YD/T 4002-2021 5G digital cellular mobile telecommunication network-test method of eMBB user equipment (Phase 1) English
5G digital cellular mobile telecommunication network - Test method of eMBB user equipment (Phase 1)
1 Scope
This standard specifies the test methods for the basic functions, RF performance, radio resource performance, protocol conformance and other aspects of 5G enhanced mobile broadband (eMBB) user equipment (UE) with a band below 6GHz.
This standard is applicable to 5G UEs with a band below 6GHz that support enhanced mobile broadband (eMBB) scenarios, and is aimed at both Non-StandAlone (NSA) and StandAlone (SA).
2 Normative references
The following referenced documents are indispensable for the application of this document. For dated reference, only the edition cited applies. For undated references, the latest edition of the referenced documents (including any amendments) applies.
YD/T 1763.1-2011 TD-SCDMA/WCDMA digital cellular mobile telecommunication network test methods for UICC-ME (Cu) interface - Part 1: Physical, electrical and logical characteristics of ME
YD/T 3230-2017 Common technical requirements and test methods for digital mobile telecommunication terminal
3GPP TS 36.521-1 (16.6.0) Evolved Universal Terrestrial Radio Access (E-UTRA); User Equipment (UE) conformance specification; Radio transmission and reception; Part 1: Conformance testing
3GPP TS 38.101-1 (15.6.0) NR; User Equipment (UE) radio transmission and reception; Part 1: Range 1 Standalone
3GPP TS 38.101-1 (15.11.0) NR; User Equipment (UE) radio transmission and reception; Part 1: Range 1 Standalone
3GPP TS 38.101-3 (15.6.0) NR; User Equipment (UE) radio transmission and reception; Part 3: Range 1 and Range 2 Interworking operation with other radios
3GPP TS 38.133 NR; Requirements for support of radio resource management
3GPP TS 38.213 (15.6.0) NR; Physical layer procedures for control
3GPP TS 38.214 (15.6.0) NR; Physical layer procedures for data
3GPP TS 38.508-1 (16.0.0) 5GS; User Equipment (UE) conformance specification; Part 1: Common test environment
3GPP TS 38.508-1 (16.5.0) 5GS; User Equipment (UE) conformance specification; Part 1: Common test environment
3GPP TS 38.521-1 (16.0.0) NR: User Equipment (UE) conformance specification; Radio transmission and reception; Part 1: Range 1 Standalone
3GPP TS 38.521-1 (16.5.0) NR: User Equipment (UE) conformance specification; Radio transmission and reception; Part 1: Range 1 Standalone
3GPP TS 38.521-3 (16.0.0) NR; User Equipment (UE) conformance specification; Radio transmission and reception; Part 3: Range 1 and Range 2 Interworking operation with other radios
3GPP TS 38.523-3 (16.0.0) 5GS; User Equipment (UE) conformance specification; Part 3: Protocol test suites
3GPP TS 38.533 (16.0.0) NR; User Equipment (UE) conformance specification; Radio Resource Management (RRM)
3 Abbreviations
For the purposes of this document, the following symbols and abbreviated terms apply.
5G-GUTI 5G globally unique temporary identity
ACK Acknowledgment
AM Acknowledgment Mode
AMC Adaptive Modulation and Coding
ARQ Automatic Repeat-reQuest
BCCH Broadcast Control CHannel
BCH Broadcast CHannel
BPSK Binary Phase Shift Keying
CCCH Common Control CHannel
CP Cyclic Prefix
CQI Channel Quality Indicator
CRC Cyclic Redundancy Check
CSI Channel State Information
DCCH Dedicated Control Channel
DCI Downlink Control Information
DFT-S-OFDM Discrete Fourier Transform-Spread OFDM
DL Downlink
DL-SCH Downlink Shared Channel
DRX Discontinuous Reception
DTX Discontinuous Transmission
eNodeB (eNB) Evolved NodeB
EPC Evolved Packet Core network
HARQ Hybrid Automatic Repeat-reQuest
IPv4 Internet Protocol Version 4
IPv6 Internet Protocol Version 6
LTE Long Term Evolution
MAC Media Access Control
MCS Modulation and Coding Scheme
MCG Master Cell group
MIB Master Information Block
MIMO Multiple Input Multiple Output
NACK Negative Acknowledgment
PBCH Physical Broadcast Channel
PCCH Paging Control Channel
PCH Paging Channel
PDCCH Physical Downlink Control Channel
PDCP Packet Data Convergence Protocol
PDSCH Physical Downlink Shared Channel
PDU Packet Data Unit
PDN Public Data Network
PRACH Physical Random Access Channel
PRB Physical Resource Block
PUCCH Physical Uplink Control Channel
PUSCH Physical Uplink Shared Channel
RB Radio Bearer
RLC Radio Link Control
RRC Radio Resource Control
RS Reference Signal
RSRP RS Received Power
RSRQ RS Received Quality
SCG Secondary Cell group
SCH Synchronization Channel
SDU Service Data Unit
SIB System Information Block
SRS Sounding Reference Signal
SSS Secondary Synchronization Signal
SUCI Subscription Concealed Identifier
SUPI Subscription Permanent Identifier
TA Timing Advance
TAI Tracking area indicator
TDD TimeDivision Duplex
TM Transparent Mode
TPC Transmit Power Control
TT Test Tolerance
UCI Uplink Control Information
UDP User Datagram Protocol
UE User Equipment
UICC Universal integrated circuit card
UL Uplink
UL-SCH Uplink Shared Channel
UM Un-acknowledgment Mode
USIM Universal subscriber identity module
4 Test environment
4.1 Test environment for services and functions
The network test environment for basic service and function tests is shown in Figure 1, which is a real 5G network or an analog network with the same structure, consisting of a full set of 5G radio access network subsystems and core network subsystems.
