6.2.4G Additional Maximum Power Reduction (A-MPR) for V2X Communication

36.521-13GPPEvolved Universal Terrestrial Radio Access (E-UTRA)Part 1: Conformance testingRadio transmission and receptionRelease 17TSUser Equipment (UE) conformance specification

Tools: ARFCN - Frequency Conversion for 5G NR/LTE/UMTS/GSM

6.2.4G.1 Additional Maximum Power Reduction (A-MPR) for V2X Communication / Non-concurrent with E-UTRA uplink transmissions

6.2.4G.1.1 Test purpose

Additional ACLR and spectrum emission requirements can be signalled by the network to indicate that the UE shall also meet additional requirements in a specific deployment scenario. To meet these additional requirements, Additional Maximum Power Reduction A-MPR is allowed for the output power as specified in Table 6.2.2.3-1. Unless stated otherwise, an A-MPR of 0 dB shall be used.

6.2.4G.1.2 Test applicability

The requirements of this test apply in test case 6.6.2.2.4 Additional Spectrum Emission Mask for network signalled values NS_33 and NS_34 to all types of UE that support V2X Sidelink communication and Band 47.

The requirements of this test apply in test case 6.6.3.2 Additional Spurious Emissions for network signalled values NS_33 and NS_34 to all types of UE that support V2X Sidelink communication and Band 47.

NOTE: As a result TC 6.2.4G.1 has not been included in the test case applicability table 4.1-1, TS 36.521-2. This does not preclude the test from being used for R&D or other purposes if deemed useful.

6.2.4G.1.3 Minimum conformance requirements

When UE is configured for E-UTRA V2X sidelink transmissions non-concurrent with E-UTRA uplink transmissions for E-UTRA V2X operating bands specified in Table 5.2G-1, the maximum output power reduction specified as

A-MPR = CEIL {M_A, 0.5}

Where M_A is defined as follows

M_A = A-MPR_Base+ G_{post connector} * A-MPR_Step

CEIL{M_A, 0.5} means rounding upwards to closest 0.5dB.

A-MPR_Base and A-MPR_Step are specified in Tables 6.2.4G.1.3-1, 6.2.4G.1.3-2 is allowed when network signalling value is provided. The supported post antenna connector gain G_{post connector}is declared by the UE following the principle described in TS 36.101 [2] annex I.

NOTE: the A-MPRstep is the increase in A-MPR allowance to allow UE to meet tighter conducted A-SE and A-SEM requirements with higher value of declared Gpost connector. A-MPRBase is the default A-MPR value when no Gpost connector is declared. A-MPRBase and A-MPRstep vary depending on channel frequency and RB allocation. For channel frequencies and RB allocations that are close to the frequency range 5815-5855MHz, those value are much higher due to stringent emission requirement in this range.

Table 6.2.4G.1.3-1: Additional Maximum Power Reduction (A-MPR) for power class 3 V2X UE

Network Signalling value

Requirements (subclause)

E-UTRA Band

Channel bandwidth (MHz)

A-MPR (dB)

NS_33

6.6.2.2.3.6 (A-SEM)

6.6.3.2.3 (A-SE)

6.6.2G

Table 6.2.4G.1.3-2

Table 6.2.4G.1.3-2: A-MPR for NS_33

Resource pool	Carrier frequency(MHz)	Resources Blocks (N_RB)	Start Resource Block	A-MPR_Base	A-MPR_Step
Adjacent	5860	≤ 10	0	15.5	0.86
			5, 6	8	0.64
			10, 12	6	0.50
			≥ 15	5	0.93
		>10 & ≤22	0	15	0.71
			5, 6	11.5	0.64
			10, 12	10	0.57
			15, 18	6	0.57
			20, 24, 25	5	0.57
			≥ 30	4.5	0.64
		>22	0, 5, 6	12.5	0.71
			10, 12	10.5	0.57
			15, 18	9.5	0.64
			20, 24, 25	6.5	0.71
	5870, 5910, 5920	<20	≥ 0	3	0.64
		≥ 20 and ≤45		1.5	0.43
		>45		2.5	0.36
	5880, 5890, 5900	<10	≥ 0	3	0.43
		≥ 10 and ≤38		1.5	0.50
		>38		2	0.43
Non-Adjacent	5860	≤ 5	≥ 0	13.5	TBD
	5860	>5	≥ 0	11.5	TBD
	5870, 5910, 5920	≤ 5	≥ 0	5	TBD
		>5 & ≤42		3	TBD
		>42		4.5	TBD
	5880, 5890, 5900	≤18	≥ 0	3.5	TBD
		>18 & ≤42		2.5	TBD
		>42		3	TBD

When UE is configured for E-UTRA V2X sidelink transmissions non-concurrent with E-UTRA uplink transmissions for E-UTRA V2X operating bands specified in Table 5.5G-1, the allowed A-MPR for the maximum output power for V2X physical channels PSCCH and PSSCH shall be as specified in Table 6.2.4G.1.3-3 and 6.2.4G.1.3-4 for V2X UE power class 2.

