6.2A Transmitter power for CA

38.101-13GPPNRPart 1: Range 1 StandaloneRelease 17TSUser Equipment (UE) radio transmission and reception

6.2A.1 UE maximum output power for CA

6.2A.1.1 UE maximum output power for Intra-band contiguous CA

For uplink intra-band contiguous carrier aggregation, the maximum output power is specified in Table 6.2A.1.1-1. For downlink intra-band contiguous carrier aggregation with a single uplink component carrier configured in the NR band, the maximum output power is specified in Table 6.2.1-1 for power class 3 and other power classes if indicated in clause 5.5A.1.

Table 6.2A.1.1-1: UE Power Class for intra-band contiguous CA

NR CA Configuration

Class 1 (dBm)

Tolerance (dB)

Class 2 (dBm)

Tolerance (dB)

Class 3 (dBm)

Tolerance (dB)

Class 4 (dBm)

Tolerance (dB)

CA_n7B

23

+2/-2

CA_n40B

23

+2/-2

CA_n41C

26

+2/-3

23

+2/-21

CA_n48B

23

+2/-3

CA_n77C

26

+2/-3

23

+2/-3

CA_n78C

26

+2/-3

23

+2/-3

CA_n79C

23

+2/-3

NOTE 1: An uplink CA configuration in which the band has NOTE 3 in Table 6.2.1-1 is allowed to reduce the lower tolerance limit by 1.5 dB when the transmission bandwidths of the band are confined within FUL_low and FUL_low + 4 MHz or FUL_high – 4 MHz and FUL_high.

NOTE 2: PPowerClass is the maximum UE power specified without taking into account the tolerance.

NOTE 3: For intra-band contiguous carrier aggregation the maximum power requirement shall apply to the total transmitted power over all component carriers (per UE).

6.2A.1.2 UE maximum output power for Intra-band non-contiguous CA

For intra-band non-contiguous carrier aggregation with one uplink carrier on the PCC, the requirements in clause 6.2.1 apply for power class 3 and other power classes if indicated in clause 5.5A.2. For intra-band non-contiguous carrier aggregation with two uplink carriers the maximum output power is specified in Table 6.2A.1.2-1.

Table 6.2A.1.2-1: UE Power Class for intraband non-contiguous CA

NR CA Configuration

Class 1 (dBm)

Tolerance (dB)

Class 2 (dBm)

Tolerance (dB)

Class 3 (dBm)

Tolerance (dB)

Class 4 (dBm)

Tolerance (dB)

CA_n41(2A)

26

+2/-3

23

+2/-3

CA_n77(2A)

23

+2/-3

CA_n78(2A)

26

+2/-3

23

+2/-3

NOTE 1: An uplink CA configuration in which the band has NOTE 3 in Table 6.2.1-1 is allowed to reduce the lower tolerance limit by 1.5 dB when the transmission bandwidths of the band are confined within FUL_low and FUL_low + 4 MHz or FUL_high – 4 MHz and FUL_high.

NOTE 2: PPowerClass is the maximum UE power specified without taking into account the tolerance.

NOTE 3: For intra-band non-contiguous carrier aggregation the maximum power requirement shall apply to the total transmitted power over all component carriers (per UE).

6.2A.1.3 UE maximum output power for Inter-band CA

For inter-band downlink carrier aggregation with one uplink carrier assigned to one NR band, the transmitter power requirements in Table 6.2.1-1 apply for power class 3 and other power classes if indicated in clause 5.5A.3.

For inter-band carrier aggregation with two uplink contiguous carrier assigned to one NR band, the transmitter power requirements specified in subclause 6.2A.1.1 apply.

For inter-band carrier aggregation with two uplink non-contiguous carrier assigned to one NR band, the transmitter power requirements specified in subclause 6.2A.1.2 apply. For inter-band uplink carrier aggregation with uplink assigned to two NR bands, UE maximum output power shall be measured over all component carriers from different bands. If each band has separate antenna connectors, maximum output power is defined as the sum of maximum output power from each UE antenna connector. The period of measurement shall be at least one sub frame (1 ms). The maximum output power is specified in Table 6.2A.1.3-1.

Table 6.2A.1.3-1 UE Power Class for uplink inter-band CA (two bands)

Uplink CA Configuration

Class 1 (dBm)

Tolerance (dB)

Class 2 (dBm)

Tolerance

(dB)

Class 3 (dBm)

Tolerance (dB)

Class 4 (dBm)

Tolerance (dB)

CA_n1A-n3A

23

+2/-3

CA_n1A-n5A

23

+2/-3

CA_n1A-n7A

23

+2/-3

CA_n1A-n8A

23

+2/-3

CA_n1A-n18A

23

+2/-3

CA_n1A-n20A

23

+2/-3

CA_n1A-n28A

23

+2/-3

CA_n1A-n40A

23

+2/-3

CA_n1A-n41A

23

+2/-3

CA_n1A-n74A

23

+2/-3

CA_n1A-n77A

23

+2/-3

CA_n1A-n78A

266,7

+2/-3

23

+2/-3

CA_n1A-n79A

23

+2/-3

CA_n2A-n5A

23

+2/-3

CA_n2A-n7A

23

+2/-3

CA_n2A-n12A

23

+2/-3

CA_n2A-n14A

23

+2/-3

CA_n2A-n30A

23

+2/-3

CA_n2A-n48A

23

+2/-3

CA_n2A-n66A

23

+2/-3

CA_n2A-n77A

266,7

+2/-3

23

+2/-3

CA_n2A-n78A

23

+2/-3

CA_n3A-n5A

23

+2/-3

CA_n3A-n7A

23

+2/-3

CA_n3A-n8A

23

+2/-3

CA_n3A-n18A

23

+2/-3

CA_n3A-n20A

23

+2/-3

CA_n3A-n28A

23

+2/-3

CA_n3A-n34A

23

+2/-3

CA_n3-n38A

23

+2/-3

CA_n3A-n40A

23

+2/-3

CA_n3A-n41A

266,7

+2/-3

23

+2/-3

CA_n3A-n74A

23

+2/-3

CA_n3A-n77A

23

+2/-3

CA_n3A-n78A

266,7

+2/-3

23

+2/-3

CA_n3A-n79A

23

+2/-3

CA_n5A-n7A

23

+2/-3

CA_n5A-n12A

23

+2/-3

CA_n5A-n14A

23

+2/-3

CA_n5A-n25A

23

+2/-3

CA_n5A-n30A

23

+2/-3

CA_n5A-n40A

23

+2/-3

CA_n5A-n48A

23

+2/-3

CA_n5A-n66A

23

+2/-3

CA_n5A-n77A

266,7

+2/-3

23

+2/-3

CA_n5A-n78A

266,7

+2/-3

23

+2/-3

CA_n5A-n79A

23

+2/-3

CA_n7A-n25A

23

+2/-3

CA_n7A-n28A

23

+2/-3

CA_n7A-n40A

23

+2/-3

CA_n7A-n46A

23

+2/-3

CA_n7A-n66A

23

+2/-3

CA_n7A-n77A

23

+2/-3

CA_n7A-n78A

266,7

+2/-3

23

+2/-3

CA_n8A-n34A

23

+2/-3

CA_n8A-n39A

23

+2/-3

CA_n8A-n40A

23

+2/-3

CA_n8A-n41A

23

+2/-3

CA_n8A-n77A

23

+2/-3

CA_n8A-n78A

23

+2/-3

CA_n8A-n79A

23

+2/-3

CA_n12A-n30A

23

+2/-3

CA_n12A-n66A

23

+2/-3

CA_n12A-n77A

266,7

+2/-3

23

+2/-3

CA_n13A-n25A

23

+2/-3

CA_n13A-n66A

23

+2/-3

CA_n13A-n77A

266

+2/-3

23

+2/-3

CA_n14A-n30A

23

+2/-3

CA_n14A-n66A

23

+2/-3

CA_n14A-n77A

266,7

+2/-3

23

+2/-3

CA_n18A-n28A

23

+2/-3

CA_n18A-n41A

23

+2/-3

CA_n18A-n74A

23

+2/-3

CA_n18A-n77A

23

+2/-3

CA_n18A-n78A

23

+2/-3

CA_n20A-n28A

23

+2/-3

CA_n20A-n78A

23

+2/-3

CA_n24A-n41A

23

+2/-3

CA_n24A-n48A

23

+2/-3

CA_n24A-n77A

23

+2/-3

CA_n25A-n38A

23

+2/-3

CA_n25A-n41A

266,7

+2/-32

23

+2/-3

CA_25A-n48A

23

+2/-3

CA_n25A-n66A

23

+2/-3

CA_n25A-n77A

266,7

+2/-3

23

+2/-3

CA_n25A-n78A

23

+2/-3

CA_n26A-n66A

23

+2/-3

CA_n26A-n70A

23

+2/-3

CA_n28A-n34A

23

+2/-3

CA_n28A-n39A

23

+2/-3

CA_n28A-n40A

23

+2/-3

CA_n28A-n41A

266,7

+2/-3

23

+2/-3

CA_n28A-n46A

23

+2/-3

CA_n28A-n50A

23

+2/-3

CA_n28A-n74A

23

+2/-3

CA_n28A-n77A

23

+2/-3

CA_n28A-n78A

266,7

+2/-3

23

+2/-3

CA_n28A-n79A

266,7

+2/-3

23

+2/-3

CA_n34A-n79A

23

+2/-3

CA_n30A-n66A

23

+2/-3

CA_n30A-n77A

266,7

+2/-3

23

+2/-3

CA_n34A-n40A

23

+2/-3

CA_n34A-n41A

23

+2/-3

CA_n38A-n66A

23

+2/-3

CA_n38A-n78A

23

+2/-3

CA_n39A-n40A

23

+2/-3

CA_n39A-n41A

23

+2/-3

CA_n39A-n79A

23

+2/-3

CA_n40A-n41A

266,7

+2/-3

23

+2/-3

CA_n40A-n77A

23

+2/-3

CA_n40A-n78A

23

+2/-3

CA_n40A-n79A

23

+2/-3

CA_n41A-n48A

23

+2/-3

CA_n41A-n50A

23

+2/-3

CA_n41A-n66A

266,7

+2/-3

23

+2/-3

CA_n41A-n70A

23

+2/-3

CA_n41A-n71A

266,7

+2/-3

23

+2/-3

CA_n41A-n74A

23

+2/-3

CA_n41A-n77A

266,7

+2/-3

23

+2/-3

CA_n41A-n78A

23

+2/-3

CA_n41A-n79A

266,7

+2/-3

23

+2/-3

CA_n46A-n48A

23

+2/-3

CA_n46A-n48B

23

+2/-3

CA_n46A-n78A

23

+2/-3

CA_n48A-n66A

23

+2/-3

CA_n48A-n70A

23

+2/-3

CA_n48A-n71A

23

+2/-3

CA_n48A-n96A

23

+2/-3

CA_n48B-n96A

23

+2/-3

CA_n48A-n96B

23

+2/-3

CA_n50A-n78A

23

+2/-3

CA_n66A-n71A

23

+2/-3

CA_n66A-n77A

266,7

+2/-3

23

+2/-3

CA_n66A-n78A

23

+2/-3

CA_n70A-n71A

23

+2/-3

CA_n70A-n78A

23

+2/-3

CA_n71A-n77A

266,7

+2/-3

23

+2/-3

CA_n71A-n78A

23

+2/-3

CA_n74A-n77A

23

+2/-3

CA_n74A-n78A

23

+2/-3

CA_n77A-n79A

23

+2/-3

CA_n78A-n79A

23

+2/-3

CA_n78A-n92A

23

+2/-3

NOTE 1: Void

NOTE 2: An uplink CA configuration in which at least one of the bands has NOTE 3 in Table 6.2.1-1 is allowed to reduce the lower tolerance limit by 1.5 dB when the transmission bandwidths of at least one of the bands is confined within FUL_low and FUL_low + 4 MHz or FUL_high – 4 MHz and FUL_high.

NOTE 3: PPowerClass is the maximum UE power specified without taking into account the tolerance

NOTE 4: For inter-band carrier aggregation the maximum power requirement should apply to the total transmitted power over all component carriers (per UE).

NOTE 5: Power class 3 is the default power class unless otherwise stated.

NOTE 6: The UE supports PC3 within NR FDD band, and supports either PC3 or PC2 within NR TDD band.

NOTE 7: The UE that supports PC3 within an NR TDD or FDD band and supports PC2 within a second NR TDD band may signal a [HigherPowerLimitCADC] capability whereby the maximum output power indicated in the table may be exceeded in accordance with sub-clause 6.2A.4.1.3. The power classes referenced are according to the reported [powerClassPerBand] if indicated or ue-PowerClass otherwise.

If a UE supports a different power class than the default UE power class for the band combination listed in Table 6.2A.1.3-1 and the supported power class enables the higher maximum output power than that of the default power class:

– if the field of UE capability maxUplinkDutyCycle-interBandCA-PC2 is not absent and the average percentage of uplink symbols transmitted in a certain evaluation period is larger than maxUplinkDutyCycle-interBandCA-PC2 as defined in TS 38.331 (The exact evaluation period is no less than one radio frame); or

– if the IE P-Max as defined in TS 38.331 [7] is provided and set to the maximum output power of the default power class or lower;

– shall apply all requirements for the default power class to the supported power class and set the configured transmitted power as specified in clause 6.2A.4;

– else;

– shall apply all requirements for the supported power class and set the configured transmitted power as specified in clause 6.2A.4 (regardless of the average percentage of uplink symbols if the field of UE capability maxUplinkDutyCycle-interBandCA-PC2 is absent).

The average percentage of uplink symbols is defined as 50% × ( DutyNR, x /maxDutyNR,x + DutyNR, y /maxDutyNR,y, ). DutyNR, x, DutyNR, y represent the actual percentage of uplink symbols transmitted in the same evaluation period (The exact evaluation period is no less than one radio frame) for NR Band x, NR Band y respectively; maxDutyNR,x, maxDutyNR,y represent the field of UE capability maxUplinkDutyCycle-PC2-FR1 per band as defined in TS 38.331. For NR Band x or NR Band y,

– if power class of one or both of the bands within the band combination is power class 2 and the corresponding UE capability maxUplinkDutyCycle-PC2-FR1 is absent;

– the corresponding maxDutyNR,x or maxDutyNR,y is equal to 50%;

– else if the band is configured with power class 3;

– the corresponding maxDutyNR,x or maxDutyNR,y is equal to 100%.

Table 6.2A.1.3-2 Void

6.2A.1.4 Void

6.2A.1.5 Void

6.2A.2 UE maximum output power reduction for CA

6.2A.2.1 UE maximum output power reduction for Intra-band contiguous CA

For intra-band contiguous carrier aggregation the allowed Maximum Power Reduction (MPR) for the maximum output power in 6.2A.1.1-1 with contiguous RB allocation is specified in Table 6.2A.2.1-1 for UE power class 3 CA bandwidth classes B and C. The MPR with contiguous RB allocation is specified in Table 6.2A.2.1-1a for power class 2 CA bandwidth classes B and C when the signalling is absent for dualPA-Architecture IE, and for power class 2 CA bandwidth classe C when the signalling is indicated for dualPA-Architecture IE. The MPR with contiguous RB allocation is specified in Table 6.2A.2.1-1b for power class 2 CA bandwidth classes B and C with TxD supported.