Temperature: 15℃~35℃.
Relative humidity: 20%~75%.
Voltage: Nominal value given by the manufacturer.
Vibration: Negligible.
Figure 1 Reference test environment for service and function tests
4.2 RF test environment and radio resource management test environment
The reference test environment is shown in Figure 2.
Normal temperature: 15℃~35℃.
Limit temperature: -10℃ for low temperature and 55℃ for high temperature.
Relative humidity: 25%~75%.
Voltage: Nominal value given by the manufacturer.
Instrument description: Mainly including radio integrated tester (or system simulator), fading channel simulator (or generate faded signals from both baseband IQ ways and send them to integrated tester or simulator, and then send the faded signals from the output). The radio integrated tester mainly simulates base station equipment, communicates with the UE, and measures the related indexes. The fading simulator mainly simulates various multi-path fading modes on the channel.
Figure 2 RF test environment and radio resource management test environment
4.3 Protocol test environment
Temperature: 15℃~35℃.
Relative humidity: 25%~75%.
Voltage: Nominal value given by the manufacturer.
4.4 Network compatibility test environment
The test environment for the network compatibility may be either a commercial network test environment or a laboratory test environment, either of which can be chosen if not specified.
When testing in the commercial network environment, the operational security of the commercial network and the compatibility and interworking between the UE and the devices from different manufacturers shall be considered. At the same time, test in a commercial environment shall not affect the normal use of other users' services in the existing commercial network. Unless otherwise specified, network compatibility test shall be conducted in areas with good wireless signal coverage.
The test items for network parameter adjustment and special configuration shall be carried out in a laboratory test environment. The requirements for the laboratory test environment are the same as those given in 4.3.
5 Basic functions and services
5.1 General
According to the basic attributes and provision methods, services may be classified into basic services and supplementary services as follows:
——Voice service: It is a service form that carries users' voice elements and meets users' real-time voice communication needs.
——Mobile message service: It is a service form that carries users' small text packets and meets users' needs for information exchange of small data volume.
——Mobile bearer service and mobile data service on it: It is a service form that carries users' data elements and meets users' needs for real-time and non-real-time data information exchange. It also includes rich high-level applications derived from diversified high-level control and organization based on mobile data bearer service.
——Mobile supplementary service: It is a service form based on basic services such as voice, adding user's service data and service features, and completing special call control for users through special control on the network side.
Basic functions include ON/OFF, lock screen protection, dual-tone multi-frequency (DTMF), operator network selection, and information display.
5.2 Basic services
5.2.1 Data service offload in NSA Mode
5.2.1.1 Test purpose for NSA uplink service offload
The NSA UEs supporting NSA uplink service offload shall have the capability of transmitting uplink data services through the MCG and SCG at the same time, and the supported transmission capability is normal and effective, and the data services of both MCG and SCG are normal.
5.2.1.2 Test method for NSA uplink service offload
The test method for NSA uplink service offload is as follows.
a) Test steps:
1) The UE is powered on and connected to the NSA network to establish a dual connection;
2) The UE carries out uplink UDP data service through the packet filling server;
3) The network side can receive fully scheduled uplink continuous data at the MAC layers of the MCG and SCG respectively, and only the PDCP layer of the SCG side has uplink continuous data, and the volume of SCGPDCP data is slightly less than the sum of that of MCGMAC data and SCGMAC data.
b) Intended results: The UE shall be able to support the uplink data service offload in the NSA mode, and shall have the capability to correctly transmit the uplink data services through the MCG and the SCG in parallel simultaneously.
5.2.1.3 Test purpose for NSA downlink service offload
The NSA UEs supporting NSA downlink service offload shall have the capability of transmitting downlink data services through the MCG and SCG at the same time, the supported transmission capability is normal and effective, and the data services of both MCG and SCG are normal.