Table 6.2.4G.1.3-3: Additional Maximum Power Reduction (A-MPR) for power class 2 V2X UE

Network Signalling value

Requirements (subclause)

E-UTRA Band

Channel bandwidth (MHz)

A-MPR (dB)

NS_34

6.6.2.2.3.6 (A-SEM)

6.6.3.2.3 (A-SE)

6.6.2G

Table 6.2.4G-4

Table 6.2.4G.1.3-4: A-MPR for NS_34

Resource pool	Carrier frequency(MHz)	Resources Blocks (N_RB)	A-MPR (dB)
Adjacent	5860	<20	15
		>20 & <30	13
		>30	12
	5870, 5900, 5880, 5890, 5900	<15 or >40	1
Non-Adjacent	5860	–	12.5
	5910, 5920	<10	5.5
	5910, 5920	<20 & >10	3
	5870, 5880, 5890, 5900	<10	5.5

The normative reference for this requirement is in TS 36.101 [2] clause 6.2.4G.

6.2.4G.1.4 Test description

6.2.4G.1.4.1 Initial condition

Initial conditions are a set of test configurations the UE needs to be tested in and the steps for the SS to take with the UE to reach the correct measurement state.

The initial test configurations consist of environmental conditions, test frequencies, and channel bandwidths based on E-UTRA operating bands specified in Table 5.2G-1. All of these configurations shall be tested with applicable test parameters for each channel bandwidth, and are shown in table 6.2.4G.1.4.1-1 and 6.2.4G.1.4.1-2. The details of the V2X reference measurement channels (RMCs) are specified in Annex A.8.3 3 and the GNSS configuration in TS 36.508 [7] subclause 4.11.

Table 6.2.4G.1.4.1-1: Test Configuration Table for Power Class 3

Initial Conditions
Test Environment (as specified in TS 36.508 [7] subclause 4.1)			NC
Test Frequencies (as specified in TS 36.508 [7] subclause 4.3.1)			Low range, Mid range, High range
Test Channel Bandwidths (as specified in TS 36.508 [7] subclause 4.3.1)			Lowest
Test Parameters for NS_33 A-MPR
		V2X Configuration to Transmit
Configura-tion ID	Ch BW	Resource pool	Mod’n	PSSCH RB allocation	PSSCH RB_start
1³	10MHz	adjacent	QPSK	3	2
2³	10MHz		QPSK	3	7
3³	10MHz		QPSK	3	12
4³	10MHz		QPSK	3	47
5³	10MHz		QPSK	8	2
6³	10MHz		QPSK	8	7
7³	10MHz		QPSK	8	12
8³	10MHz		QPSK	8	42
9³	10MHz		QPSK	18	2
10³	10MHz		QPSK	18	7
11³	10MHz		QPSK	18	12
12³	10MHz		QPSK	18	17
13³	10MHz		QPSK	18	22
14³	10MHz		QPSK	18	32
15³	10MHz		QPSK	27	2
16³	10MHz		QPSK	27	12
17³	10MHz		QPSK	27	17
18³	10MHz		QPSK	27	22
19³	10MHz		16QAM	3	2
20³	10MHz		16QAM	3	7
21³	10MHz		16QAM	3	12
22³	10MHz		16QAM	3	47
23³	10MHz		16QAM	8	2
24³	10MHz		16QAM	8	7
25³	10MHz		16QAM	8	12
26³	10MHz		16QAM	8	42
27³	10MHz		16QAM	18	2
28³	10MHz		16QAM	18	7
29³	10MHz		16QAM	18	12
30³	10MHz		16QAM	18	17
31³	10MHz		16QAM	18	22
32³	10MHz		16QAM	18	32
33³	10MHz		16QAM	27	2
34³	10MHz		16QAM	27	12
35³	10MHz		16QAM	27	17
36³	10MHz		16QAM	27	22
37⁴	10MHz		QPSK	8	2
38⁴	10MHz		QPSK	18	2
39⁴	10MHz		QPSK	48	2
40⁴	10MHz		16QAM	8	2
41⁴	10MHz		16QAM	18	2
42⁴	10MHz		16QAM	48	2
43⁵	10MHz		QPSK	3	2
44⁵	10MHz		QPSK	8	2
45⁵	10MHz		QPSK	48	2
46⁵	10MHz		16QAM	3	2
47⁵	10MHz		16QAM	8	2
48⁵	10MHz		16QAM	48	2
49³	10MHz	non- adjacent	QPSK	3	5
50³	10MHz		QPSK	45	5
51⁴	10MHz		QPSK	3	5
52⁴	10MHz		QPSK	40	5
53⁴	10MHz		QPSK	45	5
54⁵	10MHz		QPSK	16	5
55⁵	10MHz		QPSK	40	5
56⁵	10MHz		QPSK	45	5
57³	10MHz	adjacent	QPSK	48	2
58⁴	10MHz		QPSK	3	2
59⁴	10MHz		QPSK	3	47
60⁵	10MHz		QPSK	3	47
Note 1: Test Channel Bandwidths are checked separately for E-UTRA band, the applicable channel bandwidths are specified in Table 5.4.2.1-1. Note 2: The configuration ID will be used to map the applicable Test Configuration to be corresponding Test Requirement in subclause 6.2.4G as not all combinations are necessarily required based on the applicability of the UE. Note 3: Only applicable for Low range test frequency. Note 4: Only applicable for High range test frequency. Note 5: Only applicable for Mid range test frequency.