In case the modulation format or waveform is different on different component carriers then the MPR is determined by the rules applied to higher order of those modulations, or CP-OFDM waveform.

Unless otherwise specified, pi/2 BPSK in following MPR tables refers to both variants of pi/2 BPSK referenced in 6.2.2 tables 6.2.2-1.

Table 6.2A.2.1-1: Contiguous RB allocation for Power Class 3

Modulation

MPR for bandwidth class B(dB)

MPR for bandwidth class C(dB)

inner

outer

inner

outer

DFT-s-OFDM

Pi/2 BPSK

1.0

3.5

2.5

7

QPSK

1.0

3.5

2.5

7

16QAM

1.5

3.5

2.5

7

64QAM

3.0

4.0

5

7

256QAM

5.5

6.0

7

7.5

CP-OFDM

QPSK

2.0

4.0

3.5

8

16QAM

2.5

4.0

3.5

8

64QAM

3.5

4.0

5

8

256QAM

6.5

6.5

7

8

Table 6.2A.2.1-1a: Contiguous RB allocation for Power Class 2

Modulation

MPR for bandwidth class B(dB)

MPR for bandwidth class C(dB)

inner

Outer1

inner

outer

DFT-s-OFDM

Pi/2 BPSK

2.0

4.01

2.5

7

QPSK

2.0

4.01

2.5

7

16QAM

2.5

4.01

2.5

7

64QAM

3.0

4.51

5

7

256QAM

5.5

6.0

7

7.5

CP-OFDM

QPSK

2.5

5.01

3.5

8

16QAM

3.0

5.01

3.5

8

64QAM

3.5

5.01

5

8

256QAM

6.5

6.5

7

8

NOTE 1: When 1 RB or 2 RB are allocated at the lower edge of lowest CC or upper edge of upper CC, MPR for outer is 5.5 dB.

Table 6.2A.2.1-1b: Contiguous RB allocation for Power Class 2 with dual Tx2

Modulation

MPR for bandwidth class B(dB)

MPR for bandwidth class C(dB)

inner

Outer1

inner

outer

DFT-s-OFDM

Pi/2 BPSK

3.0

5.01

3.5

8

QPSK

3.0

5.01

3.5

8

16QAM

3.5

5.01

3.5

8

64QAM

4.0

5.51

6

8

256QAM

6.5

7.0

8

8.5

CP-OFDM

QPSK

3.0

5.51

4.0

8.5

16QAM

3.5

5.51

4.0

8.5

64QAM

4.0

5.51

5.5

8.5

256QAM

7.0

7.0

7.5

8.5

NOTE 1: When 1 RB or 2 RB are allocated at the lower edge of lowest CC or upper edge of upper CC, MPR for outer is 5.5 dB.

NOTE 2: UE indicating TxD supported

For CA bandwidth class B and bandwidth class C with contiguous RB allocation, the following parameters are defined to specify valid RB allocation ranges for Inner and Outer RB allocations:

An RB allocation is contiguous if LCRB1 = 0 or LCRB2 = 0 or (LCRB1 ≠ 0 and LCRB2 ≠ 0 and RBStart1 + LCRB1 = NRB1 and RBStart2 = 0), where RBStart1, LCRB1, and NRB1 are for CC1, RBStart2, LCRB2, and NRB2 are for CC2, CC1 is the component carrier with lower frequency.

In contiguous CA, a contiguous allocation is an inner allocation if

RBStart,Low ≤ RBStart_CA ≤ RBStart,High, and NRB_alloc ≤ ceil(NRB,agg /2),

where

RBStart,Low = max(1, floor(NRB_alloc /2))

RBStart,High = NRB,agg – RBStart,Low – NRB,alloc,

with

NRB_alloc= (NRB1 – RBStart1)∙ 2^µ1 + (RBStart2 + LCRB2 ) ∙ 2^µ2,

NRB,agg=NRB1∙2^µ1+ NRB2∙2^µ2.

If LCRB1 =0, RBStart_CA = NRB1∙2^µ1+ RBStart2∙2^µ2,

if LCRB1 > 0, RBStart_CA = RBStart1∙2^µ1.

A contiguous allocation that is not an Inner contiguous allocation is an Outer contiguous allocation.

For intra-band contiguous carrier aggregation the allowed Maximum Power Reduction (MPR) for the maximum output power in Table Table 6.2A.1.1-1 with non-contiguous RB allocation is specified in Table 6.2A.2.1-2 for UE power class 3 CA bandwidth classes B and C. The MPR with non-contiguous RB allocation is specified in Table 6.2A.2.1-3 for power class 2 CA bandwidth classes B and C when the signalling is absent for dualPA-Architecture IE, and for power class 2 CA bandwidth classe C when the signalling is indicated for dualPA-Architecture IE. The MPR with non-contiguous RB allocation is specified in Table 6.2A.2.1-4 for power class 2 CA bandwidth classes B and C with TxD supported.

Table 6.2A.2.1-2: non-contiguous RB allocation for Power Class 3

Modulation

MPR for bandwidth class B(dB)

MPR for bandwidth class C(dB)

inner

Outer11

Outer22

inner

Outer11

Outer22

DFT-s-OFDM

Pi/2 BPSK

2

5.5

11.5

2.5

6

13

QPSK

2

5.5

2.5

6

16QAM

2.5

5.5

3

6

64QAM

4.5

6

5

6

256QAM

6

6.5

6.5

6.5

CP-OFDM

QPSK

2.5

6.5

12

3.5

7

14

16QAM

3

7

3.5

7

64QAM

5

7

5

7

256QAM

7.5

7.5

7.5

7.5

NOTE 1: Outer 1 MPR for Pi/2 BPSK and QPSK is reduced by 2dB for aggregated allocation bandwidth > 10MHz

NOTE 2: Outer 2 MPR is reduced by 4.5dB for aggregated allocation bandwidth > 10MHz

Table 6.2A.2.1-3: non-contiguous RB allocation for Power Class 2

Modulation

MPR for bandwidth class B(dB)

MPR for bandwidth class C(dB)

inner

Outer12

Outer23

Inner

Outer12

Outer23

DFT-s-OFDM

Pi/2 BPSK

31

6.5

13

31

7.5

13.5

QPSK

31

6.5

31

7.5

16QAM

31

6.5

31

7.5

64QAM

5

6.5

5

7.5

256QAM

6.5

7

6.5

7.5

CP-OFDM

QPSK

3.51

7

14

3.51

8

14.5

16QAM

3.51

7

3.51

8

64QAM

5

7

5

8

256QAM

7.5

7.5

7.5

8

NOTE 1: the allowed MPR is [4]dB for aggregated allocation bandwidth < [2MHz].

NOTE 2: Outer 1 MPR for Pi/2 BPSK and QPSK is reduced by 2dB for aggregated allocation bandwidth > 10MHz

NOTE 3: Outer 2 MPR is reduced by 4.5dB for aggregated allocation bandwidth > 10MHz

Table 6.2A.2.1-4: non-contiguous RB allocation for Power Class 2 with dual Tx4

Modulation

MPR for bandwidth class B(dB)

MPR for bandwidth class C(dB)

inner

Outer12

Outer23

Inner

Outer12

Outer23

DFT-s-OFDM

Pi/2 BPSK

41

7.5

14

41

8.5

14.5

QPSK

41

7.5

41

8.5

16QAM

41

7.5

41

8.5

64QAM

6

7.5

6

8.5

256QAM

7.5

8

7.5

8.5

CP-OFDM

QPSK

4.51

8

15

4.51

9

15.5

16QAM

4.51

8

4.51

9

64QAM

6

8

6

9

256QAM

8.5

8.5

8.5

9

NOTE 1: the allowed MPR is [4]dB for aggregated allocation bandwidth < [2MHz].

NOTE 2: Outer 1 MPR for Pi/2 BPSK and QPSK is reduced by 2dB for aggregated allocation bandwidth > 10MHz

NOTE 3: Outer 2 MPR is reduced by 4.5dB for aggregated allocation bandwidth > 10MHz

NOTE 4: UE indicating TxD supported

For CA bandwidth classes B and C with non-contiguous RB allocation, the following parameters are defined to specify valid RB allocation ranges for Inner, Outer1 and Outer2 RB allocations:

Non-Contiguous RB allocation is defined as RBStart1 + LCRB1 < NRB1, or RBStart2 > 0, when both uplink CCs are activated and allocated with RB(s), where RBStart1, LCRB1, and NRB1 are for CC1, RBStart2, LCRB2, and NRB2 are for CC2, CC1 is the component carrier with lower frequency.

In contiguous CA, a non-contiguous RB allocation is a non-contiguous Inner RB allocation if the following conditions are met:

RBStart,Low ≤ RBStart_CA ≤ RBStart,High and NRB_alloc ≤ ceil((BWChannel_CA / 3 – BWgap ) / 0.18MHz),

where

NRB_alloc = (NRB1 – RBStart1)∙ 2^µ1 + (RBStart2 + LCRB2 ) ∙ 2^µ2, RBStart_CA = RBStart1∙2^μ1

RBStart,Low = max(1, floor(NRB_alloc + (BWgap – BWGB,low)/0.18MHz))

RBStart,High = floor((BWChannel_CA – 2 ∙ BWgap – BWGB,low)/0.18MHz – 2 ∙ NRB_alloc)

BWGB,low =Foffset,low – (NRB1∙12+1)∙SCS1/2

BWgap is the bandwidth of the gap between NRB1 and NRB2 possible allocations of CC1 and CC2 respectively.

In contiguous CA, a non-contiguous RB allocation is a non-contiguous outer 1 RB allocation if the following conditions are met:

RBStart,Low ≤ RBStart_CA ≤ RBStart,High and NRB_alloc ≤ ceil((3 BWChannel_CA / 5 – BWgap) / 0.18MHz)

where

RBStart,Low = max(1, 2 ∙ NRB_alloc – floor( (BWChannel_CA – 2 ∙ BWgap + BWGB,low)/0.18MHz)),

RBStart,High = floor((2 ∙ BWChannel_CA – 3 ∙ BWgap – BWGB,low) / 0.18MHz – 3 ∙ NRB_alloc)

NRB_alloc , RBStart_CA , BWgap and BWGB,low are as defined for the Inner region.

In contiguous CA, a non-contiguous allocation is an Outer 2 allocation if it is neither a non-contiguous Inner allocation nor an Outer 1 allocation.

6.2A.2.2 UE maximum output power reduction for Intra-band non-contiguous CA

6.2A.2.2.0 General

For intra-band non-contiguous CA, the allowed Maximum Power Reduction (MPR) for the maximum output power is specified into 2 types: MPR to meet -30dBm/MHz and -13dBm/MHz. The UE determins the MPR type as follows:

For UE indicating dualPA-Architecture supported

If OR (LCRB1 = 0, LCRB2 = 0)

MPR defined in Table 6.2.2-1 and Table 6.2.2-2 for PC3 and PC2 UE respectively

Else If AND( FIM3,low_block,low > SEM-13,low , FIM3,high_block,high < SEM-13,high )

MPR defined in Clause 6.2A.2.2.2.1 and Clause 6.2A.2.2.2.2 for PC3 and PC2 UE respectively.

Else

MPR defined in Clause 6.2A.2.2.1.1 and Clause 6.2A.2.2.1.2 for PC3 and PC2 UE respectively.

For UE without indicating dualPA-Architecture supported

If OR( LCRB1 = 0, LCRB2 = 0 )

For PC3 UE, MPR defined in Table 6.2.2-1, except for B < 9 MHz where 5.5 dB MPR is used;

For PC2 UE without indicating TxD, MPR defined in Table 6.2.2-2 is used, except for B < 11.52 MHz where 6.5 dB MPR is used;

For PC2 UE indicating TxD, MPR defined in Table 6.2D.2-1 is used, except for B < 11.52 MHz where the maximum value between 6.5 dB and MPR defined in Table 6.2D.2-1 is used.

Else If AND( FIM3,low_block,low > SEM-13,low , FIM3,high_block,high < SEM-13,high )

MPR defined in Clause 6.2A.2.2.2.3 and Clause 6.2A.2.2.2.4 for PC3 and PC2 UE respectively.

Else

MPR defined in Clause 6.2A.2.2.1.3 and Clause 6.2A.2.2.1.4 for PC3 and PC2 UE respectively.

where

– LCRB1 is for CC1 which is the component carrier with lower frequency

– LCRB2 is for CC2 which is the component carrier with higher frequency

– B = (LCRB1* 12* SCS1 + LCRB2 * 12 * SCS2)/1,000,000

– FIM3,high_block,high = (2 * Fhigh_alloc,high_edge ) – Flow_alloc,low_edge

– FIM3,low_block,low = (2 * Flow_alloc,low_edge) – Fhigh_alloc,high_edge

– Flow_alloc,low_edge is the lowermost frequency of the lower transmission bandwidth allocation.

– Flow_alloc,high_edge is the uppermost frequency of the lower transmission bandwidth allocation.

– Fhigh_alloc,low_edge is the lowermost frequency of the upper transmission bandwidth allocation.

– Fhigh_alloc,high_edge is the uppermost frequency of the upper transmission bandwidth allocation.

– SEM-13,low = Threshold frequency where lower spectral emission mask below the lower channel drops from -13 dBm / MHz to -25 dBm / MHz, as specified in Clause 6.5A.2.2.2.

– SEM-13,high = Threshold frequency where upper spectral emission mask above the upper channel drops from -13 dBm / MHz to -25 dBm / MHz, as specified in Clause 6.5A.2.2.2.

MPRs in section 6.2A.2.2.1.3, 6.2A.2.2.1.4, 6.2A.2.2.2.3 and 6.2A.2.2.2.4 are applicable only when the Gap between the component carriers is ≤ the overall channel bandwidth summed across all the component carriers and when UE declares intraBandFreqSeparationUL-v1620 value ≤ 200 MHz.

The definition of the gap is between the component carriers in a spectrum that is not part of any configured component carrier that is located in between the lowest edge of the component carrier with higher center frequency and the highest edge of the component carrier with center frequency that is located lower in frequency.