5.2.1.4 Test method for NSA downlink service offload
The test method for NSA downlink service offload is as follows.
a) Test steps:
1) The UE is powered on and connected to the NSA network to establish a dual connection;
2) The UE carries out downlink UDP data service through the packet filling server;
3) The UE can receive fully scheduled downlink continuous data at the MAC layers of the MCG and SCG respectively, only the PDCP layer of the SCG side has downlink continuous data, and the volume of SCGPDCP data is slightly less than the sum of that of MCGMAC data and SCGMAC data.
b) Intended results: The UE shall be able to support the downlink data service offload in the NSA mode, and shall have the capability to correctly receive and demodulate downlink data services through the MCG and SCG in parallel simultaneously and merge them for processing.
5.2.2 5G identity display
5.2.2.1 Test purpose for 5G identity in SA/NSA mode
For the UEs supporting NSA, the 5G identity shall be displayed correctly in various scenarios.
5.2.2.2 Test method for 5G identity when the UE in NSA mode is in idle state
When an UE in NSA mode is in the idle state, if the UE displays 5G in the idle state, the test method for 5G identity is as follows.
a) Test steps:
1) The upperLayerIndication is configured in sib2 of the eNodeB to indicate that the eNodeB supports the addition of NSA NR link, the UE is in the idle state when being powered on and connected to the LTE network, at which time 5G is displayed;
2) The upperLayerIndication is configured in sib2 of the eNodeB to indicate that the eNodeB does not support the addition of NSA NR link, the UE is in the idle state when being powered on and connected to the LTE network, at which time 5G is not displayed;
b) Intended results: The UE in NSA mode in the idle state shall be able to correctly parse the configuration information of upperLayerIndication in sib2 of the eNodeB, and shall also be able to display 5G identity according to parsed content.
5.2.2.3 Test method for 5G identity when the UE in NSA mode is in connected state
The test method for 5G identity when the UE in NSA mode is in connected state is as follows:
a) Test steps:
1) The upperLayerIndication is configured in sib2 of the eNodeB to indicate that the eNodeB supports the addition of NSA NR link, the UE is in the connected state when being powered on and establishing dual connection of MCG and SCG in NSA mode, at which time 5G is displayed;
2) The upperLayerIndication is configured in sib2 of the eNodeB to indicate that the eNodeB supports the addition of NSA NR link, the UE is powered on and tries to establish dual connection of MCG and SCG in NSA mode, the SCGSSB signal strength is reduced so that the UE is unable to measure the SCG signal, the bearing is then reconfigured and dual connection released and the UE returns to the LTE in the LTE connected state, at which time 5G is not displayed.
b) Intended results: The UE shall be able to distinguish according to the actual establishment of dual connection in NSA mode and display 5G identity according to the actual situation.
5.2.3 Mobile data service
5.2.3.1 Test purpose for mobile data service
The UEs supporting mobile data services shall be able to provide data upload and download operations, and the cell phone type UEs supporting mobile data services shall be able to support the disabling and enabling of data services.
5.2.3.2 Test method for mobile data service
The test method for mobile data service is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) For UEs with data switch function, the data connection switch is turned on;
3) The UE is operated to establish a data connection. For UEs that do not support the human-machine interface, the data connection can be established by means of AT command;
4) Perform data upload and download;
5) For UEs with data switch function, the data connection switch is closed;
6) Try to upload and download data.
b) Intended results:
1) For step 4), the UE shall be able to upload and download data normally;
2) For step 6),the UE cannot upload and download data.
5.3 Basic functions
5.3.1 On/off function
5.3.1.1 Test purpose
The cell phone type UEs shall be equipped with a power switch and be able to normally carry out on and off operations. Other types of UEs may also have the on/off function.
5.3.1.2 Test method
The test method for on/off function is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) The power supply of the UE under test is turned off.
b) Intended results: The UE shall be able to turn on and off normally.
5.3.2 Operator network selection function
5.3.2.1 Test purpose
For the UEs, the selection and registration of operator network shall be completed by automatic network selection or manual network selection.
5.3.2.2 Test method
The test method for operator network selection function is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) If the UE supports the manual network selection mode, the manual network selection is carried out, and a network is selected from the searched network list through the menu.
b) Intended results:
1) For step 1), the user is successfully registered to the operator network;
2) For step 2), the UE shall display the identities of all operators covering its location.
5.3.3 Dual-tone multi-frequency function
5.3.3.1 Test purpose
The UEs supporting voice services and having keyboard function shall support the dual-tone multi-frequency (DTMF) function.
5.3.3.2 Test method
The test method for the DTMF function is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) Use the UE under test to call a switchboard adopting two-stage dialing, and then enter the extension number according to the voice prompt after getting through.
b) Intended results: The voice service between the UE under test and the extension is normally connected.
5.3.4 Information display function
5.3.4.1 Display of calling/called information
5.3.4.1.1 Test purpose
The UEs supporting voice services and having screen display shall correctly display the identification information corresponding to the calling/called number.
5.3.4.1.2 Test method
The test method for the display of calling/called information is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) Store any valid telephone number in the phonebook of the UE under test, and enter the identification information corresponding to the number;
3) Enter the telephone number stored in step 2) and initiate a call.
