6.2.5G Configured transmitted power for V2X Communication

36.1013GPPEvolved Universal Terrestrial Radio Access (E-UTRA)Release 18TSUser Equipment (UE) radio transmission and reception

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 V2X UE is allowed to set its configured maximum output power P_CMAX,c for component carrier c. The configured maximum output power P_CMAX,c is set within the following bounds:

P_{CMAX_L,c} ≤ P_CMAX,c ≤ P_{CMAX_H,c} with

P_{CMAX_L,c} = MIN {P_EMAX,c – T_C,c, P_PowerClass –– MAX(MPR_c + A-MPR_c + ΔT_IB,c + T_C,c + T_ProSe, P-MPR_c), P_Regulatory,c }

P_{CMAX_H,c} = MIN {P_EMAX,c, P_PowerClass, P_Regulatory,c }

where

– For the total transmitted power P_CMAX,c of PSSCH and PSCCH, P_EMAX,c is the value given by IE maxTxPower, defined by [7], when the UE is not associated with a serving cell on the V2X carrier.

– For, P_EMAX,c is the value given by the IE maxTxPower in [7] when the UE is not associated with a serving cell on the V2X carrier.

– For, the value is as calculated for and applying the MPR for SSSS as specified in Section 6.2.3D.

– P_PowerClass is the maximum UE power specified in Table 6.2.2-1 without taking into account the tolerance specified in the Table 6.2.2-1;

– MPR_c and A-MPR_c for serving cell c are specified in subclause 6.2.3G and subclause 6.2.4G, respectively;

– T_IB,c, T_C,c, T_ProSe and P-MPR_c are specified in subclause 6.2.5

– P_Regulatory,c= 10 – G_{post connector} dBm when the V2X UE is within the protected zone [13] of CEN DSRC tolling system and operating in Band 47; P_Regulatory,c= 33 – G_{post connector} dBm otherwise.

The maximum output power P_CMAX,PSSCH and P_CMAX,PSCCH are derived from P_CMAX,c based on the PSD offset following subclause 14.1.1.5 in [6]. For all cases, the PSD difference between PSCCH and PSSCH shall be the same as the PSD offset value.

For the measured configured maximum output power P_UMAX,c for E-UTRA V2X sidelink transmissions non-concurrent with E-UTRA uplink transmissions, the same requirement as in subclause 6.2.5 shall be applied.

When a 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 5.5G-2, the UE is allowed to set its configured maximum output power P_{CMAX,c,E-UTRA} and P_CMAX,c,V2X for the configured E-UTRA uplink carrier and the configured E-UTRA V2X carrier, respectively, and its total configured maximum output power P_CMAX,c. The T_IB,c of P_{CMAX,c,E-UTRA} is specified in Table 6.2.5G-1.

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-UTRA} and P_{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-UTRA} are 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,V2X denotes 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 6.2.5G-2. P_{CMAX_L} may be modified for any overlapping portion of subframes (p, q) and (p +1, q+1).

When a UE is configured for asynchronous V2X and uplink transmissions, the subframe p for the E-UTRA uplink carrier and subframe q for the E-UTRA V2X carrier overlap in time and

1. if uplink carrier leads in time over q and V2X UE sidelink transmission has SCI whose “Priority” field is set to a value less than the high layer parameter thresSL-TxPrioritization, then p is the reference subframe and the (p,q) and (p,q-1) pairs are considered for determining the PCMAX tolerance

2. if uplink carrier leads in time over q and V2X UE sidelink transmission has SCI whose “Priority” field is set to a value larger than the high layer parameter thresSL-TxPrioritization, then q is the reference subframe and the (p,q) and (p+1,q) pairs are considered for determining the PCMAX tolerance

3. if V2X carrier leads in time over p and V2X UE sidelink transmission has SCI whose “Priority” field is set to a value less than the high layer parameter thresSL-TxPrioritization, then p is the reference subframe and the (p,q) and (p,q+1) pairs are considered for determining the PCMAX tolerance

4. if V2X carrier leads in time over p and V2X UE sidelink transmission has SCI whose “Priority” field is set to a value larger than the high layer parameter thresSL-TxPrioritization,, then q is the reference subframe and the (p-1,q) and (p,q) pairs are considered for determining the PCMAX tolerance

For the reference subframe p duration when uplink carrier leads:

P’_{CMAX_L} = P_{CMAX_L,,cE-UTRA} (p)

P’_{CMAX_H} = MAX {P_{CMAX_H} (p,q-1) , P_{CMAX_H} (p,q)}

For the reference subframe p duration when V2X carrier leads:

P’_{CMAX_L} = P_{CMAX_L,c,E-UTRA} (p)

P’_{CMAX_H} = MAX {P_{CMAX_H} (p,q) , P_{CMAX_H} (p,q+1)}

For the reference subframe q duration when uplink carrier leads:

P’_{CMAX_L} = P_{CMAX_L,c, E-UTRA} (q)

P’_{CMAX_H} = MAX {P_{CMAX_H} (p,q) , P_{CMAX_H} (p+1,q)}

For the reference subframe q duration when V2X carrier leads:

P’_{CMAX_L} = P_{CMAX_L,c, E-UTRA} (p)