6.2A.2.2.1 MPR to meet -30dBm/MHz

6.2A.2.2.1.1 PC3 with indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 3 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MAWhere MA is defined as follows

MA = 15; 0 ≤ B < 1.08

14.5; 1.08 ≤ B < 2.16

13.5; 2.16 ≤ B < 3.24

12.5; 3.24 ≤ B < 5.04

11.5; 5.04≤ B < 10.08

10.5; 10.08 ≤ B < 16.38

10; 16.38 ≤ B < 21.78

9; 21.78 ≤ B

6.2A.2.2.1.2 PC2 with indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 2 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MAWhere MA is defined as follows

MA = 15.5; 0 ≤ B < 1.44

15.0; 1.44 ≤ B < 2.88

14.0; 2.88 ≤ B < 5.76

12.0; 5.76 ≤ B < 10.8

10.5; 10.8 ≤ B < 23.04

9.0; 23.04 ≤ B

6.2A.2.2.1.3 PC3 without indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 3 for UEs without indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MAWhere MA is defined as follows

MA = 17.5; 0 ≤ B < 1.08

17.0; 1.08 ≤ B < 2.16

16.5; 2.16 ≤ B < 3.24

16; 3.24 ≤ B < 5.04

15; 5.04≤ B < 10.08

14.5; 10.08 ≤ B < 36

10; 36 ≤ B < 56.88

9; 56.88 ≤ B

6.2A.2.2.1.4 PC2 without indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 2 for UEs without indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MAWhere MA is defined as follows

MA = 19.5; 0 ≤ B < 1.08

19; 1.08 ≤ B < 2.16

18; 2.16 ≤ B < 5.04

16.5; 5.04≤ B < 10.08

16; 10.08 ≤ B < 36

12; 36 ≤ B < 56.88

10.5; 56.88 ≤ B

6.2A.2.2.2 MPR to meet -13dBm/MHz

6.2A.2.2.2.1 PC3 with indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 3 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MA

Where MA is defined as follows

MA = 9 ; 0 ≤ B < 0.54

8 ; 0.54 ≤ B < 1.08

7 ; 1.08 ≤ B < 2.16

6.5 ; 2.16 ≤ B < 3.24

5.5 ; 3.24 ≤ B < 5.4

4 ; 5.4 ≤ B

6.2A.2.2.2.2 PC2 with indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 2 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MA

Where MA is defined as follows

MA = 9 ; 0 ≤ B < 0.54

8 ; 0.54 ≤ B < 1.08

7 ; 1.08 ≤ B < 2.16

6.5 ; 2.16 ≤ B < 3.24

6 ; 3.24 ≤ B < 5.4

5.5 ; 5.4 ≤ B ≤ 10.8

4 ; 10.8 < B

6.2A.2.2.2.3 PC3 without indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 3 for UEs without indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MAWhere MA is defined as follows

MA = 11; 0 ≤ B < 1.08

10.5; 1.08 ≤ B < 2.16

10; 2.16 ≤ B < 3.24

9.5; 3.24≤ B < 5.04

8.5; 5.04 ≤ B < 10.08

7.5; 10.08 ≤ B < 36

7; 36 ≤ B

6.2A.2.2.2.4 PC2 without indicating dualPA-Architecture supported

MPR in this clause is for intra-band non-contiguous CA power class 2 for UEs without indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

MPR=MAWhere MA is defined as follows

MA = 14; 0 ≤ B < 1.08

12; 1.08 ≤ B < 2.16

11.5; 2.16 ≤ B < 3.24

11; 3.24≤ B < 5.04

9.5; 5.04 ≤ B < 10.08

8.5; 10.08 ≤ B < 36

6.5; 36 ≤ B

6.2A.2.3 UE maximum output power reduction for Inter-band CA

For inter-band carrier aggregation with one uplink carrier assigned to one NR band, the requirements in subclause 6.2.2 apply.

For inter-band carrier aggregation with two uplink contiguous carrier assigned to one NR band, the maximum output power reduction requirements for intra-band contiguous carrier aggregation in subclause 6.2A.2.1 apply for that band.

For inter-band carrier aggregation with two uplink non-contiguous carrier assigned to one NR band, the maximum output power reduction requirements for intra-band non-contiguous carrier aggregation in subclause 6.2A.2.2 apply for that band.

For inter-band carrier aggregation with uplink assigned to two NR bands, the requirements in clause 6.2.2 apply for each uplink component carrier.

For combinations of intra-band and inter-band carrier aggregation with three uplink component carriers (up to two contiguously aggregated carriers per operating band), the maximum output power reduction requirements specified in subclause 6.2.2 apply for the NR band supporting one component carrier, and for the NR band supporting two contiguous component carriers the requirements specified in subclause 6.2A.2.1 apply.

6.2A.2.4 Void

6.2A.3 UE additional maximum output power reduction for CA

6.2A.3.1.1 UE additional maximum output power reduction for Intra-band contiguous CA

Additional emission requirements can be signalled by the network. Each additional emission requirement is associated with a unique network signalling (NS) value indicated in RRC signalling by an NR frequency band number of the applicable operating band and an associated value in the field additionalSpectrumEmission. Throughout this specification, the notion of indication or signalling of an NS value refers to the corresponding indication of an NR frequency band number of the applicable operating band, the IE field freqBandIndicatorNR and an associated value of additionalSpectrumEmission in the relevant RRC information elements [7]. Relation between NR CA band and NR frequency band is specified in Table 5.2A.1-1.

To meet the additional requirements, additional maximum power reduction (A-MPR) is allowed for the maximum output power as specified in Table 6.2A.1.5-1. Unless stated otherwise, the total reduction to UE maximum output power is max(MPR, A-MPR) where MPR is defined in clause 6.2A.2.4. In absense of modulation and waveform types the A-MPR applies to all modulation and waveform types.

Table 6.2A.3.1.1-1 specifies the additional requirements with their associated network signalling values and the allowed A-MPR and applicable CA band(s) for each CA_NS value. The mapping of NR CA band numbers and values of the additionalSpectrumEmission to network signalling labels is specified in Table 6.2A.3.1.1-2.

Table 6.2A.3.1.1-1: Additional maximum power reduction (A-MPR)

Network signalling label

Requirements (clause)

NR CA Band

Aggregated channel bandwidth (MHz)

Resources blocks (NRB)

A-MPR (dB)

CA_NS_01

Table 5.2A.1-1

All applicaple NR CA bands

All applicaple NR CA configurations

N/A

CA_NS_04

6.5A.2.3.1.1

6.5A.3.3.1.1

CA_n41

Table 5.5A.1-1

6.2A.3.1.1.1

6.2A.3.1.1.1

CA_NS_27

6.5A.2.3.1.2

6.5A.3.3.1.2

CA_n48

Table 5.5A.1-1

6.2A.3.1.1.2

6.2A.3.1.1.2

CA_NS_46

6.5A.3.3.1.3

CA_n7

Table 5.5A.1-1

6.2A.3.1.1.3

6.2A.3.1.1.3

[The CA_NS_01 label with the field additionalPmax [7] absent is default for all NR bands.]

For UEs configured with intra-band contiguous CA in n77 and if NS_01 is indicated for an uplink component carrier in the range 3450-3650 MHz and NS_01 or NS_57 for another uplink component carrier in the range 3650-3980 MHz, the allowed additional spurious emission and maximum output power reduction requirements are according to CA_NS_01.

Table 6.2A.3.1.1-2: Mapping of network signaling label

NR CA band

Value of additionalSpectrumEmission

0

1

2

3

4

5

6

7

CA_n41

CA_NS_01

CA_NS_04

CA_n48

CA_NS_01

CA_NS_27

CA_n7

CA_NS_01

CA_NS_46

NOTE: additionalSpectrumEmission corresponds to an information element of the same name defined in clause 6.3.2 of TS 38.331 [7].

6.2A.3.1.1.1 A-MPR for CA_NS_04

6.2A.3.1.1.1.1 Contiguous allocations

For all waveform type, modulations and scs when Fedge, low – BWChannel_CA ≥ 2490.5 MHz, A-MPR = MPR

For all modulations and SCS when Fedge, low – BWChannel_CA < 2490.5 MHz

if the RB allocation is an inner allocation as defined in clause 6.2A.2.1, then A-MPR = MPR

Except for RBstart ≤ 0.33*BWchannel_CA/0.18MHz, AMPR= max (MPR, AMPRcc).

if the RB allocation is an outer allocation as defined in clause 6.2A.2.1,

then A-MPR = MPR+1.5dB for BW Class B A-MPR = MPR for BW class C.

Where

– MPR is the MPR as defined in Table 6.2A.2.1-1, Table 6.2A.2.1-1a and Table 6.2A.2.1-1b for PC3 and PC2 respectively and the respective CA bandwidth class

– AMPRcc is defined as the PC3_A2 or PC2_A4 AMPR in table 6.2.3.2-2 for PC3 and PC2 respectively.

6.2A.3.1.1.1.2 Non-contiguous allocations

For intra-band contiguous CA_n41B and CA_n41C and it receives IE CA_ NS_04, the UE determines the allowed Additional Maximum Power Reduction (AMPR) for the maximum output power as specified in this clause. The AMPR is specified by AMPRIM3 to meet -25dBm/MHz when IM3 falls in -25dBm/MHz region of Table 6.5A.2.3.1.1-1 or Table 6.5A.3.3.1.1-1. And uses MPR for all other cases.

The UE determines the AMPR type as follows:

For all waveform types, modulations and SCS when Fedge, low – BWChannel_CA ≥ 2490.5 MHz,

if allocation is an inner or outer 1 allocation as defined in Table 6.2A.2.1-2 then A-MPR = MPR

if allocation is an outer 2 allocation as defined in Table 6.2A.2.1-2 then A-MPR = MPR-1dB

For all waveform types, modulations and SCS when Fedge, low – BWChannel_CA < 2490.5 MHz

If AND( MIN(FIM3,low_block,high, SEM-13,low) < Ffilter,low , MAX( SEM-13,high, FIM3,high_block,low ) > Ffilter,high )

if RB allocation is an inner or outer 1 allocation as defined in Table 6.2A.2.1-2 then A-MPR = MPR

if RB allocation is an outer 2 allocation as defined in Table 6.2A.2.1-2 then A-MPR = MPR-1dB

Else

A-MPR = A-MPRIM3 defined in Clause 6.2A.3.1.1.1.3.

where

– MPR is the MPR as defined in Table 6.2A.2.1-2, Table 6.2A.2.1-3 and Table 6.2A.2.1-4 for PC3 and PC2 respectively and the respective CA bandwidth class

– FIM3,low_block,high = (2 * Flow_alloc,high_edge ) – Fhigh_alloc,low_edge

– FIM3,high_block,low = (2 * Fhigh_alloc,low_edge) – Flow_alloc,high_edge

– Flow_alloc,low_edge is the lowermost frequency of lower transmission bandwidth allocation.

– Flow_alloc,high_edge is the uppermost frequency of lower transmission bandwidth allocation.

– Fhigh_alloc,low_edge is the lowermost frequency of upper transmission bandwidth allocation.

– Fhigh_alloc,high_edge is the uppermost frequency of upper transmission bandwidth allocation.

– Ffilter,low = 2480 MHz

– Ffilter,high = 2745 MHz

– SEM-13,high = Threshold frequency where upper spectral emission mask for upper channel drops from -13 dBm / 1MHz to -25 dBm / 1MHz, as specified in Clause 6.5A.2.3.1.1

– SEM-13,low = Threshold frequency where lower spectral emission mask below the lower channel drops from -13 dBm / MHz to -25 dBm / MHz, as specified in Clause 6.5A.2.3.1.1

6.2A.3.1.1.1.3 AMPRIM3 to meet -25dBm/MHz

AMPR in this clause is for intra-band contiguous CA_n41B and CA_n41C. The allowed maximum output power reduction is defined as:

AMPRIM3=MA, Where MA is defined as follows

MA = 13; 0 ≤ B < 2.16

11.5; 2.16 ≤ B < 3.24

10.5; 3.24 ≤ B < 5.04

9.5; 5.04 ≤ B < 10.08

8; 10.08 ≤ B < 16.56

7; 16.56 ≤ B < 21.96

6; 21.96 ≤ B

Where:

B=(LCRB1* 12* SCS1 + LCRB2 * 12 * SCS2)/1,000,000

and LCRB1, SCS1 are for CC1, LCRB2, SCS2 are for CC2, CC1 is the component carrier with lower frequency.

6.2A.3.1.1.2 A-MPR for CA_NS_27

6.2A.3.1.1.2.1 Contiguous allocations

For all modulations and scs when Fedge, low – BWChannel_CA ≥ 3540 MHz AND Fedge, high + BWChannel_CA ≤ 3710 MHz

if allocation is inner 1 then A-MPR = 0 dB where inner 1 is defined as

RBStart,Low = max(1, floor(LCRB/2))

where max() indicates the largest value of all arguments and floor(x) is the greatest integer less than or equal to x.

RBStart,High = NRB_agg – RBStart,Low – LCRB

with following conditions

RBStart,Low ≤ RBStart ≤ RBStart,High, and

LCRB ≤ ceil(NRB_agg /2)

Inner 1 region exceptions thresholds are for LCRB < 8 and

RBstart ≤ 30 and RBend ≥ 164 for BWChannel_CA = 40MHz, and

when 3540 MHz + BWChannel_CA ≤ Fedge, low < 3530 MHz + 2*BWChannel_CA,

RBstart ≤ 25 for BWChannel_CA = 35MHz, and

RBstart ≤ 19 for BWChannel_CA = 30MHz, and

RBstart ≤ 14 for BWChannel_CA = 25MHz, and

RBstart ≤ 9 for BWChannel_CA = 20MHz, and

RBstart ≤ 3 for BWChannel_CA = 15MHz, and

when 3720 MHz – 2*BWChannel_CA < Fedge, high ≤ 3710 MHz – BWChannel_CA,

RBend ≥ 144 for BWChannel_CA = 35MHz, and

RBend ≥ 124 for BWChannel_CA = 30MHz, and

RBend ≥ 104 for BWChannel_CA = 25MHz, and

RBend ≥ 80 for BWChannel_CA = 20MHz, and

RBend ≥ 68 for BWChannel_CA = 15MHz,

For which AMPR = 5dB.

else A-MPR= 5 dB

For all modulations and scs when 3550 MHz ≤ Fedge, low < 3540 MHz + BWChannel_CA

if allocation is inner 3 then A-MPR = 0 dB.

Inner 3 region exceptions thresholds are

RBstart ≤ 63 for BWChannel_CA = 40MHz, and

RBstart ≤ 52 for BWChannel_CA = 35MHz, and

RBstart ≤ 42 for BWChannel_CA = 30MHz, and

For which AMPR = 7dB for BWChannel_CA ≤ 20MHz and 11.5dB for BWChannel_CA > 20MHz

where inner 3 is defined as

RBStart = NRB_agg /4

LCRB = NRB_agg/4

RBStart = NRB_agg 3/4 − LCRB

with following conditions

NRB_agg /4 < RBStart < NRB_agg 3/4 − LCRB AND LCRB < NRB_agg/4

else when BWagg ≤ 20 MHz, A-MPR = 7 dB or when BWagg > 20 MHz, A-MPR = 11.5dB.

For all modulations and scs when 3710 MHz – BWChannel_CA < Fedge, high ≤ 3700

if allocation is inner 3 then A-MPR = 0 dB.

Inner 3 region exceptions thresholds are

RBend ≥ 132 for BWChannel_CA = 40MHz, and

RBend ≥ 121 for BWChannel_CA = 35MHz, and

RBend ≥ 110 for BWChannel_CA = 30MHz, and

For which AMPR = 7dB for BWChannel_CA ≤ 20MHz and 11.5dB for BWChannel_CA > 20MHz

where inner 3 is defined as

RBStart = NRB_agg /4

LCRB = NRB_agg/4

RBStart = NRB_agg 3/4 − LCRB

with following conditions

NRB_agg /4 < RBStart < NRB_agg 3/4 − LCRB AND LCRB < NRB_agg/4

else when BWagg ≤ 20 MHz, A-MPR = 7 dB or when BWagg > 20 MHz, A-MPR = 11.5dB.