4) Hang up the UE;
5) Enter a telephone number other than the one stored in step 2) and initiate a call;
6) Hang up the UE;
7) Initiate a call to the UE under test by a mobile UE with the telephone number stored in step 2);
8) Hang up the UE;
9) Initiate a call to the UE under test by a mobile UE with a telephone number other than the one stored in step 2);
10) Hang up the UE;
11) Send a piece of SMS to the UE under test using a non-local number.
b) Intended results:
1) For step 2), the telephone number and its corresponding identification information shall be stored correctly and effectively;
2) For steps 3) and 5), the UE under test shall correctly display the called number or corresponding identification information as well as the call time and call duration;
3) For steps 7) and 9), the UE under test shall correctly display the calling number or corresponding identification information as well as the call time and call duration;
4) For step 11), the UE under test shall display the received short message by icon or other means.
5.3.4.2 Data connection display
5.3.4.2.1 Test purpose
The UEs support mobile data services and screen display shall be able to give the corresponding data connection display, such as symbols or graphics, according to the data connection state. Users can know the current state of connection according to the corresponding data connection display.
5.3.4.2.2 Test method
The test method for data connection prompt is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) Establish a data connection using the UE;
3) Check the information displayed on the human-machine interface of the UE while the data connection is in progress.
b) Intended results: The UE shall be able to display the corresponding data connection according to the connection state, such as a symbolic or graphical display.
5.3.4.3 Chinese display and input function
5.3.4.3.1 Test purpose
The UEs with screen display shall support simplified Chinese display, and the preset menu information shall support simplified Chinese. The UEs supporting both screen display and keyboard shall correctly provide input methods for simplified Chinese, letters, numbers and punctuations and be able to accept input correctly.
5.3.4.3.2 Test method
The test method for Chinese display and input function is as follows:
a) Test steps:
1) The UE is powered on and activates the subscriber identity module to enter the standby state;
2) Set the UE under test to the Chinese display/edit mode through the function menu;
3) Select simplified Chinese, letters, numbers and punctuations respectively, and input accordingly.
b) Intended results: The UE shall support simplified Chinese display and the preset menu information shall support simplified Chinese; the UE shall correctly provide input methods for simplified Chinese, letters, numbers and punctuations and be able to accept input correctly.
5.3.4.4 Display of signal strength, network information and operator
5.3.4.4.1 Test purpose
The mobile UEs with screen display shall display the information of received signal strength and the identification information of the operator and its network, and the operator information shall meet the requirements of the Regulation of the People's Republic of China on Telecommunications.
5.3.4.4.2 Test method
The test method for the display of signal strength, network information and operator is as follows:
a) Test steps:
1) The UE is powered on and activates the subscriber identity module to enter the standby state;
2) Check whether there is signal strength indication on the standby interface;
3) Check the identification information of the operator and its network in the standby state of the mobile UE.
b) Intended results:
1) For step 2), the UE displays the received signal strength;
2) For step 3), the UE shall be able to correctly display the identification information of the operator and its network.
5.3.4.5 Display of battery and charging information
5.3.4.5.1 Test purpose
The UEs with rechargeable battery and screen display shall support the battery capacity and charging information display function, and shall give an alarm prompt when the battery capacity is insufficient. The battery capacity indication shall change with the trend of battery power. The battery shall be able to be charged in both on and off states of the UE, and the UE shall have the indication that the battery is being charged during the charging process.
5.3.4.5.2 Test method
The test method for the display of battery and charging information is as follows:
a) Test steps:
1) The UE is powered on and the subscriber identity module is activated;
2) Check the information on the human-machine interface;
3) Assemble the UE with a battery with insufficient power, check the screen and pay attention to whether the UE gives alarm prompt in the standby and call states;
4) Charge the battery with the special charger or power adapter in both off and standby states of the UE to check the information displayed on screen.
b) Intended results:
1) For step 2), the UE's screen displays the capacity of the battery it uses;
2) For step 3), the UE gives an alarm prompt in both the standby and call states;
3) For step 4), the UE's screen displays the prompt information that the battery is being charged.
5.3.5 Test for SRS Switching function
5.3.5.1 Test for SRS Switching function in NSA mode
5.3.5.1.1 Test purpose
Ensure that the SRS Switching function shall be available in NSA mode, but not applicable to band n28.
