRX is used to improve UE’s battery power consumption. This allows UE to be active for a certain amount of time to monitor PDCCH. UE shall become active or inactive based on the DRX timers.
When UE is created at O-DU during RRC connection setup procedure, DU APP forwards the default DRX configuration to MAC, who then passes it to SCH as part of UE configuration request. SCH stores these configuration and will use it to calculate the start time and expiry time of various DRX timers. But these timers will only start after UE is RRC connected.
O-DU may receive modified DRX-configuration in UE CONTEXT SETUP REQUEST from O-CU. DU APP forwards it to MAC who forwards it to SCH as part of UE reconfiguration request. In this case, SCH will stop all DRX timers, re-calculate the start time and expiry time of various timers based on updated configuration and restart the drx-onDurationTimer.
Along with long cycle, DRX in O-DU high also supports short cycle which is enabled if short cycle configuration is recived in UE CONTEXT SETUP REQUEST.
DRX timers supported in ODU-High are drx-onDurationTimer, drx-InactivityTimer, drx-ShortCycleTimer, drx-HARQ-RTT-TimerDL, drx-RetransmissionTimerDL, drx-HARQ-RTT-TimerUL and drx-RetransmissionTimerUL.
UE is active when any of the following timers is running: drx-onDurationTimer, drx-InactivityTimer, drx-RetransmissionTimerDL or drx-RetransmissionTimerUL, else the UE is considered as inactive.
Initially, drx-onDurationTimer is started based on long cycle length. While drx-onDurationTimer or drx-InactivityTimer are running, UE becomes active to monitor PDCCH and send data in UL/DL. When drx-InactivityTimer expires, drx-ShortCycleTimer starts. While drx-ShortCycleTimer is running, drx-onDurationTimer is started based on short cycle length. Once drx-ShortCycleTimer expires, long cycle length is used again. Refer to figure 12 below for detailed working of these timers.
If HARQ is received/sent, drx-HARQ-RTT-TimerDL or drx-HARQ-RTT-TimerUL is started. On its expiry drx-RetransmissionTimerDL or drx-RetransmissionTimerUL will start. While it is running, UE becomes active for retransmission of data in DL/UL. Refer to figure 13 and 14 below for detailed working of these timers.
If O-DU receives DRX configuration release indicator IE as a part of UE CONTEXT MODIFICATION REQUEST from O-CU, DU APP will forward this indicator to MAC which forwards it to SCH as part of UE reconfiguration request. In this case SCH stops all DRX timers, deletes DRX configuration and marks UE as active by default.
E2AP Functionality
O-DU High communicates with Near RT RIC on the E2 interface using various Global Procedures and Near-RT RIC Functional Procedures. The implementation of these procedures are strictly compliant to O-RAN.WG3.E2GAP-R003-v03.00, O-RAN.WG3.E2AP-R003-v03.00.
ODU-High supports E2 Service Model-Key Performance Measurement, compliant to O-RAN.WG3.E2SM-KPM-R003-v03.00. Following KPIs are implemented in ODU-High as part of E2SM-KPM. These comply with 3GPP 28.552 v15.6.0 section 5.1.1.2 Radio resource utilization.
KPI |
Section |
Remark |
---|---|---|
DL Total PRB Usage(RRU.PrbTotDl) |
5.1.1.2.1 |
Calulates the total usage of PRBs on DL |
UL Total PRB Usage(RRU.PrbTotUl) |
5.1.1.2.2 |
Calulates the total usage of PRBs on UL |
E2 API Flow Triggered in ODU-High’s stub-based test framework
This section describes the E2AP messages triggered when executing O-DU High in stub-based test framework.
E2AP Procedures Supported in ODU-High
This section contains flow diagrams for E2AP procedures that may/may not be triggered in ODU-High, however the code supports its working as per O-RAN WG3 E2 specifications.
E2 Setup Procedure
This section describes the E2 Setup Procedure within O-DU High and Near-RT RIC.
E2 Node Configuration Update Procedure
This section describes the E2 Node Configuration Procedure within O-DU High and Near-RT RIC.
RIC Service Update procedure
This section describes the RIC Service Update Procedure within O-DU High and Near-RT RIC. Note - This API is not currently triggered by ODU-High.
E2 Connection Update Procedure
This section describes the E2 Connection Update Procedure within O-DU High and Near-RT RIC. Note - This API is not currently triggered by stub-based framework.
E2 Removal Procedure
This section describes the E2 removal Procedure from both DU-initiated and RIC-initiated within O-DU High and Near-RT RIC. Note - This API is not currently triggered by ODU-High or Stub-based test framework as of now.
Reset Procedure
This section describes the Reset Procedure from both DU-initiated and RIC-initiated within O-DU High and Near-RT RIC. Note - This API is not currently triggered by ODU-High or Stub-based test framework as of now.
Error Indication Procedure
This procedure can be triggered from either O-DU or Near-RT RIC. It informs that an error has been found in DU or Near-RT RIC. Note - This API is not currently triggered by ODU-High or Stub-based test framework as of now.
RIC Subscription Procedure / RIC Indication
This section describes the RIC Subscription Procedure within O-DU High and Near-RT RIC. In addition to this procedure, the RIC indication procedure has been described.
RIC Subscription Modification Required
Only framework is added as part of this procedure. The complete handling and flow will be added once use-case is determined.
RIC Subscription Modification Procedure
This section describes the RIC Subscription Modification Procedure within O-DU High and Near-RT RIC. Note - This API is not currently triggered by stub-based framework.
RIC Subscription Delete Procedure
This section describes the RIC Subscription Delete Procedure within O-DU High and Near-RT RIC. Note - This API is not currently triggered by stub-based framework.
OSC Testcases Supported
The O-DU High partially supports below use-cases:
Traffic Steering
Health Check
Containerization of DU, CU stub & RIC stub
This section describes the Containerization of DU, CU stub and RIC stub:
The DU, CU Stub, and RIC Stub are packaged into portable containers for consistent operation across various environments.
Docker is used to create these containers, ensuring that all necessary dependencies are included for proper functionality.
These containers are deployed and managed using Kubernetes, which handles scaling, load balancing, and resource allocation.
Helm automates the deployment and configuration of the containers, simplifying the management process.
Addition Functionality
Tool for FAPI message decoder
This tool decodes FAPI messages exchanged between the DU and L1.
Tool for Memory leak
The tool detects the memory leaks in the ODU code.