6.2A.3.1.1.2.2 Non-contiguous allocations

For all modulations and scs when Fedge, low – BWChannel_CA ≥ 3540 MHz AND Fedge, high + BWChannel_CA ≤ 3710 MHz

A-MPRCA_IM5=     

13; 0 ≤B<1.08

12; 1.08 ≤B<2.16

11; 2.16 ≤B<3.24

10.5; 3.24 ≤ B < 5.04

9.5; 5.04≤B< 10.08

8; 10.08 ≤B< 16.56

7; 16.56 ≤ B < 21.96

6.5; 21.96 ≤B

For all modulations and scs when 3550 MHz ≤ Fedge, low < 3540 MHz + BWChannel_CA or 3710 MHz – BWChannel_CA < Fedge, high ≤ 3700

when BWagg ≤ 20 MHz

A-MPRCA_IM5=     

13; 0 ≤B<1.08

12; 1.08 ≤B<2.16

11; 2.16 ≤B<3.24

10.5; 3.24 ≤ B < 5.04

9.5; 5.04 ≤B< 10.08

8; 10.08 ≤B< 16.56

7; 16.56 ≤ B < 21.96

6.5; 21.96 ≤B

or when BWagg > 20 MHz

A-MPRCA_IM3 =

20; 0 ≤B<1.08

19.5; 1.08 ≤B<2.16

19; 2.16 ≤B<3.24

18.5; 3.24 ≤ B < 5.04

18; 5.04 ≤B< 10.08

17; 10.08 ≤B< 16.56

16; 16.56 ≤ B < 21.96

13; 21.96 ≤B.

Where:

B=(LCRB1* 12* SCS1 + LCRB2 * 12 * SCS2)/1,000,000

and LCRB1, SCS1 are for CC1, LCRB2, SCS2 are for CC2, CC1 is the component carrier with lower frequency.

6.2A.3.1.1.3 A-MPR for CA_NS_46

6.2A.3.1.1.3.1 Contiguous allocations

[For all modulations and scs when BWChannel_CA > 25 MHz

IF RBend > NRB_agg 5/6 with the exception of NRB_agg 3/4 for BWChannel_CA = 50MHz OR RBend > 4/3 NRB_agg – LCRB

THEN A-MPR = 11dB

ELSE IF RBend < NRB_agg /6 AND LCRB < 5

THEN A-MPR = 5dB

ELSE IF LCRB 3/2< RBend < NRB_agg 3/4 AND LCRB < NRB_agg /4

THEN A-MPR = 0 dB,

OTHERWISE A-MPR = [7] dB.

For all modulations and scs when BWChannel_CA <= 25 MHz and 2595 MHz – 2*BWChannel_CA < Fedge,high ≤ 2570 MHz

IF RBend ≥ 4/3 NRB_agg – LCRB

THEN A-MPR = 6 dB.

OTHERWISE A-MPR = 0 dB.

For all modulations and scs when BWChannel_CA <= 25 MHz and Fedge_high <= 2595 MHz – 2*BWChannel_CA,

A-MPR = 0 dB.]

6.2A.3.1.1.3.2 Non-contiguous allocations

[For all modulations and scs when BWChannel_CA > 25 MHz and 2595 MHz – BWChannel_CA ≤ Fedge_high ≤ 2570 MHz

A-MPRCA_IM3 =

20; 0 ≤B<1.08

19.5; 1.08 ≤B<2.16

19; 2.16 ≤B<3.24

18.5; 3.24 ≤ B < 5.04

18; 5.04 ≤B< 10.08

17; 10.08 ≤B< 16.56

16; 16.56 ≤ B < 21.96

13; 21.96 ≤B

For all modulations and scs when BWChannel_CA > 25 MHz and Fedge_high < 2595 MHz – BWChannel_CA

A-MPRCA_IM5 =

13; 0 ≤B<1.08

12; 1.08 ≤B<2.16

11; 2.16 ≤B<3.24

10.5; 3.24 ≤ B < 5.04

9.5; 5.04 ≤B< 10.08

8; 10.08 ≤B< 16.56

7.5; 16.56 ≤ B < 21.96

7; 21.96 ≤B

For all modulations and scs when BWChannel_CA <= 25 MHz and 2595 MHz – 2*BWChannel_CA ≤ Fedge_high ≤ 2570 MHz

A-MPRCA_IM5 =

13; 0 ≤B<1.08

12; 1.08 ≤B<2.16

11; 2.16 ≤B<3.24

10.5; 3.24 ≤ B < 5.04

9.5; 5.04 ≤B< 10.08

8; 10.08 ≤B< 16.56

7.5; 16.56 ≤ B < 21.96

7; 21.96 ≤B

Where:

B=(LCRB1* 12* SCS1 + LCRB2 * 12 * SCS2)/1,000,000

and LCRB1, SCS1 are for CC1, LCRB2, SCS2 are for CC2, CC1 is the component carrier with lower frequency.]

6.2A.3.1.2 UE additional maximum output power reduction for Intra-band non-contiguous CA

6.2A.3.1.2.0 General

Table 6.2A.3.1.2-1 specifies the additional requirements with their associated network signalling values and the allowed A-MPR and applicable CA band(s) for each CA_NC_NS value. The mapping of NR CA band numbers and values of the additionalSpectrumEmission to network signalling labels is specified in Table 6.2A.3.1.2-2.

Table 6.2A.3.1.2-1: Additional Maximum Power Reduction (A-MPR) for intra-band non-contiguous CA

CA Network Signalling value

Requirements (clause)

Uplink CA Configuration

A-MPR for sub-blocks in order of increasing uplink carrier frequency

A-MPR [dB]

(clause)

CA_NC_NS_01

All applicaple NR CA configurations

N/A

CA_NC_NS_04

6.5A.2.3.2.1

6.5A.3.3.2.1

CA_n41(2A)

6.2A.3.1.2.1

For UEs configured with intra-band non-contiguous CA in n77 and if NS_01 is indicated for an uplink component carrier in the range 3700-3980 MHz and NS_01 or NS_55 for another uplink component carrier in the range 3450-3550 MHz, the allowed additional spurious emission and maximum output power reduction requirements are according to CA_NC_NS_01.

Table 6.2A.3.1.2-2: Mapping of network signaling label

NR CA band

Value of additionalSpectrumEmission

0

1

2

3

4

5

6

7

CA_n41

CA_NC_NS_01

CA_NC_NS_04

NOTE: additionalSpectrumEmission corresponds to an information element of the same name defined in clause 6.3.2 of TS 38.331 [7].

6.2A.3.1.2.1 AMPR for CA_NC_NS_04 (CA_n41(2A))

For intra-band non-contiguous CA_n41(2A) and it receives IE CA_NC_NS_04 for UE indicating dualPA-Architecture supported for PC3 and PC2 operation, the UE determines the allowed Additional Maximum Power Reduction (AMPR) for the maximum output power as specified in this clause. The AMPR is specified into 2 types: AMPR to meet -25dBm/MHz and -13dBm/MHz. The A-MPR defined in this clause is used instead of MPR defined in 6.2A.2.2, not additively, so CA MPR=0 when CA_NC_NS_04 is signaled.

The UE determins the AMPR type as follows:

If AND( MIN(FIM3,low_block,high, SEM-13,low) < Ffilter,low , MAX( SEM-13,high, FIM3,high_block,low ) > Ffilter,high )

A-MPRIM3 defined in Clause 6.2A.3.2.1.2

Else

A-MPRIM3 defined in Clause 6.2A.3.2.1.1

where

– LCRB1 is for CC1 which is the component carrier with lower frequency

– LCRB2 is for CC2 which is the component carrier with higher frequency

– B = (LCRB1* 12* SCS1 + LCRB2 * 12 * SCS2)/1,000,000

– FIM3,low_block,high = (2 * Flow_alloc,high_edge ) – Fhigh_alloc,low_edge

– FIM3,high_block,low = (2 * Fhigh_alloc,low_edge) – Flow_alloc,high_edge

– Flow_alloc,low_edge is the lowermost frequency of lower transmission bandwidth allocation.

– Flow_alloc,high_edge is the uppermost frequency of lower transmission bandwidth allocation.

– Fhigh_alloc,low_edge is the lowermost frequency of upper transmission bandwidth allocation.

– Fhigh_alloc,high_edge is the uppermost frequency of upper transmission bandwidth allocation.

– Ffilter,low = -2480 MHz-

– Ffilter,high = -2745 MHz-

– SEM-13,high = Threshold frequency where upper spectral emission mask for upper channel drops from -13 dBm / 1MHz to -25 dBm / 1MHz, as specified in Clause 6.5A.2.3.2.

– SEM-13,low = Threshold frequency where lower spectral emission mask below the lower channel drops from -13 dBm / MHz to -25 dBm / MHz, as specified in Clause 6.5A.2.3.2.

6.2A.3.1.2.1.1 AMPRIM3 to meet -25dBm/MHz for PC3

AMPR in this clause is for intra-band non-contiguous CA_n41(2A) power class 3 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

AMPRIM3=MAWhere MA is defined as follows

MA = 12; 0 ≤ B < 1.08

12; 1.08 ≤ B < 2.16

11; 2.16 ≤ B < 3.24

10; 3.24 ≤ B < 5.04

9; 5.04 ≤ B < 10.08

8; 10.08 ≤ B < 16.38

7; 16.38 ≤ B < 21.78

6; 21.78 ≤ B

6.2A.3.1.2.1.2 AMPRIM3 to meet -13dBm/MHz for PC3

AMPR in this clause is for intra-band non-contiguous CA_n41(2A) power class 3 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

AMPRIM3=MA

Where MA is defined as follows

MA = 9 ; 0 ≤ B < 0.54

8 ; 0.54 ≤ B < 1.08

7 ; 1.08 ≤ B < 2.16

6.5 ; 2.16 ≤ B < 3.24

5.5 ; 3.24 ≤ B < 5.4

4 ; 5.4 ≤ B

6.2A.3.1.2.1.3 AMPRIM3 to meet -25dBm/MHz for PC2

AMPR in this clause is for intra-band non-contiguous CA_n41(2A) power class 2 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

AMPRIM3=MAWhere MA is defined as follows

MA = 14.5; 0 ≤ B < 1.44

14.0; 1.44 ≤ B < 2.88

13.0; 2.88 ≤ B < 5.76

11.0; 5.76 ≤ B < 10.8

9.5; 10.8 ≤ B < 23.04

9.0; 23.04 ≤ B

Where:

B=(LCRB_alloc, 1* 12* SCS1 + LCRB_alloc,2 * 12 * SCS2)/1,000,000

6.2A.3.1.2.1.4 AMPRIM3 to meet -13dBm/MHz for PC2

AMPR in this clause is for intra-band non-contiguous CA_n41(2A) power class 2 for UEs indicating IE dualPA-Architecture supported. The allowed maximum output power reduction is defined as:

AMPRIM3=MA

Where MA is defined as follows

MA = 9 ; 0 ≤ B < 0.54

8 ; 0.54 ≤ B < 1.08

7 ; 1.08 ≤ B < 2.16

6.5 ; 2.16 ≤ B < 3.24

6 ; 3.24 ≤ B < 5.4

5.5 ; 5.4 ≤ B ≤ 10.8

4 ; 10.8 < B

Where:

B=(LCRB_alloc, 1* 12* SCS1 + LCRB_alloc,2 * 12 * SCS2)/1,000,000

6.2A.3.1.3 UE additional maximum output power reduction for Inter-band CA

Unless otherwise stated, for inter-band carrier aggregation with one uplink carrier assigned to one NR band, the requirements in subclause 6.2.3 apply.

Unless otherwise stated, for inter-band carrier aggregation with two uplink contiguous carrier assigned to one NR band, the additional maximum output power reduction requirements for intra-band contiguous carrier aggregation in subclause 6.2A.3.1.1 apply for that band, for inter-band carrier aggregation with two uplink non-contiguous carrier assigned to one NR band, the additional maximum output power reduction requirements for intra-band contiguous carrier aggregation in subclause 6.2A.3.1.2 apply for that band.

For combinations of intra-band and inter-band carrier aggregation with three uplink component carriers (up to two contiguously aggregated carriers per operating band), the additional maximum output power reduction requirements specified in subclause 6.2.3 apply for the NR band supporting one component carrier, and for the NR band supporting two contiguous component carriers the requirements specified in subclause 6.2A.3.1.1apply.

Unless specified in Table 6.2A.3.1.3-1, for inter-band carrier aggregation with uplink assigned to two NR bands, the requirements in clause 6.2.3 apply only to the indicated carrier. The requirements in Table 6.2A.3.1.3-1 are specified in terms of an additional spectrum emission requirement with their associated network signalling values and the allowed A-MPR. Unless otherwise stated, the combined requirements and allowed A-MPR are applicable on both bands when both component carriers are active. Additional spurious emission requirements are signalled by the network to indicate that the UE shall meet the additional requirement for a specific deployment scenario as part of the cell handover/broadcast message.

To meet the additional requirements, additional maximum power reduction (A-MPR) is allowed for the maximum output power as specified in Table 6.2.1-1. Unless stated otherwise, the total reduction to UE maximum output power is max(MPR, A-MPR) where MPR is defined in clause 6.2.2. In case of a power class 3 UE, when IE powerBoostPi2BPSK is set to 1, power class 2 A-MPR values apply.

For almost contiguous allocations in CP-OFDM waveforms in power class 3, the allowed A-MPR defined in clause 6.2.3 is increased by CEIL{ 10 log10(1 + NRB_gap / NRB_alloc), 0.5 } dB, where NRB_gap is the total number of unallocated RBs between allocated RBs and NRB_alloc is the total number of allocated RBs, and the parameter LCRB is replaced by NRB_alloc + NRB_gap in specifying the RB allocation regions.

Unless otherwise specified, pi/2 BPSK in following A-MPR tables refers to both variants of pi/2 BPSK referenced in 6.2.2 tables 6.2.2-1.

The emission requirements specified in Table 6.2A.3.1.3-1 also apply for the frequency ranges that are less than FOOB (MHz) in Table 6.5.3.1-1 from the edge of the channel bandwidth.