5.3.5.1.2 Test method
a) Test steps:
1) The UE is connected to the test instrument by means of direct RF connection, as shown in Figure 2;
2) The UE is powered on, and it completes the ENDC dual connection after the LTE is attached, and then resides in both LTE and NR cells.
b) Intended results:
1) Check the supportedSRS-TxPortSwitchIE of the MRDC capability reporting message of the UE on the instrument side, which will report 1T2R or 1T4R capability;
2) Check the NR cell configuration message sent by the network side, and there will be 2R or 4R capability resource configuration information reported by the corresponding UE under the SRS-ResourceSetIE, and the usage value under the resourceType is 3 (antenna switching), indicating antenna rounding;
Foreword III
1 Scope
2 Normative references
3 Abbreviations
4 Test environment
4.1 Test environment for services and functions
4.2 RF test environment and radio resource management test environment
4.3 Protocol test environment
4.4 Network compatibility test environment
5 Basic functions and services
5.1 General
5.2 Basic services
5.3 Basic functions
5.4 Test for IPv4 and IPv
6 RF performance test
6.1 Characteristics of SA transmitter
6.2 Characteristics of SA Rx
6.4 EN-DC receiver characteristics
6.5 UL-MIMO transmitter characteristics
6.6 UL-MIMO receiver characteristics
7 Radio resource management conformance test
7.1 EN-DC
7.2 SA
8 Protocol conformance test
8.1 Idle mode operations
8.2 Layer
8.3 RRC layer
8.4 Mobility management
8.5 Session management
9 Network compatibility test
9.1 SA mode
9.2 NSA mode
10 Conformance test of machine-card interface
10.1 The UE uses an empty scheme to calculate SUCI
10.2 The UE uses profile B to calculate SUCI
10.3 SUCI identifies the UE - USIM uses profile B to calculate SUCI during initial registration
10.4 The UE uses SUCI to respond to "identity request" information
10.5 The UE uses SUCI to respond to the "IDENTITY REQUEST" message, and T3519 timer expires
10.6 The UE uses SUCI to respond to the "IDENTITY REQUEST" message, and the authentication is rejected
10.7 The UE uses an empty scheme for SUCI calculation - the parameters supported by the subscription identifier privacy in the SIM are missing
10.8 The UE uses 5G-GUTI for authentication - the last registered TAI exists on the USIM
10.9 The UE uses 5G-GUTI for authentication - the last registered TAI exists on the UE
10.10 UE identity authentication, with SUPI changes
10.11 The UE uses profile A to calculate SUCI
10.12 Electrical properties
10.13 Logical characteristics
5G数字蜂窝移动通信网增强移动宽带 终端设备测试方法(第一阶段)
1范围
本标准规定了6GHz以下频段5G增强移动宽带终端设备的基本功能、射频性能、无线资源性能、协 议一致性等方面的测试方法。
本标准适用于支持增强移动宽带场景(eMBB)的6GHz以下频段的5G终端,面向非独立组网
(Non-StandAlone)和独立组网(StandAlone)。
2规范性引用文件
下列文件对于本文件的应用是必不可少的。凡是注日期的引用文件,仅注日期的版本适用于本文件。 凡是不注日期的引用文件,其最新版本(包括所有的修改单)适用于本文件。
YD/T 1763.1-2011 TD-SCDMA/WCDMA数字蜂窝移动通信网通用集成电路卡(UICC)与终端间Cu 接口测试方法第1部分:物理、电气和逻辑特性