Table 6.2.4G.1.4.1-2: Test Configuration Table for Power Class 2

Initial Conditions
Test Environment (as specified in TS 36.508 [7] subclause 4.1)			NC
Test Frequencies (as specified in TS 36.508 [7] subclause 4.3.1)			Low range, Mid range, High range
Test Channel Bandwidths (as specified in TS 36.508 [7] subclause 4.3.1)			Lowest
Test Parameters for NS_34 A-MPR
		V2X Configuration to Transmit
Configura-tion ID	Ch BW	Resource pool	Mod’n	PSSCH RB allocation	PSSCH RB_start
1³	10MHz	adjacent	QPSK	16	2
2³	10MHz		QPSK	27	2
3³	10MHz		QPSK	48	2
4³	10MHz		16QAM	16	2
5³	10MHz		16QAM	27	2
6³	10MHz		16QAM	48	2
7⁵	10MHz		QPSK	12	2
8⁵	10MHz		QPSK	36	2
9⁵	10MHz		QPSK	48	2
10⁵	10MHz		16QAM	12	2
11⁵	10MHz		16QAM	36	2
12⁵	10MHz		16QAM	48	2
13³	10MHz	non- adjacent	QPSK	45	5
14⁴	10MHz		QPSK	6	5
15⁴	10MHz		QPSK	16	5
16⁴	10MHz		QPSK	45	5
17⁵	10MHz		QPSK	6	5
18⁵	10MHz		QPSK	45	5
19³	10MHz	adjacent	QPSK	3	2
20³	10MHz		QPSK	3	47
21⁴	10MHz		QPSK	3	2
22⁴	10MHz		QPSK	3	47
23⁴	10MHz		QPSK	48	2
24⁵	10MHz		QPSK	3	2
25⁵	10MHz		QPSK	3	47
Note 1: Test Channel Bandwidths are checked separately for E-UTRA band, the applicable channel bandwidths are specified in Table 5.4.2.1-1. Note 2: The configuration ID will be used to map the applicable Test Configuration to be corresponding Test Requirement in subclause 6.2.4G as not all combinations are necessarily required based on the applicability of the UE. Note 3: Only applicable for Low range test frequency. Note 4: Only applicable for High range test frequency. Note 5: Only applicable for Mid range test frequency.

1. Connect the SS and GNSS simulator to the UE antenna connectors as shown in TS 36.508 [7] Annex A, Figure A.92.

2. The parameter settings for the V2X sidelink transmission over PC5 are pre-configured according to TS 36.508 [7] subclause 4.10.1. Message content exceptions are defined in clause 6.2.4G.1.4.3.

3. The V2X reference measurement channel is set according to Table 6.2.4G.1.4.1-1 and Table 6.2.4G.1.4.1-2.

4. The GNSS simulator is configured for Scenario #1: static in Geographical area #1, as defined in TS36.508 [7] Table 4.11.2-2. Geographical area #1 is also pre-configured in the UE.

5. Propagation conditions are set according to Annex B.0.

6. Ensure the UE is in State 5A-V2X in Transmit Mode according to TS 36.508 [7] clause 4.5.9.

7. The GNSS simulator is triggered to start step 1 of Scenario #1 to simulate a location in the centre of Geographical area #1. Wait for the UE to acquire the GNSS signal and start to transmit.

6.2.4G.1.4.2 Test procedure

1. The UE starts to perform the V2X sidelink communication according to SL-V2X-Preconfiguration. Since the UE has no payload and no loopback data to send the UE sends uplink MAC padding bits on the V2X RMC. (UE should be already transmitting P_UMAX after Initial Conditions setting)

2. Measure the mean power of the UE in the channel bandwidth for each test point in table 6.2.4G.1.5-1 according to the test configuration from Table 6.2.4G.1.4.1-1 for Power Class 3 and Table 6.2.4G.1.4.1-2 for Power Class 2. The period of measurement shall be at least continuous duration of one sub-frame (1ms).

6.2.4G.1.4.3 Message contents

Message contents are according to TS 36.508 [7] clause 4.6, 4.7.I and 4.10 with the following exceptions:

Table 6.2.4G.1.4.3-1: SL-CommResourcePoolV2X-r14 for non- adjacent resource pool

Derivation Path: TS 36.508 [7] clause 4.6.3, Table 4.6.3-20C SL-CommResourcePoolV2X-r14-DEFAULT
Information Element	Value/remark	Comment	Condition
SL-CommResourcePoolV2X-r14-DEFAULT ::= SEQUENCE {
adjacencyPSCCH-PSSCH-r14	FALSE	BOOLEAN
numSubchannel-r14	n9
startRB-Subchannel-r14	5		10 MHz
startRB-PSCCH-Pool-r14	0

6.2.4G.1.4.3.1 Message contents exceptions (network signalled value "NS_33")

1. Information element additionalSpectrumEmission is set to NS_33. This can be set in the SL-PreconfigGeneral-r12 as part of the SL-V2X-Preconfiguration. This exception indicates that the UE shall meet the additional spurious emission requirement for a specific deployment scenario.