Table 6.2A.3.1.3-1: Additional Requirements for uplink inter-band carrier aggregation (two-bands)

NR CA combination

Band

Applied

NS

Requirements

(clause)

A-MPR

(table/clause)

Note

CA_n1-n3

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

n3

100

6.5.2.4.2

Table 6.2.3.1-2

CA_n1-n8

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

n8

43

6.5.3.3.5

Clause 6.2.3.6

43U

6.5.3.3.5, 6.5.2.4.2

Clause 6.2.3.6

CA_n1-n18

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

n18

100

6.5.2.4.2

Table 6.2.3.1-2

CA_n1-n28

n1

05

6.5.3.3.4

Clause 6.2.3.4

1,2

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

n28

17

6.5.3.3.2

N/A

CA_n1-n40

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

CA_n1-n41

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n1-n74

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

n74

37

6.5.3.3.6

Table 6.2.3.8-1

CA_n1-n77

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

CA_n1-n78

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

CA_n1-n79

n1

05

6.5.3.3.4

Clause 6.2.3.4

1

05U

6.5.3.3.4, 6.5.2.4.2

Clause 6.2.3.4

CA_n3-n8

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

n8

43

6.5.3.3.5

Clause 6.2.3.6

43U

6.5.3.3.5, 6.5.2.4.2

Clause 6.2.3.6

CA_n3-n18

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

n18

100

6.5.2.4.2

Table 6.2.3.1-2

CA_n3-n28

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1,2

n28

17

6.5.3.3.2

N/A

CA_n3-n40

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n3-n41

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n3-n74

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

n74

37

6.5.3.3.6

Table 6.2.3.8-1

CA_n3-n77

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n3-n78

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n3-n79

n3

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n5-n77

n5

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n5-n78

n5

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n5-n79

n5

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n8-n40

n8

43

6.5.3.3.5

Clause 6.2.3.6

1

43U

6.5.3.3.5, 6.5.2.4.2

Clause 6.2.3.6

CA_n8-n41

n8

43

6.5.3.3.5

Clause 6.2.3.6

1

43U

6.5.3.3.5, 6.5.2.4.2

Clause 6.2.3.6

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n8-n78

n8

43

6.5.3.3.5

Clause 6.2.3.6

1

43U

6.5.3.3.5, 6.5.2.4.2

Clause 6.2.3.6

CA_n8-n79

n8

43

6.5.3.3.5

Clause 6.2.3.6

1

43U

6.5.3.3.5, 6.5.2.4.2

Clause 6.2.3.6

CA_n18-n28

n18

100

6.5.2.4.2

Table 6.2.3.1-2

1, 2

n28

17

6.5.3.3.2

N/A

CA_n18-n41

n18

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n18-n74

n18

100

6.5.2.4.2

Table 6.2.3.1-2

1

n74

37

6.5.3.3.6

Table 6.2.3.8-1

CA_n18-n77

n18

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n18-n78

n18

100

6.5.2.4.2

Table 6.2.3.1-2

1

CA_n28-n40

n28

17

6.5.3.3.2

N/A

2

CA_n28-n41

n28

17

6.5.3.3.2

N/A

2

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n28-n74

n28

17

6.5.3.3.2

N/A

2

2

n74

37

6.5.3.3.6

Table 6.2.3.8-1

CA_n28-n77

n28

17

6.5.3.3.2

N/A

2

CA_n28-n78

n28

17

6.5.3.3.2

N/A

2

CA_n28-n79

n28

17

6.5.3.3.2

N/A

2

CA_n40-n41

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n41-n74

n41

47

6.5.3.3.15

Table 6.2.3.18-2

n74

37

6.5.3.3.6

Table 6.2.3.8-1

CA_n41-n77

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n41-n78

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n41-n79

n41

47

6.5.3.3.15

Table 6.2.3.18-2

CA_n74-n77

n74

37

6.5.3.3.6

Table 6.2.3.8-1

CA_n74-n78

n74

37

6.5.3.3.6

Table 6.2.3.8-1

NOTE 1: NS_05U, NS_43U and NS_100 can be signalled for NR bands that have UTRA services deployed and the requirements in clause 6.5.2.4.2 are only applicable to the signalling carrier.

NOTE 2: Applicable when the assigned NR carrier is confined within 718 MHz and 748 MHz and when the channel bandwidth used is 5 or 10 MHz.

6.2A.4 Configured output power for CA

6.2A.4.1 Configured transmitted power level

6.2A.4.1.1 Configured transmitted power for Intra-band contiguous CA

For uplink carrier aggregation the UE is allowed to set its configured maximum output power PCMAX,c for serving cell c and its total configured maximum output power PCMAX.

The configured maximum output power PCMAX,c on serving cell c shall be set as specified in clause 6.2.4, but with MPRc = MPR and A-MPRc = A-MPR with MPR and A-MPR as determined by subclause 6.2A.2 and 6.2A.3, respectively. For PH reporting the following exception applies: if the UE is configured with multiple uplink serving cells, the power PCMAX,c used for the purpose of PH reporting on first serving cell c = c1 does not consider for computation of the PH report transmissions on a second serving cell c2 as exempted in subclause 7.7.1 in [8]. There is one power management term for the UE, denoted P-MPR, and P-MPR c = P-MPR.

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

PCMAX_L ≤ PCMAX ≤ PCMAX_H

For uplink intra-band contiguous carrier aggregation when same slot pattern is used in all aggregated serving cells,

PCMAX_L = MIN{10 log10 ∑ pEMAX,c – TC , PEMAX,CA,(PPowerClass,CA– ΔPPowerClass,CA) – MAX(MAX(MPR, A-MPR) + ΔTIB,c + TC + TRxSRS, P-MPRc ) }

PCMAX_H = MIN{10 log10 ∑ pEMAX,c , PEMAX,CA ,PPowerClass,CA– ΔPPowerClass,CA }

where

– pEMAX,c is the linear value of PEMAX,c which is given by IE P-Max for serving cell c in [7];

PPowerClass,CA is the maximum UE power specified in Table 6.2A.1.1-1 without taking into account the tolerance;

– MPR and A-MPR are specified in clause 6.2A.2 and 6.2A.3, respectively;

– ΔPPowerClass,CA = 3 dB for a power class 2 capable UE when 10 log10 ∑ pEMAX,c of 23 dBm or lower is indicated; or when PEMAX,CA of 23dBm or lower is indicated; or when the field of UE capability maxUplinkDutyCycle-PC2-FR1 is absent and the percentage of total uplink symbols transmitted on all UL CCs in a certain evaluation period is larger than 50%; or when the field of UE capability maxUplinkDutyCycle-PC2-FR1 is not absent and the percentage of total uplink symbols transmitted in a certain evaluation period is larger than maxUplinkDutyCycle-PC2-FR1 as defined in TS 38.331 (The exact evaluation period is no less than one radio frame); otherwise ΔPPowerClass,CA = 0 dB;

– TIB,c is the additional tolerance for serving cell c as specified in clause 6.2A.4.2 for NR CA, clause 6.2C.2 for SUL, or TS 38.101-3 clause 6.2B.4.2 for EN-DC; In case the UE supports more than one of band combinations for CA, SUL or DC, and an operating band belongs to more than one band combinations then

a) When the operating band frequency range is ≤ 1 GHz, the applicable additional ∆TIB,c shall be the average value for all band combinations defined in clause 6.2A.4.2, 6.2C.2 in this specification and 6.2B.4.2 in TS 38.101-3 [3], truncated to one decimal place that apply for that operating band among the supported band combinations. In case there is a harmonic relation between low band UL and high band DL, then the maximum ∆TIB,c among the different supported band combinations involving such band shall be applied

b) When the operating band frequency range is > 1 GHz, the applicable additional ∆TIB,c shall be the maximum value for all band combinations defined in clause 6.2A.4.2, 6.2C.2 in this specification and 6.2B.4.2 in TS 38.101-3 [3] for the applicable operating bands.

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

– TC is the highest value TC,c among all serving cells c;

– ∆TRxSRS is the highest value among all serving cells c;

– PEMAX,CA is the value indicated by p-NR-FR1 or by p-UE-FR1 whichever is the smallest if both are present.

For uplink intra-band contiguous carrier aggregation, when at least one different numerology/slot pattern is used in aggregated cells, the UE is allowed to set its configured maximum output power PCMAX,c(i),i for serving cell c(i) of slot numerology type i, and its total configured maximum output power PCMAX.

The configured maximum output power PCMAX,c(i),i (p) in slot p of serving cell c(i) on slot numerology type i shall be set within the following bounds:

PCMAX_L,f,c(i),i (p) ≤ PCMAX,f,c(i), i (p) ≤ PCMAX_H,f,c(i),i (p)

where PCMAX_L,f,c (i),i (p) and PCMAX_H,f,c(i),i (p) are the limits for a serving cell c(i) of slot numerology type i as specified in clause 6.2.4.

The total UE configured maximum output power PCMAX (p,q) in a slot p of slot numerology or symbol pattern i, and a slot q of slot numerology or symbol pattern j that overlap in time shall be set within the following bounds unless stated otherwise:

PCMAX_L(p,q) ≤ PCMAX (p,q) ≤ PCMAX_H (p,q)

When slots p and q have different transmissions lengths and belong to different cells on different or same bands:

PCMAX_L (p,q) = MIN {10 log10 [pCMAX_L,f,c(i),i (p) + pCMAX_L,f,c(i),j (q)], PPowerClass,CA, PEMAX,CA}

PCMAX_H (p,q) = MIN {10 log10 [pCMAX_ H,f,c(i),i (p) + pCMAX_ H,f,c(i),j (q)], PPowerClass,CA, PEMAX,CA}

where pCMAX_L,f,c (i),i and pCMAX_ H,f,c(i),i are the respective limits PCMAX_L,f,c (i),i and PCMAX_H,f,c(i),i expressed in linear scale.

TREF and Teval are specified in Table 6.2A.4.1.1-0 when same and different slot patterns are used in aggregated carriers. For each TREF, the PCMAX_L is evaluated per Teval and given by the minimum value taken over the transmission(s) within the Teval; the minimum PCMAX_L over the one or more Teval is then applied for the entire TREF. The lesser of PPowerClass,CA and PEMAX,CA shall not be exceeded by the UE during any period of time.

Table 6.2A.4.1.1-0: PCMAX evaluation window for different slot and channel durations

TREF

Teval

Teval with frequency hopping

TREF of largest slot duration over both UL CCs

Physical channel length

Min(Tno_hopping, Physical Channel Length)

If the UE is configured with multiple TAGs and transmissions of the UE on slot i for any serving cell in one TAG overlap some portion of the first symbol of the transmission on slot i +1 for a different serving cell in another TAG, the UE minimum of PCMAX_L for slots i and i + 1 applies for any overlapping portion of slots i and i + 1. The lesser of PPowerClass,CA and PEMAX,CA shall not be exceeded by the UE during any period of time.

The measured maximum output power PUMAX over all serving cells with same slot pattern shall be within the following range:

PCMAX_L – MAX{TL, TLOW(PCMAX_L) } ≤ PUMAX ≤ PCMAX_H + THIGH(PCMAX_H)

PUMAX = 10 log10 ∑ pUMAX,c

where pUMAX,c denotes the measured maximum output power for serving cell c expressed in linear scale. The tolerances TLOW(PCMAX) and THIGH(PCMAX) for applicable values of PCMAX are specified in Table 6.2A.4.1.1-1. The tolerance TL is the absolute value of the lower tolerance for applicable NR CA configuration as specified in Table 6.2A.1.1-1 for intra-band carrier aggregation.

The measured maximum output power PUMAX over all serving cells, when at least one slot has a different transmission numerology or slot pattern, shall be within the following range:

P’CMAX_L– MAX{TL, TLOW (P’CMAX_L)} ≤ P’UMAX ≤ P’CMAX_H + THIGH (P’CMAX_H)

P’UMAX = 10 log10 ∑ p’UMAX,c

where p’UMAX,c denotes the average measured maximum output power for serving cell c expressed in linear scale over TREF. The tolerances TLOW(P’CMAX) and THIGH(P’CMAX) for applicable values of P’CMAX are specified in Table 6.2A.4.1.1-1 for intra-band carrier aggregation. The tolerance TL is the absolute value of the lower tolerance for applicable NR CA configuration as specified in Table 6.2A.1.1-1 for inter-band carrier aggregation.

where:

P’CMAX_L = MIN{ MIN {10log10∑( pCMAX_L,f,c(i),i), PPowerClass,CA} over all overlapping slots in TREF}

P’CMAX_H = MAX{ MIN{10 log10 ∑ pEMAX,c , PPowerClass,CA} over all overlapping slots in TREF}

Table 6.2A.4.1.1-1: PCMAX tolerance for uplink intra-band contiguous CA

PCMAX
(dBm)

Tolerance
TLOW(PCMAX)
(dB)

Tolerance
THIGH(PCMAX)
(dB)

23 < PCMAX ≤ 26

3

2

21 ≤ PCMAX ≤ 23

2.0

20 ≤ PCMAX < 21

2.5

19 ≤ PCMAX < 20

3.5

18 ≤ PCMAX < 19

4.0

13 ≤ PCMAX < 18

5.0

8 ≤ PCMAX < 13

6.0

-40 ≤ PCMAX < 8

7.0

6.2A.4.1.2 Configured transmitted power for Intra-band non-contiguous CA

For uplink carrier aggregation the UE is allowed to set its configured maximum output power PCMAX,c for serving cell c and its total configured maximum output power PCMAX.

The configured maximum output power PCMAX,c on serving cell c shall be set as specified in subclause 6.2.4.

The configured maximum output power PCMAX,c on serving cell c shall be set as specified in subclause 6.2.4, but with MPRc = MPR and A-MPRc = A-MPR with MPR and A-MPR as determined by subclause 6.2A.2 and 6.2A.3, respectively. For PH reporting the following exception applies: if the UE is configured with multiple uplink serving cells, the power PCMAX,c used for the purpose of PH reporting on first serving cell c = c1 does not consider for computation of the PH report transmissions on a second serving cell c2 as exempted in subclause 7.7.1 in [8]. There is one power management term for the UE, denoted P-MPR, and P-MPR c = P-MPR.

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

PCMAX_L ≤ PCMAX ≤ PCMAX_H

For uplink intra-band non-contiguous carrier aggregation when same slot pattern is used in all aggregated serving cells,

PCMAX_L = MIN{10 log10 ∑ pEMAX,c – TC , PEMAX,CA,PPowerClass,CA – MAX(MAX(MPRc, A-MPRc) + ΔTIB,c + TC + DTRxSRS, P-MPR ) }

PCMAX_H = MIN{10 log10 ∑ pEMAX,c , PEMAX,CA ,PPowerClass,CA}

where

– pEMAX,c is the linear value of PEMAX,c which is given by IE P-Max for serving cell c in [7];

– PPowerClass,CA is the maximum UE power specified in Table 6.2A.1.2-1 without taking into account the tolerance;

– MPR and A-MPR are specified in subclause 6.2A.2 and subclause 6.2A.3 respectively;

– TIB,c is the additional tolerance for serving cell c as specified in clause 6.2A.4.2 for NR CA, clause 6.2C.2 for SUL, or TS 38.101-3 clause 6.2B.4.2 for EN-DC; In case the UE supports more than one of band combinations for CA, SUL or DC, and an operating band belongs to more than one band combinations then

a) When the operating band frequency range is ≤ 1 GHz, the applicable additional ∆TIB,c shall be the average value for all band combinations defined in clause 6.2A.4.2, 6.2C.2 in this specification and 6.2B.4.2 in TS 38.101-3 [3], truncated to one decimal place that apply for that operating band among the supported band combinations. In case there is a harmonic relation between low band UL and high band DL, then the maximum ∆TIB,c among the different supported band combinations involving such band shall be applied

b) When the operating band frequency range is > 1 GHz, the applicable additional ∆TIB,c shall be the maximum value for all band combinations defined in clause 6.2A.4.2, 6.2C.2 in this specification and 6.2B.4.2 in TS 38.101-3 [3] for the applicable operating bands.

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

– TC is the highest value TC,c among all serving cells c;

– ∆TRxSRS is the highest value among all serving cells c;

– PEMAX,CA is the value indicated by p-NR-FR1 or by p-UE-FR1 whichever is the smallest if both are present.

[For uplink intra-band non-contiguous carrier aggregation, when at least one different numerology/slot pattern is used in aggregated cells, the UE is allowed to set its configured maximum output power PCMAX,c(i),i for serving cell c(i) of slot numerology type i, and its total configured maximum output power PCMAX.