YD/T 3230-2017数字移动通信终端通用技术要求和测试方法
3GPP TS 36.521-1 (16.6.0)演进型通用陆地无线接入终端一致性:发射和接收(Evolved Universal Terrestrial Radio Access (E-UTRA) ; User Equipment (UE) conformance specification; Radio transmission and reception; Part 1: Confbnnance testing)
3GPP TS 38.101-1 (15.6.0)终端无线发射和接收;部分1 :范围1独立组网(NR; User Equipment(UE) radio transmission and reception; Part 1: Range 1 Standalone)
3GPP TS 38.101-1 (15.11.0)终端无线发射和接收;部分1:范围1独立组网(NR; User Equipment (UE) radio transmission and reception; Part 1: Range 1 Standalone)
3GPP TS 38.101-3(15.6.0)终端无线发射和接收;部分3:范围1和范围2与其他无线电的互操作(NR; User Equipment CUE) radio transmission and reception; Part 3: Range 1 and Range 2 Interworking operation with other radios)
3GPP TS 38.133 NR无线资源管理(NR; Requirements for support of radio resource management)
3GPP TS 38.213 (15.6.0) NR物理层过程控制(NR; Physical layer procedures for control
3GPP TS 38.214 (15.6.0) NR数据的物理层过程(NR; Physical layer procedures for data)
3GPP TS 38.508-1 (16.0.0)5GS终端一致性;部分 1 :测试环境(5GS; User Equipment(UE)confonnance specification; Part 1: Common test environment)
3GPP TS 38.508-1( 16.5.0)5GS终端一致性;部分 1:测试环境(5GS; User Equipment(UE)conformance
specification; Part 1: Common test environment)
3GPP TS 38.521-1 (16.0.0)终端一致性;无线发射接收;范围1独立组网(NR:User Equipment (UE) conformance specification; Radio transmission and reception Part 1: Range 1 Standalone)
3GPP TS 38.521-1 (16.5.0)终端一致性;无线发射接收;范围1独立组网(NR:User Equipment (UE) conformance specification; Radio transmission and reception Part 1: Range 1 Standalone)
3GPP TS 38.521-3 (16.0.0)终端一致性;无线发射接收;部分3:范围1和范围2与其他无线电的互 操作(NR;User Equipment (UE) conformance specification;Radio transmission and reception;Part 3: Range 1 and Range 2 Interworking operation with other radios)
3GPP TS 38.523-3 (16.0.0) 5GS终端一致性;部分3:协议测试套(5GS; User Equipment (UE) confonnance specification; Part 3: Protocol Test Suites)
3GPP TS 38.533 (16.0.0) NR终端无线发射和接收;无线资源管理(NR; User Equipment (UE) confonnance specification; Radio Resource Management (RRM)")
3缩略语
下列符号和缩略语适用于本文件。
5G-GUTI 5G全球唯一临时标识 5G globally unique temporary identity
ACK 肯定确认 Acknowledgement
AM 确认模式 Acknowledgement Mode
AMC 自适应调制和编码 Adaptive Modulation and Coding
ARQ 自动重传请求 Automatic Repeat-reQuest
BCCH 广播控制信道 Broadcast Control CHannel
BCH 广播信道 Broadcast CHannel
BPSK 二相相移键控 Binary Phase Shift Keying
CCCH 公共控制信道 Common Control CHannel
CP 循环前缀 Cyclic Prefix
CQI 信道质量指示 Channel Quality Indicator
CRC 循环冗余校验 Cyclic Redundancy Check
CSI 信道状态信息 Channel State Information
DCCH 专用控制信道 Dedicated Control Channel
DCI 下行控制信息 Downlink Control Information
DFT-S-OFDM DFT 扩展 OFDM Discrete Fourier Transform-Spread OFDM
DL 下行 Downlink
DL-SCH 下行共享信道 Downlink Shared Channel
DRX 不连续接收 Discontinuous Reception
DTX 不连续发送 Discontinuous Transmission
eNodeB (eNB) LTE基站 Evolved NodeB
EPC 演进型分组核心网 Evolved Packet Core network
HARQ 混合自动重传请求 Hybrid Automatic Repeat-reQuest