P’_{CMAX_H} = MAX {P_{CMAX_H} (p-1,q) , P_{CMAX_H} (p,q)}

where P_{CMAX_L,,cE-UTRA} (p) and P_{CMAX_H} are the applicable limits for each overlapping subframe pairs above 4case with (p,q), (p, q-1) or (p,q), (p, q+1) or (p,q), (p+1,q) or (p,q), (p-1, q). The measured total configured maximum output power P_UMAX shall be within the following bounds:

P’_{CMAX_L} – T_LOW (P’_{CMAX_L}) ≤ P_UMAX ≤ P’_{CMAX_H} + T_HIGH (P’_{CMAX_H})

with the tolerances T_LOW(P_CMAX) and T_HIGH(P_CMAX) for applicable values of P_CMAX specified in Table 6.2.5G-2.

For intra-band contiguous multi-carrier operation, MPR_c = MPR and A-MPR_c = A-MPR with MPR and A-MPR specified in subclause 6.2.3G and subclause 6.2.4G respectively. There is one power management term for the UE, denoted P-MPR, and P-MPR _c = P-MPR. P_CMAX,c is calculated under the assumption that the transmit power is increased by the same amount in dB on all component carriers.

The total configured maximum output power P_CMAX shall be set within the following bounds:

P_{CMAX_L} ≤ P_CMAX ≤ P_{CMAX_H}

P_{CMAX_L} = MIN{10 log₁₀ ∑ p_EMAX,c – T_C , P_PowerClass – MAX(MPR + A-MPR + ΔT_IB,c + T_C + T_ProSe, P-MPR ), P_Regulatory }

P_{CMAX_H} = MIN{10 log₁₀ ∑ p_EMAX,c , P_PowerClass, P_Regulatory }

where

– p_EMAX,c is the linear value of P_EMAX,c which is given by IE maxTxPower in [7];

– P_PowerClass is the maximum UE power specified in Table 6.2.2G-1 without taking into account the tolerance specified in the Table 6.2.2G-1;

– MPR and A-MPR are specified in subclause 6.2.3G and subclause 6.2.4G respectively;

– T_IB,c is the additional tolerance for serving cell c as specified in Table 6.2.5-2;

– P-MPR is the power management term for the UE;

– T_C is the highest value T_C,c among all serving cells c in the subframe over both timeslots. T_C,c = 1.5 dB when NOTE 2 in Table 6.2.2-1 applies, otherwise T_C,c = 0 dB;

– T_ProSe applies as specified in subclause 6.2.5.

– P_Regulatory= 10 – G_{post connector} dBm when V2X UE is within the protected zone [13] of CEN DSRC tolling system and operating in Band 47; P_Regulatory= 33 – G_{post connector} dBm otherwise.

NOTE: The supported post antenna connector gain G_{post connector} declared by the UE following the principle described in annex I.

Table 6.2.5G-1: ΔT_IB,c for inter-band con-current V2X operation (two bands)

V2X con-current band Combination	E-UTRA or V2X Operating Band	ΔTIB,c [dB]
V2X_3-47	3	0.0
V2X_5-47	5	0.2
V2X_7-47	7	0.0
V2X_8-47	8	0.0
V2X_20-47	20	0.2
V2X_28A-47A	28	0.2
V2X_34-47	34	0.0
V2X_39-47	39	0.0
V2X_41-47	41	0.0
V2X_71A-47A	71	0.0

For V2X UE supporting Transmit Diversity, the transmitted power is configured per each UE.

If the UE transmits on two antenna connectors at the same time, the tolerance is specified in Table 6.2.5G-2 and 6.2.5G-3 for PC2 and PC3 V2X UE respectively.

Table 6.2.5G-2: P_CMAX,c tolerance in Transmit Diversity scheme for PC2 V2X UE

PCMAX,c (dBm)	Tolerance TLOW(PCMAX_L,c) (dB)	Tolerance THIGH(PCMAX_H,c) (dB)
PCMAX,c =26	3.0	2.0
23 ≤ PCMAX,c < 26	4.0	2.0
22 ≤ PCMAX,c < 23	5.0	2.0
21 ≤ PCMAX,c < 22	5.0	3.0
20 ≤ PCMAX,c < 21	6.0	4.0
16 ≤ PCMAX,c < 20	5.0
11 ≤ PCMAX,c < 16	6.0
-30 ≤ PCMAX,c < 11	7.0

Table 6.2.5G-3: P_CMAX,c tolerance in Transmit Diversity scheme for PC3 V2X UE

PCMAX,c (dBm)	Tolerance TLOW(PCMAX_L,c) (dB)	Tolerance THIGH(PCMAX_H,c) (dB)
PCMAX,c =23	3.0	2.0
22 ≤ PCMAX,c < 23	5.0	2.0
21 ≤ PCMAX,c < 22	5.0	3.0
20 ≤ PCMAX,c < 21	6.0	4.0
16 ≤ PCMAX,c < 20	5.0
11 ≤ PCMAX,c < 16	6.0
-40 ≤ PCMAX,c < 11	7.0

If the UE transmits on one antenna connector at a time, the requirements in Table 6.2.5-1 apply to the active antenna connector.