The configured maximum output power PCMAX,c(i),i (p) in slot p of serving cell c(i) on slot numerology type i shall be set within the following bounds:

PCMAX_L,f,c(i),i (p) ≤ PCMAX,f,c(i), i (p) ≤ PCMAX_H,f,c(i),i (p)

where PCMAX_L,f,c (i),i (p) and PCMAX_H,f,c(i),i (p) are the limits for a serving cell c(i) of slot numerology type i as specified in subclause 6.2.4.

The total UE configured maximum output power PCMAX (p,q) in a slot p of slot numerology or symbol pattern i, and a slot q of slot numerology or symbol pattern j that overlap in time shall be set within the following bounds unless stated otherwise:

PCMAX_L(p,q) ≤ PCMAX (p,q) ≤ PCMAX_H (p,q)

When slots p and q have different transmissions lengths and belong to different cells on different or same bands:

PCMAX_L (p,q) = MIN {10 log10 [pCMAX_L,f,c(i),i (p) + pCMAX_L,f,c(i),j (q)], PPowerClass,CA, PEMAX,CA}

PCMAX_H (p,q) = MIN {10 log10 [pCMAX_ H,f,c(i),i (p) + pCMAX_ H,f,c(i),j (q)], PPowerClass,CA, PEMAX,CA}

where pCMAX_L,f,c (i),i and pCMAX_ H,f,c(i),i are the respective limits PCMAX_L,f,c (i),i and PCMAX_H,f,c(i),i expressed in linear scale.]

TREF and Teval are specified in Table 6.2A.4.1.2-1 when same and different slot patterns are used in aggregated carriers. For each TREF, the PCMAX_L is evaluated per Teval and given by the minimum value taken over the transmission(s) within the Teval; the minimum PCMAX_L over the one or more Teval is then applied for the entire TREF. The lesser of PPowerClass,CA and PEMAX,CA shall not be exceeded by the UE during any period of time.

Table 6.2A.4.1.2-1: PCMAX evaluation window for different slot and channel durations

TREF

Teval

Teval with frequency hopping

TREF of largest slot duration over both UL CCs

Physical channel length

Min(Tno_hopping, Physical Channel Length)

If the UE is configured with multiple TAGs and transmissions of the UE on slot i for any serving cell in one TAG overlap some portion of the first symbol of the transmission on slot i +1 for a different serving cell in another TAG, the UE minimum of PCMAX_L for slots i and i + 1 applies for any overlapping portion of slots i and i + 1. The lesser of PPowerClass,CA and PEMAX,CA shall not be exceeded by the UE during any period of time.

The measured maximum output power PUMAX over all serving cells with same slot pattern shall be within the following range:

PCMAX_L – MAX{TL, TLOW(PCMAX_L) } ≤ PUMAX ≤ PCMAX_H + THIGH(PCMAX_H)

PUMAX = 10 log10 ∑ pUMAX,c

where pUMAX,c denotes the measured maximum output power for serving cell c expressed in linear scale. The tolerances TLOW(PCMAX) and THIGH(PCMAX) for applicable values of PCMAX are specified in Table 6.2A.4.1.2-2. The tolerance TL is the absolute value of the lower tolerance for applicable NR CA configuration as specified in Table 6.2A.1.2-1 for intra-band carrier aggregation.

The measured maximum output power PUMAX over all serving cells, when at least one slot has a different transmission numerology or slot pattern, shall be within the following range:

P’CMAX_L– MAX{TL, TLOW (P’CMAX_L)} ≤ P’UMAX ≤ P’CMAX_H + THIGH (P’CMAX_H)

P’UMAX = 10 log10 ∑ p’UMAX,c

where p’UMAX,c denotes the average measured maximum output power for serving cell c expressed in linear scale over TREF. The tolerances TLOW(P’CMAX) and THIGH(P’CMAX) for applicable values of P’CMAX are specified in Table 6.2A.4.1.2-2 for intra-band carrier aggregation. The tolerance TL is the absolute value of the lower tolerance for applicable NR CA configuration as specified in Table 6.2A.1.2-2 for intra-band carrier aggregation.

where:

P’CMAX_L = MIN{ MIN {10log10∑( pCMAX_L,f,c(i),i), PPowerClass,CA} over all overlapping slots in TREF}

P’CMAX_H = MAX{ MIN{10 log10 ∑ pEMAX,c , PPowerClass,CA} over all overlapping slots in TREF}

Table 6.2A.4.1.2-2: PCMAX tolerance for uplink intra-band non-contiguous CA

PCMAX
(dBm)

Tolerance
TLOW(PCMAX)
(dB)

Tolerance
THIGH(PCMAX)
(dB)

21 ≤ PCMAX ≤ 23

3.0

2.0

20 ≤ PCMAX < 21

2.5

19 ≤ PCMAX < 20

3.5

18 ≤ PCMAX < 19

4.0

13 ≤ PCMAX < 18

5.0

8 ≤ PCMAX < 13

6.0

-40 ≤ PCMAX < 8

7.0

6.2A.4.1.3 Configured transmitted power for Inter-band CA

For uplink carrier aggregation the UE is allowed to set its configured maximum output power PCMAX,c for serving cell c and its total configured maximum output power PCMAX.

The configured maximum output power PCMAX,c on serving cell c shall be set as specified in clause 6.2.4, except that the UE power class for serving cell c on the specific operating band shall be determined by the [powerClassPerBand] IE [TS 38.331] as indicated for the band combination if signalled.

For uplink inter-band carrier aggregation, MPRc and A-MPRc apply per serving cell c and are specified in clause 6.2.2 and clause 6.2.3, respectively. P-MPR c accounts for power management for serving cell c. PCMAX,c is calculated under the assumption that the transmit power is increased independently on all component carriers.

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

PCMAX_L ≤ PCMAX ≤ PCMAX_H

For uplink inter-band carrier aggregation with one serving cell c per operating band when same slot symbol pattern is used in all aggregated serving cells,

PCMAX_L = MIN {10log10∑ MIN [ pEMAX,c/ (tC,c), pPowerClass.c/(MAX(mprc·∆mprc, a-mprc)·tC,c ·tIB,c·tRxSRS,c) , pPowerClass,c/pmprc], PEMAX,CA, PPowerClass,CA-ΔPPowerClass, CA}

PCMAX_H = MIN{10 log10 ∑ pEMAX,c , PEMAX,CA, PPowerClass,CA-ΔPPowerClass, CA}

where

– pEMAX,c is the linear value of PEMAX, c which is given by IE P-Max for serving cell c in [7];

– PPowerClass,CA is the maximum UE power specified in Table 6.2A.1.3-1 without taking into account the tolerance specified in the Table 6.2A.1.3-1; If the UE indicates [HigherPowerLimitCADC] for an eligible CA configuration as specified in Table 6.2A.1.3-1 and ΔPPowerClass, CA = 0, PPowerClass,CA is replaced by 10 log10 ∑ pPowerClass,c.

– pPowerClass,c is the linear value of the maximum UE power for serving cell c specified in Table 6.2.1-1 according to [powerClassPerBand] if indicated or ue-PowerClass otherwise without taking into account the tolerance;

– ΔPPowerClass,CA = 3 dB for a power class 2 capable UE when the requirements of default power class are applied as specified in sub-clause 6.2.A.1.3; otherwise ΔPPowerClass, CA = 0 dB;

– mpr c and a-mpr c are the linear values of MPR c and A-MPR c as specified in clause 6.2.2 and clause 6.2.3, respectively;

– ∆mpr c is the linear value of ∆MPR c as specified in clause 6.2.2;

– pmprc is the linear value of P-MPR c;

– ∆tRxSRS,c is the linear value of ∆TRxSRS,c;

– tC,c is the linear value of TC,ctC,c = 1.41 when NOTE 2 in Table 6.2A.1.3-1 applies for a serving cell c, otherwise tC,c = 1;

– tIB,c is the linear value of the inter-band relaxation term TIB,c of the serving cell c as specified in clause 6.2A.4.2 for NR CA, clause 6.2C.2 for SUL, or TS 38.101-3 clause 6.2B.4.2 for EN-DC; otherwise tIB,c In case the UE supports more than one of band combinations for CA, SUL or DC, and an operating band belongs to more than one band combinations then

a) When the operating band frequency range is ≤ 1 GHz, the applicable additional TIB,c shall be the average value for all band combinations defined in clause 6.2A.4.2, 6.2C.2 in this specification and 6.2B.4.2 in TS 38.101-3 [3], truncated to one decimal place that apply for that operating band among the supported band combinations. In case there is a harmonic relation between low band UL and high band DL, then the maximum ∆TIB,c among the different supported band combinations involving such band shall be applied

b) When the operating band frequency range is > 1 GHz, the applicable additional ∆TIB,c shall be the maximum value for all band combinations defined in clause 6.2A.4.2, 6.2C.2 in this specification and 6.2B.4.2 in TS 38.101-3 [3] for the applicable operating bands.

– PEMAX,CA is the value indicated by p-NR-FR1 or by p-UE-FR1 whichever is the smallest if both are present.For uplink inter-band carrier aggregation with one serving cell c per operating band when at least one different numerology/slot pattern is used in aggregated cells, the UE is allowed to set its configured maximum output power PCMAX,c(i),i for serving cell c(i) of slot numerology type i, and its total configured maximum output power PCMAX.

The configured maximum output power PCMAX,c(i),i (p) in slot p of serving cell c(i) on slot numerology type i shall be set within the following bounds:

PCMAX_L,f,c(i),i (p) ≤ PCMAX,f,c(i), i (p) ≤ PCMAX_H,f,c(i),i (p)

where PCMAX_L,f,c (i),i (p) and PCMAX_H,f,c(i),i (p) are the limits for a serving cell c(i) of slot numerology type i as specified in clause 6.2.4, except that the UE power class for the serving cell c(i) on the specific operating band shall be determined by the [powerClassPerBand] IE [TS 38.331] as indicated for the band combination if signalled.

The total UE configured maximum output power PCMAX (p,q) in a slot p of slot numerology or symbol pattern i, and a slot q of slot numerology or symbol pattern j that overlap in time shall be set within the following bounds unless stated otherwise:

PCMAX_L(p,q) ≤ PCMAX (p,q) ≤ PCMAX_H (p,q)

When slots p and q have different transmissions lengths and belong to different cells on different bands:

PCMAX_L (p,q) = MIN {10 log10 [pCMAX_L,f,c(i),i (p) + pCMAX_L,f,c(i),j (q)], PPowerClass,CA, PEMAX,CA}

PCMAX_H (p,q) = MIN {10 log10 [pCMAX_ H,f,c(i),i (p) + pCMAX_ H,f,c(i),j (q)], PPowerClass,CA, PEMAX,CA}

where pCMAX_L,f,c (i),i and pCMAX_ H,f,c(i),i are the respective limits PCMAX_L,f,c (i),i and PCMAX_H,f,c(i),i expressed in linear scale and pPowerClass,c is the linear value of the maximum UE power for serving cell c specified in Table 6.2.1-1 according to [powerClassPerBand] if indicated or ue-PowerClass otherwise without taking into account the tolerance; If the UE indicates [HigherPowerLimitCADC], PPowerClass,CA is replaced by 10 log10 ∑ pPowerClass,c.

For combinations of intra-band and inter-band carrier aggregation with UE configured for transmission on three serving cells (up to two contiguously aggregated carriers per operating band), the following apply:

The UE power class for the serving cell(s) on the operating band Bi including intra-band carrier aggregation shall be determined by the [powerClassPerBand] IE [TS 38.331] as indicated for the band combination if signalled.

For the case when p and q belong to the same band and k belongs to a different band, but p, q and k are of the same numerology and slot patterns.

PCMAX_L = MIN {10log10∑( pCMAX_L, Bi), PEMAX,CA, PPowerClass.CA }

PCMAX_H = MIN{10 log10 ∑ pEMAX,c , PEMAX,CA, PPowerClass.CA }

Where

– pCMAX_L, Bi is the linear values of PCMAX_L specified for the specific operating band Bi.

– The linear value of PCMAX_L specified for uplink intra-band contiguous carrier aggregation in subclause 6.2A.4.1.1 applies for operating band supporting two contiguous serving cells, designated by its band index Bi. The linear value of PCMAX_L specified for single carrier in subclause 6.2.4 applies for operating band Bj supporting one serving cell.

For the case when p and q belong to the same band and are of the same numerology i and slot patterns (p,q),while k belong to a different band and is of different numerology j and/or slot pattern on the 3rd cell then:

PCMAX_L (p,q,k) = MIN {10 log10 [pCMAX_L,Bi,i(p,q) + pCMAX_L,c(3),Bj,j(k)], PEMAX,CA, PPowerClass.CA }

PCMAX_H (p,q,k) = MIN {10 log10 [pCMAX_ H,Bi,i (p,q) + pCMAX_ H,c(3), Bj,j(k)], PEMAX,CA, PPowerClass.CA }

Where

– pEMAX,c is the linear value of PEMAX, c which is given by IE P-Max for serving cell c in [7];

– PEMAX,CA is p-UE-FR1 value signalled by RRC and defined in [38.331];

– PPowerClass.CA is the maximum UE power specified in Table 6.2A.1.3-1 without taking into account the tolerance specified in the Table 6.2A.1.3-1 or Table 6.2F.1A.1-1 for shared spectrum bands;

– pCMAX_L,c(3),Bj,j(k) and pCMAX_ H,c(3), Bj,j(k) are the linear values of PCMAX_L and PCMAX_H respectively, specified for single carrier in subclause 6.2.4 and applies for operating band supporting one serving cell in the Bj band on numerology j, using slot pattern k;

– pCMAX_L,Bi,i(p,q) and pCMAX_ H,Bi,i (p,q) are the linear values of PCMAX_L respectively PCMAX_H for uplink intra-band contiguous carrier aggregation specified in subclause 6.2A.4.1.1 which applies for operating band Bi on numerology i, supporting two contiguous serving cells, using the same slot pattern (p,q).

TREF and Teval are specified in Table 6.2A.4.1.3-0 when same and different slot patterns are used in aggregated carriers. For each TREF, the PCMAX_L is evaluated per Teval and given by the minimum value taken over the transmission(s) within the Teval; the minimum PCMAX_L over the one or more Teval is then applied for the entire TREF. The lesser of PPowerClass,CA and PEMAX,CA shall not be exceeded by the UE during any period of time.

Table 6.2A.4.1.3-0: PCMAX evaluation window for different slot and channel durations

TREF

Teval

Teval with frequency hopping

TREF of largest slot duration over both UL CCs

Physical channel length

Min(Tno_hopping, Physical Channel Length)

If the UE is configured with multiple TAGs and transmissions of the UE on slot i for any serving cell in one TAG overlap some portion of the first symbol of the transmission on slot i +1 for a different serving cell in another TAG, the UE minimum of PCMAX_L for slots i and i + 1 applies for any overlapping portion of slots i and i + 1. The lesser of PPowerClass,CA and PEMAX,CA shall not be exceeded by the UE during any period of time.