Table 6.2.4G.1.4.3.1-1: SL-V2X-PreconfigFreqInfo-r14-DEFAULT: Additional spurious emissions test requirement for "NS_33"

Derivation Path: TS 36.508 [7] clause 4.6.3, Table 4.6.3-20K SL-V2X-PreconfigFreqInfo-r14-DEFAULT
Information Element	Value/remark	Comment	Condition
additionalSpectrumEmission-v1440	33 (NS_33)

6.2.4G.1.4.3.2 Message contents exceptions (network signalled value "NS_34")

1. Information element additionalSpectrumEmission is set to NS_34. This can be set in the SL-PreconfigGeneral-r12 as part of the SL-V2X-Preconfiguration. This exception indicates that the UE shall meet the additional spurious emission requirement for a specific deployment scenario.

Table 6.2.4G.1.4.3.2-1: SL-V2X-PreconfigFreqInfo-r14-DEFAULT: Additional spurious emissions test requirement for "NS_34"

Derivation Path: TS 36.508 [7] clause 4.6.3, Table 4.6.3-20K SL-V2X-PreconfigFreqInfo-r14-DEFAULT
Information Element	Value/remark	Comment	Condition
additionalSpectrumEmission-v1440	34 (NS_34)

6.2.4G.1.5 Test Requirements

The maximum output power, derived in step 2 shall be within the range prescribed by the nominal maximum output power and tolerance in the applicable Table 6.2.4G.1.4.1-1 and Table 6.2.4G.1.4.1-2. For the UE maximum output power modified by A-MPR specified in sub-clause 6.2.4G.1.3, the power limits specified in Table 6.2.5.3-1 apply.

Table 6.2.4G.1.5-1: Test requirement (network signalled value NS_33)

Configuration ID	MPR (dB)	A-MPR (dB)	ΔT_C,c (dB)	P_CMAX,c (dBm)	T(P_{CMAX_L,c}) (dB)	Upper limit (dBm)	Lower limit (dBm)
1	1.5	20	0	1.5	7.0	26.3	-6.8
2	1.5	8	0	13.5	5.0	26.3	7.2
3	1.5	6	0	15.5	5.0	26.3	9.2
4	1.5	5	0	16.5	5.0	26.3	10.2
5	1.5	15.5	0	6	7.0	26.3	-2.3
6	1.5	8	0	13.5	5.0	26.3	7.2
7	1.5	6	0	15.5	5.0	26.3	9.2
8	1.5	5	0	16.5	5.0	26.3	10.2
9	1.5	15	0	6.5	7.0	26.3	-3.3
10	1.5	11.5	0	10	6.0	26.3	2.7
11	1.5	10	0	11.5	6.0	26.3	4.2
12	1.5	6	0	15.5	5.0	26.3	9.2
13	1.5	5	0	16.5	5.0	26.3	10.2
14	1.5	4.5	0	17	5.0	26.3	10.7
15	1.5	12.5	0	9	6.0	26.3	1.7
16	1.5	10.5	0	11	6.0	26.3	3.7
17	1.5	9.5	0	12	6.0	26.3	4.7
18	1.5	6.5	0	15	5.0	26.3	8.7
19	2	20	0	1	7.0	26.3	-7.3
20	2	8	0	13	5.0	26.3	6.7
21	2	6	0	15	5.0	26.3	8.7
22	2	5	0	16	5.0	26.3	9.7
23	2	15.5	0	5.5	7.0	26.3	-2.8
24	2	8	0	13	5.0	26.3	6.7
25	2	6	0	15	5.0	26.3	8.7
26	2	5	0	16	5.0	26.3	9.7
27	2	15	0	6	7.0	26.3	-2.3
28	2	11.5	0	9.5	6.0	26.3	2.2
29	2	10	0	11	6.0	26.3	3.7
30	2	6	0	15	5.0	26.3	8.7
31	2	5	0	16	5.0	26.3	9.7
32	2	4.5	0	16.5	5.0	26.3	10.2
33	2	12.5	0	8.5	6.0	26.3	1.2
34	2	10.5	0	10.5	6.0	26.3	3.2
35	2	9.5	0	11.5	6.0	26.3	4.2
36	2	6.5	0	14.5	5.0	26.3	8.2
37	1.5	3	0	18.5	4.0	26.3	13.2
38	1.5	1.5	0	20	2.5	26.3	16.2
39	1.5	2.5	0	19	3.5	26.3	14.2
40	2	3	0	18	4.0	26.3	12.7
41	2	1.5	0	19.5	3.5	26.3	14.7
42	2	2.5	0	18.5	4.0	26.3	13.2
43	1.5	3	0	18.5	4.0	26.3	13.2
44	1.5	1.5	0	20	2.5	26.3	16.2
45	1.5	2	0	19.5	3.5	26.3	14.7
46	2	3	0	18	4.0	26.3	12.7
47	2	1.5	0	19.5	3.5	26.3	14.7
48	2	2	0	19	3.5	26.3	14.2
49	4.5	13.5	0	5	7.0	26.3	-3.3
50	2	11.5	0	9.5	6.0	26.3	2.2
51	4.5	5	0	13.5	5.0	26.3	7.2
52	2	3	0	18	4.0	26.3	12.7
53	2	4.5	0	16.5	5.0	26.3	10.2
54	3.5	3.5	0	16	5.0	26.3	9.7
55	2	2.5	0	18.5	4.0	26.3	13.2
56	2	3	0	18	4.0	26.3	12.7
57	1.5	12.5	0	9	6.0	26.3	1.7
58	1.5	3	0	18.5	4.0	26.3	13.2
59	1.5	3	0	18.5	4.0	26.3	13.2
60	1.5	3	0	18.5	4.0	26.3	13.2
Note 1: Lower limit is assuming Δ_TIB,c is zero. If non-zero, P_CMAX,c will decrease and T(P_{CMAX_L,c}) may be higher resulting in different test requirements according to Table 6.2.5.3-1. Note 2: The default value of G_{post connector} is 0dBi, if external antenna is not used.