IPv4 互联网协议第4版 Internet Protocol Version 4
IPv6 互联网协议第6版 Internet Protocol Version 6
LTE 长期演进 Long Term Evolution
MAC 媒体接入控制 Media Access Control
MCS 调制编码方式 Modulation and Coding Scheme
MCG 主小区组 Master Cell group
MIB 主信息块 Master Infbnnation Block
MIMO 多入多出 Multiple Input Multiple Output
NACK 否定确认 Negative Acknowledgement
PBCH 物理广播信道 Physical Broadcast Channel
PCCH 寻呼控制信道 Paging Control Channel
PCH 寻呼信道 Paging Channel
PDCCH 物理下行控制信道 Physical Downlink Control Channel
PDCP 分组数据汇聚协议 Packet Data Convergence Protocol
PDSCH 物理下行共享信道 Physical Downlink Shared Channel
PDU 分组数据单元 Packet Data Unit
PDN 公用数据网 Public Data Network
PRACH 物理随机接入信道 Physical Random Access Channel
PRB 物理资源块 Physical Resource Block
PUCCH 物理上行控制信道 Physical Uplink Control Channel
PUSCH 物理上行共享信道 Physical Uplink Shared Channel
RB 无线承载 Radio Bearer
RLC 无线链路控制 Radio Link Control
RRC 无线资源控制 Radio Resource Control
RS 参考信号 Reference Signal
RSRP RS接收功率 RS Received Power
RSRQ RS接收质量 RS Received Quality
SCG 辅小区组 Secondary Cell group
SCH 同步信道 Synchronization Channel
SDU 业务数据单元 Service Data Unit
SIB 系统信息块 System Information Block
SRS 信道探测参考信号 Sounding Reference Signal
SSS 辅同步信号 Secondary Synchronization Signal
SUCI 用户隐藏标识符 Subscription Concealed Identifier
SUPI 用户永久标识符 Subscription Permanent Identifier
TA 时间提前量 Timing Advance
TAI 跟踪区标识 Tracking area indicator
TDD 时分双工 TimeDivision Duplex
TM 透明模式 Transparent Mode
TPC 发送功率控制 Transmit Power Control
TT 测试容限 Test Tolerance
UCI 上行控制信息 Uplink Control Information
UDP 用户数据报协议 User Datagram Protocol
UE 用户设备 User Equipment
UICC 通用集成电路卡 Universal integrated circuit card
UL 上行 Uplink
UL-SCH 上行共享信道 Uplink Shared Channel
UM 非确认模式 Un-acknowledgement Mode
USIM 通用用户身份识别模块 Universal subscriber identity module
4测试环境
4.1业务和功能测试环境
基本业务功能测试的网络测试环境如图1所示,它是一个真实的5G网络或具有相同结构的模拟网,
包含一个全套的5G无线接入网络子系统和核心网子系统。 温度:15。。〜35。(3。
相对湿度:20%〜75%。
电压:厂商给出的标称值。
振动:可忽略。
5GC
(a) SA Option2
图1业务和功能测试参考测试环境
4.2射频测试环境和无线资源管理测试环境
参考测试环境如图2所示。
正常温度:15°C-35°Co
极限温度:低温是-10°C,高温是55°Co
相对湿度:25%〜75%。
电压:厂商给出的标称值。
仪表说明:主要测试仪表为无线综合测试仪(或系统模拟器)、衰道模拟器(或从基带IQ两路产生 衰落信号送至综合测试仪或模拟器,再从输出端发送已经加衰落的信号)。上线综合测试主要模拟基站 设备,与UE进行通信并测量相关指标。衰落模拟器主要模拟信道上各种多径衰落模式。
无线综合
测试仪或
系统模拟
器
图2射频测试环境和无线资源管理测试环境
4.3协议测试环境
温度:15。(2 〜35。(3。
相对湿度:25%〜75%。
电压:厂商给出的标称值。
4.4网络兼容性测试环境
网络兼容性部分的测试环境可为商用网络测试环境或者实验室测试环境,如无特殊说明,两者 任选一种即可。
在商用网络环境中进行测试时,应考虑商用网络的运营安全以及终端与不同设备厂商设备的兼 容互通等情况。同时,商用环境中的测试不应当影响到现有商业网络中其他用户业务的正常使用。 如无特殊说明,网络兼容性测试应善在无线信号覆盖情况好的地区进行。
对于要进行网络参数调整和特殊配置的测试项,应在实验室测试环境进行。实验室的测试环境 同4. 3的要求。
5基本功能和业务
5.1概述
按照业务基本属性和提供方式,可以分为基本业务和补充业务,具体如下:
一 话音业务:是以承载用户话音要素,满足用户实时语音交流需求的业务形式。
一移动消息业务:是以承载用户文字类小数据包,满足用户小数据量信息交换需求的业务形式。
一 移动承载业务以及其上的移动数据业务:是以承载用户数据要素,满足用户进行实时、非实时 数据信息交换需求的业务形式。同时也包括基于移动数据承载业务,通过多样化的高层控制与
组织衍生出的丰富的高层应用。
一移动补充业务:是基于话音等基本业务,增加用户业务数据和业务特征,通过网络侧的特殊控 制完成用户特殊的呼叫控制类的业务形式。
基本功能包括如开关机、锁屏保护、双音多频、运营商网络选择、信息显示等。
5.2基本业务
5.2.1 NSA模式的数据业务分流
5.2.1.1 NSA上行业务分流测试目的
对于支持NSA上行业务分流的NSA终端应具备上行数据业务同时通过MCG和SCG进行传输的能力, 所支持的传输能力正常有效,MCG和SCG的数据业务均正常。