The measured maximum output power PUMAX over all serving cells with same slot pattern shall be within the following range:

PCMAX_L – MAX{TL, TLOW(PCMAX_L) } ≤ PUMAX ≤ PCMAX_H + THIGH(PCMAX_H)

PUMAX = 10 log10 ∑ pUMAX,c

where pUMAX,c denotes the measured maximum output power for serving cell c expressed in linear scale. The tolerances TLOW(PCMAX) and THIGH(PCMAX) for applicable values of PCMAX are specified in Table 6.2A.4.1.3-1. The tolerance TL is the absolute value of the lower tolerance for applicable NR CA configuration as specified in Table 6.2A.1.3-1-2 for inter-band carrier aggregation.

The measured maximum output power PUMAX over all serving cells, when at least one slot has a different transmission numerology or symbol pattern, shall be within the following range:

P’CMAX_L– MAX{TL, TLOW (P’CMAX_L)} ≤ P’UMAX ≤ P’CMAX_H + THIGH (P’CMAX_H)

P’UMAX = 10 log10 ∑ p’UMAX,c

where p’UMAX,c denotes the average measured maximum output power for serving cell c expressed in linear scale over TREF. The tolerances TLOW(P’CMAX) and THIGH(P’CMAX) for applicable values of P’CMAX are specified in Table 6.2A.4.1.3-1 for inter-band carrier aggregation. The tolerance TL is the absolute value of the lower tolerance for applicable NR CA configuration as specified in Table 6.2A.1.3-1 for inter-band carrier aggregation.

where:

P’CMAX_L = MIN{ MIN {10log10∑( pCMAX_L,f,c(i),i), PPowerClass,CA} over all overlapping slots in TREF}

P’CMAX_H = MAX{ MIN{10 log10 ∑ pEMAX,c , PPowerClass,CA} over all overlapping slots in TREF}

If the UE indicates [HigherPowerLimitCADC], PPowerClass,CA is replaced by 10 log10 ∑ pPowerClass,c

Table 6.2A.4.1.3-1: PCMAX tolerance for uplink inter-band CA (two bands)

PCMAX
(dBm)

Tolerance
TLOW(PCMAX)
(dB)

Tolerance
THIGH(PCMAX)
(dB)

23 ≤ PCMAX ≤ 28

3.0

2.0

22 ≤ PCMAX < 23

5.0

2.0

21 ≤ PCMAX < 22

5.0

3.0

20 ≤ PCMAX < 21

6.0

4.0

16 ≤ PCMAX < 20

5.0

11 ≤ PCMAX < 16

6.0

-40 ≤ PCMAX < 11

7.0

6.2A.4.1.4 Void

6.2A.4.2 ΔTIB,c for CA

For the UE which supports inter-band NR CA configuration, ΔTIB,c in tables below applies. Unless otherwise stated, ΔTIB,c is set to zero.

6.2A.4.2.1 Void
6.2A.4.2.2 Void
6.2A.4.2.3 ΔTIB,c for Inter-band CA (two bands)

Table 6.2A.4.2.3-1: ΔTIB,c due to NR CA (two bands)

Inter-band CA combination

NR Band

ΔTIB,c (dB)

CA_n1-n3

n1

0.3

n3

0.3

CA_n1-n5

n1

0.3

n5

0.3

CA_n1-n7

n1

0.5

n7

0.6

CA_n1-n8

n1

0.3

n8

0.3

CA_n1-n18

n1

0.3

n18

0.3

CA_n1-n20

n1

0.3

n20

0.3

CA_n1-n28

n1

0.3

n28

0.6

CA_n1-n38

n1

0.5

n38

0.5

CA_n1-n40

n1

0.5

n40

0.5

CA_n1-n41

n1

0.5

n41

0.5

CA_n1-n67

n1

0.3

CA_n1-n74

n1

0.3

n74

0.3

CA_n1-n77

n1

0.6

n77

0.8

CA_n1-n78

n1

0.3

n78

0.8

CA_n2-n5

n2

0.3

n5

0.3

CA_n2-n7

n2

0.5

n7

0.5

CA_n2-n12

n2

0.3

n12

0.3

CA_n2-n14

n2

0.3

n14

0.3

CA_n2-n29

n2

0.3

CA_n2-n30

n2

0.5

n30

0.3

CA_n2-n48

n2

0.6

n48

0.8

CA_n2-n66

n2

0.5

n66

0.5

CA_n2-n77

n2

0.6

n77

0.8

CA_n2-n78

n2

0.6

n78

0.8

CA_n3-n5

n3

0.3

n5

0.3

CA_n3-n7

n3

0.5

n7

0.5

CA_n3-n8

n3

0.3

n8

0.3

CA_n3-n18

n3

0.3

n18

0.3

CA_n3-n20

n3

0.3

n20

0.3

CA_n3-n28

n3

0.3

n28

0.3

CA_n3-n34

n3

0.5

n34

0.5

CA_n3-n38

n3

0.5

n38

0.5

CA_n3-n40

n3

0.5

n40

0.5

CA_n3-n41

n3

0.5

n41

0.34

0.85

CA_n3-n74

n3

0.8

n74

0.9

CA_n3-n77

n3

0.6

n77

0.8

CA_n3-n78

n3

0.6

n78

0.8

CA_n3-n79

n3

0.3

n79

0.8

CA_n5-n7

n5

0.3

n7

0.3

CA_n5-n12

n5

0.8

n12

0.4

CA_n5-n14

n5

0.5

n14

0.5

CA_n5-n25

n5

0.3

n25

0.3

CA_n5-n28

n5

0.5

n28

0.5

CA_n5-n29

n5

0.5

CA_n5-n30

n5

0.3

n30

0.3

CA_n5-n40

n5

0.3

n40

0.3

CA_n5-n48

n5

0.3

n48

0.3

CA_n5-n66

n5

0.3

n66

0.3

CA_n5-n77

n5

0.6

n77

0.8

CA_n5-n78

n5

0.6

n78

0.8

CA_n7-n8

n7

0.3

n8

0.6

CA_n7-n25

n7

0.5

n25

0.5

CA_n7-n28

n7

0.3

n28

0.3

CA_n7-n40

n7

0.5

n40

0.6

CA_n7-n46

n7

0.3

CA_n7-n66

n7

0.5

n66

0.5

CA_n7-n77

n7

0.5

n77

0.8

CA_n7-n78

n7

0.5

n78

0.8

CA_n7-n79

n7

0.5

n79

0.8

CA_n8-n20

n8

0.4

n20

0.4

CA_n8-n28

n8

0.6

n28

0.5

CA_n8-n34

n8

0.3

n34

0.3

CA_n8-n38

n8

0.6

n38

0.3

CA_n8-n39

n8

0.3

n39

0.3

CA_n8-n40

n8

0.3

n40

0.3

CA_n8-n41

n8

0.6

n41

0.3

CA_n8-n75

n8

0.3

CA_n8-n77

n8

0.6

n77

0.8

CA_n8-n78

n8

0.6

n78

0.8

CA_n8-n79

n8

0.3

n79

0.8

CA_n12-n25

n12

0.3

n25

0.3

CA_n12-n30

n12

0.3

n30

0.3

CA_n12-n48

n12

0.3

n48

0.3

CA_n12-n66

n12

0.8

n66

0.3

CA_n12-n71

n12

1

n71

1

CA_n12-n77

n12

0.5

n77

0.8

CA_n13-n25

n13

0.3

n25

0.3

CA_n13-n66

n13

0.3

n66

0.3

CA_n13-n77

n13

0.5

n78

0.8

CA_n14-n30

n14

0.3

n30

0.3

CA_n14-n66

n14

0.3

n66

0.3

CA_n14-n77

n14

0.5

n77

0.8

CA_n18-n28

n18

0.5

n28

0.5

CA_n18-n41

n18

0.3

n41

0.3

CA_n18-n74

n18

0.3

n74

0.3

CA_n18-n77

n18

0.3

n77

0.8

CA_n18-n78

n18

0.3

n78

0.8

CA_n20-n28

n20

0.5

n28

0.5

CA_n20-n40

n20

0.3

n40

0.3

CA_n20-n75

n20

0.3

CA_n20-n78

n20

0.6

n78

0.8

CA_n20-n67

n20

0.5

CA_n24-n41

n24

0.3

n41

0.46

0.97

CA_n24-n48

n24

0.6

n48

0.8

CA_n24-n77

n24

0.6

n77

0.8

CA_n25-n29

n25

0.3

CA_n25-n38

n25

0.5

n38

0.5

CA_n25-n41

n25

0.5

n41

0.46

0.97

CA_n25-n48

n25

0.6

n48

0.8

CA_n25-n66

n25

0.5

n66

0.5

CA_n25-n71

n25

0.3

n71

0.6

CA_n25-n77

n25

0.6

n77

0.8

CA_n26-n66

n26

0.3

n66

0.3

CA_n26-n70

n26

0.3

n70

0.3

CA_n28-n34

n28

0.3

n34

0.3

CA_n28-n38

n28

0.3

n38

0.3

CA_n28-n39

n28

0.3

n39

0.3

CA_n28-n40

n28

0.3

n40

0.3

CA_n28-n41

n28

0.3

n41

0.3

CA_n28-n50

n28

0.3

n50

0.4

CA_n28-n71

n28

1.1

n71

1.1

CA_n28-n74

n28

0.6

n74

0.4

CA_n28-n75

n28

0.3

CA_n28-n77

n28

0.5

n77

0.8

CA_n28-n78

n28

0.5

n78

0.8

CA_n28-n79

n28

0.5

n79

0.8

CA_n29-n30

n30

0.3

CA_n29-n66

n66

0.3

CA_n29-n70

n70

0.3

CA_n29-n71

n71

0.5

CA_n29-n77

n77

0.8

CA_n34-n79

n34

0.3

n79

0.8

CA_n30-n66

n30

0.5

n66

0.8

CA_n30-n77

n30

0.3

n77

0.8

CA_n34-n41

n34

0.3

n41

0.3

CA_n34-n79

n34

0.3

n79

0.8

CA_n38-n40

n38

0.53

n40

0.53

CA_n38-n66

n38

0.5

n66

0.5

CA_n38-n78

n38

0.3

n78

0.8

CA_n38-n79

n38

0.3

n79

0.8

CA_n39-n41

n39

02

n41

02

n39

0.53

n41

0.53

CA_n39-n79

n39

0.3

n79

0.8

CA_n40-n41

n40

0.53

n41

0.53

CA_n40-n77

n77

0.5

CA_n40-n78

n78

0.5

CA_n40-n79

n40

0.3

n79

0.8

CA_n41-n48

n41

0.3

n48

0.8

CA_n41-n50

n41

0.3

n50

0.4

CA_n41-n66

n41

0.86

1.37

n66

0.5

CA_n41-n70

n41

0.5

n70

0.5

CA_n41-n71

n41

0.3

n71

0.6

CA_n41-n74

n41

0.3

n74

0.3

CA_n41-n771

n41

0.3

n77

0.8

CA_n41-n781

n41

0.3

n78

0.8

CA_n41-n79

n41

0.3

n79

0.8

CA_n46-n48

n48

0.5

CA_n46-n78

n78

0.8

CA_n46-n96

n96

0.5

CA_n48-n53

n48

0.53

n53

0.33

CA_n48-n66

n48

0.8

n66

0.6

CA_n48-n70

n48

0.8

n70

0.6

CA_n48-n71

n48

0.3

n71

0.3

CA_n48-n96

n48

0.5

n96

0.5

CA_n50-n78

n50

02

n78

02

n50

0.53

n78

0.53

CA_n66-n70

n66

0.5

n70

0.5

CA_n66-n71

n66

0.3

n71

0.3

CA_n66-n77

n66

0.6

n77

0.8

CA_n66-n78

n66

0.6

n78

0.8

CA_n70-n71

n70

0.3

n71

0.6

CA_n70-n78

n70

0.6

n78

0.8

CA_n71-n77

n71

0.5

n77

0.8

CA_n71-n78

n71

0.5

n78

0.8

CA_n74-n77

n74

0.4

n77

0.8

CA_n74-n78

n74

0.4

n78

0.8

CA_n75-n78

n78

0.8

CA_n76-n78

n78

0.8

CA_n77-n79

n77

0.5

n79

0.5

CA_n78-n79

n78

0.5

1.58

n79

0.5

1.58

CA_n78-n92

n78

0.8

n92

0.6

NOTE 1: The requirements only apply when the sub-frame and Tx-Rx timings are synchronized between the component carriers. In the absence of synchronization, the requirements are not within scope of these specifications.

NOTE 2: Only applicable for UE supporting inter-band carrier aggregation with uplink in one NR band and without simultaneous Rx/Tx.

NOTE 3: Applicable for UE supporting inter-band carrier aggregation without simultaneous Rx/Tx.

NOTE 4: The requirement is applied for UE transmitting on the frequency range of 2515-2690 MHz.

NOTE 5: The requirement is applied for UE transmitting on the frequency range of 2496-2515 MHz.

NOTE 6: The requirement is applied for UE transmitting on the frequency range of 2545-2690 MHz.

NOTE 7: The requirement is applied for UE transmitting on the frequency range of 2496-2545 MHz.

NOTE 8: The requirements only apply for UE supporting inter-band carrier aggregation with simultaneous Rx/Tx capability, and NR UL carrier frequencies are confined to 3700 MHz-3800MHz for n78 and 4400 MHz-4500MHz for n79. Simultaneous Rx/Tx capability does not apply for UEs supporting band n78 with a n77 implementation.