Table 6.2.4G.1.5-2: Test requirement (network signalled value NS_34)

Configuration ID	MPR (dB)	A-MPR (dB)	ΔT_C,c (dB)	P_CMAX,c (dBm)	T(P_{CMAX_L,c}) (dB)	Upper limit (dBm)	Lower limit (dBm)
1	2	15		9	6.0	29.3	1.7
2	2	13	0	11	6.0	29.3	3.7
3	2	12	0	12	6.0	29.3	4.7
4	2.5	15		8.5	6.0	29.3	1.2
5	2.5	13	0	10.5	6.0	29.3	3.2
6	2.5	12	0	11.5	6.0	29.3	4.2
7	2	1	0	23	2.0	29.3	19.7
8	2	0	0	24	2.0	29.3	20.7
9	2	1	0	23	2.0	29.3	19.7
10	2.5	1	0	22.5	2.0	29.3	19.2
11	2.5	0	0	23.5	2.0	29.3	20.2
12	2.5	1	0	22.5	2.0	29.3	19.2
13	2.5	12.5	0	11.0	6.0	29.3	3.7
14	4.5	5.5	0	16.0	5.0	29.3	9.7
15	2.5	3	0	20.5	2.5	29.3	16.7
16	2.5	0	0	23.5	2.0	29.3	20.2
17	4.5	5.5	0	16.0	5.0	29.3	9.7
18	2.5	0	0	23.5	2.0	29.3	20.2
19	2	15	0	9	6.0	29.3	1.7
20	2	15	0	9	6.0	29.3	1.7
21	2	0	0	24	2.0	29.3	20.7
22	2	0	0	24	2.0	29.3	20.7
23	2	0	0	24	2.0	29.3	20.7
24	2	1	0	23	2.0	29.3	19.7
25	2	1	0	23	2.0	29.3	19.7
Note 1: Lower limit is assuming Δ_TIB,c is zero. If non-zero, P_CMAX,c will decrease and T(P_{CMAX_L,c}) may be higher resulting in different test requirements according to Table 6.2.5.3-1. Note 2: The default value of G_{post connector} is 0dBi, if external antenna is not used.

6.2.4G.2 Additional Maximum Power Reduction (A-MPR) for V2X Communication / Simultaneous E-UTRA V2X sidelink and E-UTRA uplink transmissions

6.2.4G.2.1 Test purpose

6.2.4G.2.2 Test applicability

The requirements of this test apply in test case 6.6.2.2.4 Additional Spectrum Emission Mask for simultaneous E-UTRA V2X sidelink and E-UTRA uplink transmissions for network signalled values NS_04/NS_33 to all types of E-UTRA Power Class 3 UE release 14 and forward that support V2X communication and is capable of V2X Sidelink communication simultaneous with E-UTRA uplink transmissions.

The requirements of this test apply in test case 6.6.3.3 Additional Spurious Emissions for simultaneous E-UTRA V2X sidelink and E-UTRA uplink transmissions for network signalled values NS_04/NS_33 to all types of E-UTRA Power Class 3 UE release 14 and forward that support V2X communication and is capable of V2X Sidelink communication simultaneous with E-UTRA uplink transmissions.

NOTE: As a result TC 6.2.4G.2 has not been included in the test case applicability table 4.1-1, TS 36.521-2. This does not preclude the test from being used for R&D or other purposes if deemed useful.

6.2.4G.2.3 Minimum conformance requirements

When UE is configured for simultaneous E-UTRA V2X sidelink and E-UTRA uplink transmissions for inter-band E-UTRA V2X / E-UTRA bands specified in Table 5.2G-2, the requirements in subclause 6.2.4G.1 apply for V2X PSSCH and PSCCH transmission. The allowed A-MPR requirements in subclause 6.2.4D [2] apply for other V2X sidelink transmission (PSBCH/PSSS/SSSS). The A-MPR requirements in subclause 6.2.4 apply for uplink transmission.