5.2.1.2 NSA上行业务分流测试方法
NSA上行业务分流测试方法如下=
a) 测试步骤:
1)终端开机并接入NSA网络建立双连接;
2 )终端通过灌包服务器进行上行UDP数据业务;
3)网络侧可以分别在MCG和SCG各自的MAC层收到满调度的上行连续数据,且仅SCG 侧的PDCP层有上行连续数据,SCGPDCP数据量略小于MCGMAC数据量SCGMAC数 据量。
b) 预期结果:终端应能在NSA模式支持上行数据业务分流,上行数据业务同时通过MCG和SCG 并行正确传输的能力。
5.2.1.3 NSA下行业务分流测试目的
对于支持NSA下行业务分流的NSA终端应具备下行数据业务同时通过MCG和SCG进行传输的能力, 所支持的传输能力正常有效,MCG和SCG的数据业务均正常。
5.2.1.4 NSA下行业务分流测试方法
NSA下行业务分流测试方法如下。
a) 测试步骤:
1)终端开机并接入NSA网络建立双连接;
2 )通过灌包服务器向终端进行下行UDP数据业务;
3)终端可以分别通过MCG和SCG各自的MAC层收到满调度的下行连续数据,且仅SCG 侧的PDCP层有下行连续数据,SCGPDCP数据量略小于MCGMAC数据量+SCGMAC数 据量。
b) 预期结果:终端应能在NSA模式支持下行数据业务分流,下行数据业务同时通过MCG和SCG 并行正确接收解调并合并处理的能力。
5.2.2 5G标识显示
5.2.2.1 SA/NSA模式5G标识测试目的
对于支持NSA的终端在各种场景下的5G标识正确显示。
5.2.2.2 NSA模式终端处于空闲态5G标识测试方法
NSA模式终端处于空闲态,如果终端在空闲态显示5G,贝U5G标识测试方法如下。
a)测试步骤:
1) 将LTE基站sib2中配置upperLayerlndication表示LTE基站支持NSA NR链路的添加,终 端开机并接入LTE网络处于idle态,此时显示5G;
2) 将LTE基站sib2中配置upperLayerlndication表示LTE基站不支持NSA NR链路的添加, 终端开机并接入LTE网络处于idle态,此时不显示5G;
b)预期结果:终端应能在NSA模式空闲态时正确解析LTE基站sib2中upperLayerlndication 配置信息,并可以根据解析内容显示5G标识的能力。
5.2.2.3 NSA模式终端处于连接态5G标识测试方法
NSA模式终端处于连接态5G标识测试方法如下:
a)测试步骤:
1) 将LTE基站sib2中配置upperLayerlndication表示LTE基站支持NSA NR链路的添加,终 端开机并在NSA模式下建立MCG和SCG的双连接,处于连接态,此时显示5G;
2) 将LTE基站sib2中配置upperLayerlndication表示LTE基站支持NSA NR链路的添加,终 端开机并在NSA模式下尝试建立MCG和SCG的双连接,降低SCGSSB信号强度,使终 端无法测量到SCG信号,承载重配,释放双连接,终端回到LTE,终端处于LTE连接态, 此时不显示5Go
b)预期结果:终端应能在NSA模式根据实际双连接建立情况进行区分并根据实际情况显示 5G标识。
5.2.3移动数据业务
5.2.3.1移动数据业务测试目的
对于支持移动数据业务的终端应能提供数据上传和数据下载操作,对于支持移动数据业务的手机类 型的终端应能支持数据业务的打开与关闭。
5.2.3.2移动数据业务测试方法
移动数据业务测试方法如下:
a)测试步骤:
1) 终端开机并激活用户识别卡;
2) 对于具备数据开关功能的终端,打开数据连接开关;
3) 操作终端建立一个数据连接,对于不支持人机界面的终端,可通过AT命令的方式建立数 据连接;
4) 进行数据的上传和下载;
5) 对于具备数据开关功能的终端,关闭数据连接开关;
6) 尝试进行数据的上传和下载。
b)预期结果:
1) 步骤4),终端应能正常实现数据的上传和下载;
2) 步骤6),终端无法进行数据的上传和下载。
5.3基本功能
5.3.1开、关机功能
5.3.1.1测试目的
对于手机类型的终端应具备电源开关,并且能够正常进行开、关机操作。对于其他类型的终端,也 可具备开、关机功能。
5.3.1.2测试方法
开、关机功能测试方法如下:
a) 测试步骤:
1) 终端开机并激活用户识别卡;
2) 关闭被测终端电源。
b) 预期结果:终端应能正常开、关机。
5.3.2运营商网络选择功能
5.3.2.1测试目的
对于终端,应通过自动选网或手动选网的方式完成对运营商网络的选择和注册。
5.3.2.2测试方法
运营商网络选择功能测试方法如下:
a) 测试步骤:
1) 终端开机并激活用户识别卡;
2) 如终端支持手动选网方式,则进行手动网络选择,尝试通过菜单在搜索的网络列表中选择 一个网络。
b) 预期结果:
1) 步骤1),用户成功注册到运营商网络;
2) 步骤2),终端应显示覆盖其所处位置所有的运营者标识,终端应尝试在用户选择的网络 中进行注册。
5.3.3双音多频功能
5.3.3.1测试目的
对于支持话音业务且具有键盘功能的终端,应支持双音多频(DTMF)功能。
5.3.3.2测试方法
双音多频功能测试方法如下:
a) 测试步骤:
1) 终端开机并激活用户识别卡;
2) 使用被测终端拨叫一个采用二次拨号的总机,拨通后根据语音提示键入分机号码。
b) 预期结果:被测终端与分机之间的话音业务正常接通。
5.3.4信息显示功能
5.3.4.1主/被叫信息显示
5.3.4.1.1测试目的
对于支持话音业务且具有屏幕显示的终端应正确显示主叫号码和被叫号码对应的标识信息。
5.3.4.1.2测试方法
主/被叫信息显示测试方法如下:
a) 测试步骤:
1) 终端开机并激活用户识别卡;
2) 在被测终端的电话簿中存储任意有效电话号码,并输入该号码对应的标识信息;
3) 输入步骤2)中已存储的电话号码,并发起呼叫;
4) 终端挂机;
5) 输入非步骤2)中已存储的电话号码,并发起呼叫;
6) 终端挂机;
7) 使用步骤2)中已存储电话号码的移动终端向被测终端发起呼叫;
8) 终端挂机;
9) 使用非步骤2)中已存储电话号码的移动终端向被测终端发起呼叫;
10) 终端挂机;
11) 使用非本机号码向被测终端发送短消息。
b) 预期结果:
1) 步骤2),电话号码及其对应标识信息的存储正确有效;
2) 步骤3)和步骤5),被测终端均应正确显示被叫号码或对应的标识信息,且应显示呼叫 时间及通话时长;
3) 步骤7)和步骤9),被测终端均应正确显示主叫号码或对应的标识信息,且应显示呼叫 时间及通话时长。
4) 步骤11),被测终端应以图标或其他方式显示接收到短消息。