The configured maximum output power P_CMAX_c_,_E-UTRA(p) in subframe p for the configured E-UTRA uplink carrier shall be set within the bounds:

P_{CMAX_L,}_c,E-UTRA (p) ≤ P_CMAX,_c,E-UTRA(p) ≤ P_{CMAX_H,}_c,E-UTRA (p)

where P_{CMAX_L,}_c,E-UTRAandP_{CMAX_H,}_c,E-UTRA are the limits for a serving cell c as specified in subclause 6.2.5.

The configured maximum output power P_CMAX_c_,_V2X(q) in subframe q for the configured E-UTRA V2X carrier shall be set within the bounds:

P_CMAX,_c,V2X(q) ≤ P_{CMAX_H,}_c,V2X (q)

where P_{CMAX_H,}_c,V2X is the limit as specified in subclause 6.2.5G.

The total UE configured maximum output power P_CMAX(p,q) in a subframe p of an E-UTRA uplink carrier and a subframe q of an E-UTRA V2X sidelink that overlap in time shall be set within the following bounds for synchronous and asynchronous operation unless stated otherwise:

P_{CMAX_L}(p,q) ≤ P_CMAX(p,q) ≤ P_{CMAX_H}(p,q)

with

P_{CMAX_L}(p,q) = P_{CMAX_L,}_c,E-UTRA (p)

P_{CMAX_H}(p,q) = 10 log₁₀ [p_{CMAX_H,}_c,E-UTRA(p) + p_{CMAX_H,}_c,V2X(q)]

where p_{CMAX_H}_,c,V2X and p_{CMAX_H,}_c,E-UTRAare the limits P_{CMAX_H,}_c,V2X (q) and P_{CMAX_H,}_c,E-UTRA (p) expressed in linear scale.

The measured total maximum output power P_UMAX over both the E-UTRA uplink and E-UTRA V2X carriers is

P_UMAX = 10 log₁₀ [p_UMAX,_c,E-UTRA + p_UMAX,_c,V2X],

where p_UMAX,_c,E-UTRA denotes the measured output power of serving cell c for the configured E-UTRA uplink carrier, and p_UMAX,_c,V2Xdenotes the measured output power for the configured E-UTRA V2X carrier expressed in linear scale.

When a UE is configured for synchronous V2X sidelink and uplink transmissions,

P_{CMAX_L}(p, q) – T_LOW (P_{CMAX_L}(p, q)) ≤ P_UMAX ≤ P_{CMAX_H}(p, q) + T_HIGH (P_{CMAX_H}(p, q))

where P_{CMAX_L}(p,q) and P_{CMAX_H}(p,q) are the limits for the pair (p,q) and with the tolerances T_LOW(P_CMAX) and T_HIGH(P_CMAX) for applicable values of P_CMAX specified in Table 6.2.5C-1. P_{CMAX_L} may be modified for any overlapping portion of subframes (p, q) and (p +1, q+1).

The normative reference for this requirement is in TS 36.101 [2] clause 6.2.4G.

6.2.4G.2.4 Test description

6.2.4G.2.4.1 Initial condition

Initial conditions are a set of test configurations the UE needs to be tested in and the steps for the SS to take with the UE to reach the correct measurement state.

The initial test configurations consist of environmental conditions, test frequencies, and channel bandwidths based on E-UTRA operating bands specified in Table 5.4.2G.1-2. All of these configurations shall be tested with applicable test parameters for each channel bandwidth, and are shown in table 6.2.4G.2.4.1-1. The details of the uplink and V2X reference measurement channels (RMCs) are specified in A.2 and A.8.3 respectively. Configurations of PDSCH and PDCCH before measurement are specified in Annex C.2.

Table 6.2.4G.2.4.1-1: Test Configuration Table

Initial Conditions
Test Environment as specified in TS 36.508 [7] subclause 4.1					NC
Test Frequencies as specified in TS 36.508 [7] subclause 4.3.1					Low range for uplink and Low range for V2X, High range for uplink and High range for V2X
Test Channel Bandwidths as specified in TS 36.508 [7] subclause 4.3.1					5MHz for uplink and 10MHz for V2X 20MHz for uplink and 10MHz for V2X
Test Parameters for NS_04 and NS_33 A-MPR
	E-UTRA uplink Configuration to Transmit				V2X Configuration to Transmit
Configura-tion ID	Ch BW	Mod’n	PUSCH RB allocation	RB_start TDD	Ch BW	Resource pool	Mod’n	PSSCH RB allocation	PSSCH RB_start
1¹	5MHz	QPSK	1	0	10MHz	adjacent	QPSK	8	2
2¹	5MHz	QPSK	16	9	10MHz		QPSK	27	2
3¹	5MHz	16QAM	16	9	10MHz		QPSK	8	2
4¹	5MHz	16QAM	16	9	10MHz		QPSK	27	2
5²	5MHz	QPSK	25	0	10MHz		QPSK	8	2
6²	5MHz	QPSK	25	0	10MHz		QPSK	48	2
7²	5MHz	16QAM	25	0	10MHz		QPSK	8	2
8²	5MHz	16QAM	25	0	10MHz		QPSK	48	2
9¹	20MHz	QPSK	1	0	10MHz		QPSK	8	2
10¹	20MHz	QPSK	100	0	10MHz		QPSK	27	2
11¹	20MHz	16QAM	100	0	10MHz		QPSK	8	2
12¹	20MHz	16QAM	100	0	10MHz		QPSK	27	2
13²	20MHz	QPSK	100	0	10MHz		QPSK	8	2
14²	20MHz	QPSK	100	0	10MHz		QPSK	48	2
15²	20MHz	16QAM	100	0	10MHz		16QAM	8	2
16²	20MHz	16QAM	100	0	10MHz		16QAM	48	2
17¹	5MHz	QPSK	1	0	10MHz	non- adjacent	QPSK	3	5
18¹	5MHz	QPSK	16	9	10MHz		QPSK	45	5
19¹	5MHz	16QAM	16	9	10MHz		QPSK	3	5
20¹	5MHz	16QAM	16	9	10MHz		QPSK	45	5
21²	5MHz	QPSK	25	0	10MHz		QPSK	3	5
22²	5MHz	QPSK	25	0	10MHz		QPSK	45	5
23²	5MHz	16QAM	25	0	10MHz		QPSK	3	5
24²	5MHz	16QAM	25	0	10MHz		QPSK	45	5
25¹	20MHz	QPSK	1	0	10MHz		QPSK	3	5
26¹	20MHz	QPSK	100	0	10MHz		QPSK	45	5
27¹	20MHz	16QAM	100	0	10MHz		QPSK	3	5
28¹	20MHz	16QAM	100	0	10MHz		QPSK	45	5
29²	20MHz	QPSK	100	0	10MHz		QPSK	3	5
30²	20MHz	QPSK	100	0	10MHz		QPSK	45	5
31²	20MHz	16QAM	100	0	10MHz		QPSK	3	5
32²	20MHz	16QAM	100	0	10MHz		QPSK	45	5
Note 1: Test Channel Bandwidths are checked separately for E-UTRA band, the applicable channel bandwidths are specified in Table 5.4.2.1-1. Note 2: The configuration ID will be used to map the applicable Test Configuration to be corresponding Test Requirement in subclause 6.2.4G as not all combinations are necessarily required based on the applicability of the UE. Note 3: Only applicable for Low range for uplink and Low range for V2X. Note 4: Only applicable for High range for uplink and High range for V2X.

1. Connect the SS to the UE antenna connectors as shown in TS 36.508 [7] Annex A, Figure A.93a.

2. The parameter settings for the cell are set up according to TS 36.508 [7] subclause 4.4.3. Message content exceptions are defined in clause 6.2.4G.2.4.3

3. Downlink signals are initially set up according to Annex C.0, C.1, and C.3.0, and uplink signals according to Annex H.1 and H.3.0.

4. The UL and V2X Reference Measurement Channels are set according to Table 6.2.4G.2.4.1-1.

5. Propagation conditions are set according to Annex B.0.

6. Ensure the UE is in State 3A-RF-V2X according to TS 36.508 [7] clause 5.2A.2C. Message content exceptions are defined in clause 6.2.4G.2.4.3.

6.2.4G.2.4.2 Test procedure

1. The SS simultaneously sends uplink scheduling information for each UL HARQ process via PDCCH DCI format 0 for C_RNTI to schedule the UL RMC and V2X scheduling information via PDCCH DCI format 5A for SL_V_RNTI to schedule the V2X RMC according to Table 6.2.4G.2.4.1-1. Since the UE has no payload and no loopback data to send the UE sends uplink MAC padding bits on the UL and V2X RMCs.

2. Send continuously uplink power control "up" commands in the uplink scheduling information to the UE to ensure that the UE transmits at P_UMAXlevel. Configure the UE to transmit PSCCH and PSSCH with the P_UMAX level of each test points; allow at least 200ms for the UE to reach P_UMAXlevel.

3. Measure the mean power over all component carriers in the V2X con-current band configuration. The period of measurement shall be at least continuous duration of one sub-frame (1ms). On E-UTRA carrier, the TDD slots with transient periods are not under test.

6.2.4G.2.4.3 Message contents

Message contents are according to TS 36.508 [7] clause 4.6, 4.7.I and 4.10 with the following exceptions:

Table 6.2.4G.2.4.3-1: SL-CommResourcePoolV2X-r14 for non- adjacent resource pool

Derivation Path: TS 36.508 [7] clause 4.6.3, Table 4.6.3-20C SL-CommResourcePoolV2X-r14-DEFAULT
Information Element	Value/remark	Comment	Condition
SL-CommResourcePoolV2X-r14-DEFAULT ::= SEQUENCE {
adjacencyPSCCH-PSSCH-r14	FALSE	BOOLEAN
numSubchannel-r14	n9
startRB-Subchannel-r14	5		10 MHz
startRB-PSCCH-Pool-r14	0

6.2.4G.2.4.3.1 Message contents exceptions (network signalled value "NS_04" for E-UTRA uplink transmission)

1. Information element additionalSpectrumEmission is set to NS_04. This can be set in the SystemInformationblockType2 as part of the cell broadcast message. This exception indicates that the UE shall meet the additional spurious emission requirement for a specific deployment scenario.

Table 6.2.4G.2.4.3.1-1: SystemInformationBlockType2: Additional spurious emissions test requirement for "NS_04"

Derivation Path: TS 36.508 [7] clause 4.4.3.3, Table 4.4.3.3-1
Information Element	Value/remark	Comment	Condition
additionalSpectrumEmission	4 (NS_04)

6.2.4G.2.4.3.2 Message contents exceptions (network signalled value "NS_33" for E-UTRA V2X sidelink transmission)

Table 6.2.4G.2.4.3.1-2: SL-PreconfigGeneral-r12: Additional spurious emissions test requirement for "NS_33"

Derivation Path: TS 36.331 [5] clause 9.3.2
Information Element	Value/remark	Comment	Condition
additionalSpectrumEmission	33 (NS_33)

6.2.4G.2.5 Test Requirements

The maximum output power, derived in step 2 shall be within the range prescribed by the nominal maximum output power and tolerance in the applicable Table 6.2.4G.2.4.1-1. For the UE maximum output power modified by A-MPR specified in sub-clause 6.2.4G.2.3, the power limits specified in Table 6.2.5.3-1 apply.

Table 6.2.4G.2.5-1: Test requirement (network signalled value NS_04/NS_33)

Configuration ID	MPR_E-UTRA (dB)	A-MPR_E-UTRA (dB)	ΔT_C,c.E-UTRA (dB)	P_{CMAX,c,E-UTRA} (dBm)	MPR_V2X (dB)	A-MPR_V2X (dB)	ΔT_C,c,V2X (dB)	P_CMAX,c,V2X (dBm)	ΔT_IB,c (dB)	P_{CMAX_L}(p, q) (dBm)	T(P_{CMAX_L,c}) (dB)	Upper limit (dBm)	Lower limit (dBm)
1	0	2	1.5	19.5	1.5	15.5	1.5	4.5	0	19.6	5	26.3	13.3
2	1	0	0	22	1.5	12.5	0	9	0	22.2	5	26.3	15.9
3	2	0	0	21	1.5	15.5	1.5	4.5	0	21.1	5	26.3	14.8
4	2	0	0	21	1.5	12.5	0	9	0	21.3	5	26.3	15.0
5	1	0	0	22	1.5	3	0	18.5	0	23.6	3	26.3	19.3
6	1	0	0	22	1.5	2.5	0	19	0	23.8	3	26.3	19.5
7	2	0	0	21	1.5	3]	0	18.5	0	22.9	5	26.3	16.6
8	2	0	0	21	1.5	2	0	19	0	23.1	3	26.3	18.8
9	0	3	1.5	18.5	1.5	15.5	1.5	4.5	0	18.7	5	26.3	12.4
10	1	3	0	19	1.5	12.5	0	9	0	19.4	5	26.3	13.1
11	2	3	0	18	1.5	15.5	0	6	0	18.3	5	26.3	12.0
12	2	3	0	18	1.5	12.5	0	9	0	18.5	5	26.3	12.2
13	1	0	0	22	1.5	3	0	18.5	0	23.6	3	26.3	19.3
14	1	0	0	22	1.5	2.5	0	19	0	23.8	3	26.3	19.5
15	2	0	0	21	2	3	0	18	0	22.8	5	26.3	16.5
16	2	0	0	21	2	2.5	0	18.5	0	22.9	5	26.3	16.6
17	0	2	1.5	19.5	4.5	13.5	1.5	3.5	0	19.6	5	26.3	13.3
18	1	0	0	22	2	11.5	0	9.5	0	22.2	5	26.3	15.9
19	2	0	0	21	4.5	13.5	1.5	3.5	0	21.1	5	26.3	14.8
20	2	0	0	21	2	11.5	0	9.5	0	21.3	5	26.3	15.0
21	1	0	0	22	4.5	53.5	0	13.5	0	22.6	5	26.3	16.3
22	1	0	0	22	2	4.5	0	16.5	0	23.1	3	26.3	18.8
23	2	0	0	21	4.5	5	0	13.5	0	21.7	5	26.3	15.4
24	2	0	0	21	2	4.5	0	16.5	0	22.3	5	26.3	16.0
25	0	3	1.5	18.5	4.5	13.5	1.5	3.5	0	18.6	5	26.3	12.3
26	1	3	0	19	2	11.5	0	9.5	0	19.5	5	26.3	13.2
27	2	3	0	18	4.5	13.5	1.5	3.5	0	18.2	5	26.3	11.9
28	2	3	0	18	2	11.5	0	9.5	0	18.6	5	26.3	12.3
29	1	0	0	22	4.5	5	0	13.5	0	22.6	5	26.3	16.3
30	1	0	0	22	2	4.5	0	16.5	0	23.1	3	26.3	18.8
31	2	0	0	21	4.5	5	0	13.5	0	21.7]	5	26.3	15.4
32	2	0	0	21	2	4.5	0	16.5	0	22.3	5	26.3	16.0
Note 1: Lower limit is assuming Δ_TIB,c is zero. If non-zero, P_CMAX,c will decrease and T(P_{CMAX_L,c}) may be higher resulting in different test requirements according to Table 6.2.5G.2.3-1.