Table 6.2A.4.2.3-2: Void

Table 6.2A.4.2.3-3: Void

6.2A.4.2.4 ΔTIB,c for Inter-band CA (three bands)

Table 6.2A.4.2.4-1: ΔTIB,c due to NR CA (three bands)

Inter-band CA combination

NR Band

ΔTIB,c (dB)

CA_n1-n3-n5

n1

0.3

n3

0.3

n5

0.3

CA_n1-n3-n7

n1

0.6

n3

0.6

n7

0.6

CA_n1-n3-n8

n1

0.3

n3

0.3

n8

0.3

CA_n1-n3-n18

n1

0.3

n3

0.3

n18

0.3

CA_n1-n3-n20

n1

0.3

n3

0.3

n20

0.3

CA_n1-n3-n28

n1

0.3

n3

0.3

n28

0.6

CA_n1-n3-n41

n1

0.5

n3

0.5

n41

0.35

0.86

CA_n1-n3-n77

n1

0.6

n3

0.6

n77

0.8

CA_n1-n3-n78

n1

0.6

n3

0.6

n78

0.8

CA_n1-n3-n79

n1

0.3

n3

0.3

n79

0.8

CA_n1-n5-n7

n1

0.5

n5

0.3

n7

0.6

CA_n1-n5-n28

n1

0.3

n5

0.6

n28

0.6

CA_n1-n5-n78

n1

0.6

n5

0.6

n78

0.8

CA_n1-n7-n8

n1

0.5

n7

0.6

n8

0.6

CA_n1-n7-n28

n1

0.5

n7

0.6

n28

0.6

CA_n1-n7-n40

n1

0.6

n7

0.8

n40

0.9

CA_n1-n7-n78

n1

0.6

n7

0.6

n78

0.8

CA_n1-n7-n79

n1

0.6

n7

0.6

n79

0.8

CA_n1-n8-n28

n1

0.3

n8

0.6

n28

0.6

CA_n1-n8-n40

n1

0.3

n8

0.3

n40

0.5

CA_n1-n8-n77

n1

0.3

n8

0.6

n77

0.8

CA_n1-n8-n78

n1

0.3

n8

0.6

n78

0.8

CA_n1-n8-n79

n1

0.3

n8

0.6

n79

0.8

CA_n1-n18-n28

n1

0.3

n18

0.5

n28

0.5

CA_n1-n18-n41

n1

0.5

n18

0.3

n41

0.5

CA_n1-n18-n77

n1

0.3

n18

0.3

n77

0.8

CA_n1-n20-n67

n1

0.5

n20

0.6

n67

0.8

CA_n1-n20-n78

n1

0.3

n20

0.6

n78

0.8

CA_n1-n28-n38

n1

0.5

n28

0.6

n38

0.5

CA_n1-n28-n40

n1

0.6

n28

0.3

n40

0.5

CA_n1-n28-n41

n1

0.5

n28

0.6

n41

0.6

CA_n1-n28-n77

n1

0.6

n28

0.6

n77

0.8

CA_n1-n28-n78

n1

0.3

n28

0.6

n78

0.8

CA_n1-n28-n79

n1

0

n28

0.2

n79

0.5

CA_n1-n38-n78

n1

0.5

n38

0.5

n78

0.8

CA_n1-n40-n78

n1

0.3

n40

0.5

n78

0.8

CA_n1-n41-n77

n1

0.5

n41

0.5

n77

0.8

CA_n1-n77-n79

n1

0.6

n77

0.8

n79

0.5

CA_n1-n78-n79

n1

0.3

n78

0.8

1.57

n79

0.5

1.57

CA_n2-n5-n30

n2

0.5

n5

0.3

n30

0.3

CA_n2-n5-n48

n2

0.6

n5

0.3

n48

0.8

CA_n2-n5-n66

n2

0.5

n5

0.3

n66

0.5

CA_n2-n5-n77

n2

0.6

n5

0.8

n77

0.8

CA_n2-n12-n30

n2

0.5

n12

0.3

n30

0.3

CA_n2-n12-n66

n2

0.5

n12

0.8

n66

0.5

CA_n2-n12-n77

n2

0.6

n12

0.3

n77

0.8

CA_n2-n14-n30

n2

0.5

n14

0.3

n30

0.5

CA_n2-n14-n66

n2

0.5

n14

0.3

n66

0.5

CA_n2-n14-n77

n2

0.5

n14

0.3

n77

0.8

CA_n2-n29-n30

n2

0.5

n30

0.3

CA_n2-n29-n66

n2

0.5

n66

0.5

CA_n2-n29-n77

n2

0.6

n77

0.8

CA_n2-n30-n66

n2

0.5

n30

0.3

n66

0.5

CA_n2-n30-n77

n2

0.6

n30

0.3

n77

0.8

CA_n2-n48-n66

n2

0.6

n48

0.8

n66

0.6

CA_n2-n48-n77

n2

0.6

n48

0.8

n77

0.8

CA_n2-n66-n77

n2

0.6

n66

0.6

n77

0.8

CA_n2-n66-n78

n2

0.6

n66

0.6

n78

0.8

CA_n2-n71-n78

n2

0.6

n71

0.6

n78

0.8

CA_n3-n5-n7

n3

0.5

n5

0.3

n7

0.5

CA_n3-n5-n28

n3

0.3

n5

0.6

n28

0.5

CA_n3-n5-n78

n3

0.6

n5

0.6

n78

0.8

CA_n3-n7-n8

n3

0.5

n7

0.5

n8

0.6

CA_n3-n7-n28

n3

0.5

n7

0.5

n28

0.3

CA_n3-n7-n78

n3

0.6

n7

0.6

n78

0.8

CA_n3-n8-n28

n3

0.3

n8

0.6

n28

0.5

CA_n3-n8-n41

n3

0.5

n8

0.3

n41

0.31

0.82

CA_n3-n8-n77

n3

0.6

n8

0.6

n77

0.8

CA_n3-n8-n79

n3

0.3

n8

0.3

n79

0.5

CA_n3-n8-n78

n3

0.6

n8

0.6

n78

0.8

CA_n3-n18-n28

n3

0.3

n18

0.5

n28

0.3

CA_n3-n18-n41

n3

0.5

n18

0.3

n41

0.31/0.82

CA_n3-n18-n77

n3

0.6

n18

0.3

n77

0.8

CA_n3-n20-n67

n3

0.3

n20

0.5

n67

0.5

CA_n3-n20-n78

n3

0.6

n20

0.6

n78

0.8

CA_n3-n28-n41

n3

0.5

n28

0.3

n41

0.31/0.82

CA_n3-n28-n77

n3

0.6

n28

0.5

n77

0.8

CA_n3-n28-n78

n3

0.5

n28

0.3

n78

0.8

CA_n3-n28-n79

n3

0.3

n28

0.5

n79

0.8

CA_n3A-n38A-n40A

n3

0.5

n38

0.51,3

n40

0.5

CA_n3-n77-n79

n3

0.6

n77

0.8

n79

0

CA_n3-n40-n41

n3

0.5

n40

0.5

n41

0.51,3

0.82,3

CA_n3-n41-n77

n3

0.6

n41

0.31/0.82

n77

0.8

CA_n3-n41-n78

n3

0.6

n41

0.31/0.82

n78

0.8

CA_n3-n41-n79

n3

0.3

n41

0.31

0.82

n79

0.8

CA_n5-n7-n28

n5

0.5

n7

0.3

n28

0.6

CA_n5-n7-n78

n5

0.6

n7

0.6

n78

0.8

CA_n5-n12-n77

n5

0.8

n12

0.4

n77

0.5

CA_n5-n14-n77

n5

0.5

n14

0.3

n77

0.8

CA_n5-n25-n66

n5

0.3

n25

0.5

n66

0.5

CA_n5-n25-n77

n5

0.6

n25

0.6

n77

0.8

CA_n5-n25-n78

n5

0.6

n25

0.6

n78

0.8

CA_n5-n29-n77

n5

0.8

n77

0.5

CA_n5-n30-n66

n5

0.3

n30

0.3

n66

0.5

CA_n5-n30-n77

n5

0.6

n30

0.3

n77

0.8

CA_n5-n40-n78

n5

0.6

n40

0.5

n78

0.8

CA_n5-n48-n66

n5

0.3

n48

0.8

n66

0.6

CA_n5-n48-n77

n5

0.6

n48

0.8

n77

0.8

CA_n5-n66-n77

n5

0.6

n66

0.6

n77

0.8

CA_n5_n66-n78

n5

0.6

n66

0.6

n78

0.8

CA_n7-n8-n28

n7

0.3

n8

0.6

n28

0.5

CA_n7-n8-n40

n7

0.5

n8

0.6

n40

0.6

CA_n7-n8-n78

n7

0.5

n8

0.6

n78

0.8

CA_n7_n25-n66

n7

0.5

n25

0.5

n66

0.5

CA_n7-n25-n77

n7

0.5

n25

0.6

n77

0.8

CA_n7-n25-n78

n7

0.5

n25

0.6

n78

0.8

CA_n7_n28-n78

n7

0.3

n28

0.3

n78

0.8

CA_n7-n46-n78

n7

0.5

n46

0

n78

0.8

CA_n7-n66-n77

n7

0.5

n66

0.6

n77

0.8

CA_n7_n66-n78

n7

0.5

n66

0.6

n78

0.8

CA_n8-n28-n78

n8

0.6

n28

0.5

n78

0.8

CA_n8A-n38A-n40A

n8

0.3

n38

0.3

n40

0.3

CA_n8-n39-n41

n8

0.6

n39

0.54

n41

0.54

CA_n8-n39-n79

n8

0.3

n39

0.3

n79

0

CA_n8-n40-n41

n8

0.3

n40

0.33

n41

0.33

CA_n8A-n40A-n78A

n8

0.6

n40

0.3

n78

0.8

CA_n8-n41-n79

n8

0.6

n41

0.3

n79

0.8

CA_n8-n78-n79

n8

0.6

n78

0.8

n79

0.8

CA_n12-n30-n66

n12

0.8

n30

0.3

n66

0.5

CA_n12-n30-n77

n12

0.5

n30

0.3

n77

0.5

CA_n12-n66-n77

n12

0.8

n66

0.6

n77

0.8

CA_n13-n25-n66

n13

0.3

n25

0.5

n66

0.5

CA_n13-n25-n77

n13

0.3

n25

0.6

n77

0.8

CA_n13-n66-n77

n13

0.5

n66

0.6

n77

0.8

CA_n14-n30-n66

n14

0.3

n30

0.3

n66

0.5

CA_n14-n30-n77

n14

0.5

n30

0.3

n77

0.8

CA_n14-n66-n77

n14

0.6

n66

0.6

n77

0.8

CA_n18-n28-n41

n18

0.4

n28

0.4

n41

0.3

CA_n18-n28-n77

n18

0.5

n28

0.5

n77

0.8

CA_n18-n41-n77

n18

0.3

n41

0.3

n77

0.8

CA_n20-n28-n78

n20

0.6

n28

0.5

n78

0.8

CA_n24-n41-n48

n24

0.6

n41

0.41

0.92

n48

0.8

CA_n24-n41-n77

n24

0.6

n41

0.45

0.96

n77

0.8

CA_n24-n48-n77

n24

0.6

n48

0.8

n77

0.8

CA_n25-n29-n66

n25

0.5

n29

0

n66

0.5

CA_n25-n38-n78

n25

0.5

n38

0.4

n78

0.8

CA_n25-n41-n66

n25

0.5

n41

0.85

1.36

n66

0.5

CA_n25-n41-n71

n25

0.5

n41

0.5

n71

0.6

CA_n25-n41-n77

n25

0.5

n41

0.5

n77

0.6

CA_n25-n41-n78

n25

0.6

n41

0.5

n78

0.8

CA_n25-n48-n66

n25

0.6

n48

0.8

n66

0.6

CA_n25-n66-n71

n25

0.5

n66

0.5

n71

0.6

CA_n25-n66-n77

n25

0.6

n66

0.6

n77

0.8

CA_n25-n66-n78

n25

0.6

n66

0.6

n78

0.8

CA_n25-n71-n77

n25

0.6

n71

0.6

n77

0.8

CA_n25-n71-n78

n25

0.6

n71

0.6

n78

0.8

CA_n26-n66-n70

n26

0.3

n66

0.5

n70

0.5

CA_n28-n38-n78

n28

0.5

n38

0.3

n78

0.8

CA_n28-n39-n40

n28

0.3

n39

0.3

n40

0.3

CA_n28-n39-n41

n28

0.3

n39

0.5

n41

0.5

CA_n28-n39-n79

n28

0.5

n39

0.3

n79

0.8

CA_n28-n40-n41

n28

0.3

n40

0.5

n41

0.5

CA_n28-n40-n78

n28

0.5

n40

0.3

n78

0.8

CA_n28-n40-n79

n28

0.5

n40

0.3

n79

0.8

CA_n28-n41-n79

n28

0.5

n41

0.3

n79

0.8

CA_n28-n41-n77

n28

0.5

n41

0.3

n77

0.8

CA_n28-n41-n78

n28

0.5

n41

0.3

n78

0.8

CA_n28-n46-n78

n28

0.5

n46

0

n78

0.8

CA_n28-n77-n79

n28

0.5

n77

0.8

n79

0.5

CA_n28-n78-n79

n28

0.5

n78

0.8

1.57

n79

0.5

1.57

CA_n29-n30-n66

n30

0.3

n66

0.5

CA_n29-n30-n77

n30

0.3

n77

0.5

CA_n29-n66-n70

n29

0

n66

0.5

n70

0.5

CA_n29-n66-n77

n66

0.6

n77

0.8

CA_n30-n66-n77

n30

0.3

n66

0.6

n77

0.8

CA_n38-n66-n78

n38

0.5

n66

0.5

n78

0.8

CA_n39-n40-n41

n39

0.3

n40

0.3

n41

0.3

CA_n39-n40-n79

n39

0.3

n40

0

n79

0.8

CA_n39-n41-n79

n39

0.3

n41

0.34

n79

0.84

CA_n40-n41-n79

n40

0.53

n41

0.53

n79

0.8

CA_n41-n66-n71

n41

0.85

1.36

n66

0.5

n71

0.3

CA_n41-n66-n77

n41

0.5

n66

0.6

n77

0.8

CA_n41-n66-n78

n41

0.5

n66

0.6

n78

0.8

CA_n41-n70-n78

n41

0.6

n70

0.6

n78

0.8

CA_n41-n71-n77

n41

0.3

n71

0.5

n77

0.8

CA_n41-n71-n78

n41

0.3

n71

0.5

n78

0.8

CA_n46-n48-n96

n46

0.5

n48

0.8

n96

0.6

CA_n48-n66-n70

n48

0.8

n66

0.6

n70

0.6

CA_n48-n66-n71

n48

0.5

n66

0.5

n71

0.3

CA_n48-n66-n77

n48

0.8

n66

0.6

n77

0.8

CA_n48-n70-n71

n48

0.5

n70

0.5

n71

0.3

CA_n66-n70-n71

n66

0.5

n70

0.5

n71

0.6

CA_n66-n71-n77

n66

0.6

n71

0.6

n77

0.8

CA_n66-n71-n78

n66

0.6

n71

0.5

n78

0.8

NOTE 1: The requirement is applied for UE transmitting on the frequency range of 2515-2690 MHz.

NOTE 2: The requirement is applied for UE transmitting on the frequency range of 2496-2515 MHz.

NOTE 3: Only applicable for UE supporting inter-band carrier aggregation without simultaneous Rx/Tx among band 40 and 41.

NOTE 4: Applicable for UE supporting inter-band carrier aggregation without simultaneous Rx/Tx between n39 and n41.

NOTE 5: The requirement is applied for UE transmitting on the frequency range of 2545 – 2690 MHz.

NOTE 6: The requirement is applied for UE transmitting on the frequency range of 2496 – 2545 MHz.

NOTE 7: The requirements only apply for UE supporting inter-band carrier aggregation with simultaneous Rx/Tx capability, and NR UL carrier frequencies are confined to 3700 MHz-3800MHz for n78 and 4400 MHz-4500MHz for n79. Simultaneous Rx/Tx capability does not apply for UEs supporting band n78 with a n77 implementation.

6.2A.4.2.5 ΔTIB,c for Inter-band CA (four bands)

Table 6.2A.4.2.5-1: ΔTIB,c due to NR CA (four bands)

Inter-band CA combination

NR Band

ΔTIB,c (dB)

CA_n1-n3-n5-n7

n1

0.6

n3

0.6

n5

0.3

CA_n1-n3-n5-n78

n1

0.6

n3

0.6

n5

0.3

n78

0.8

CA_n1-n3-n7-n28

n1

0.6

n3

0.6

n7

0.6

n28

0.6

CA_n1-n3-n7-n78

n1

0.7

n3

0.7

n7

0.7

n78

0.8

CA_n1-n3-n8-n78

n1

0.6

n3

0.6

n8

0.6

n78

0.8

CA_n1-n3-n8-n77

n1

0.6

n3

0.6

n8

0.6

n77

0.8

CA_n1-n3-n18-n28

n1

0.3

n3

0.3

n18

0.5

n28

0.5

CA_n1-n3-n18-n41

n1

0.5

n3

0.5

n18

0.3

n41

0.33

0.84

CA_n1-n3-n18-n77

n1

0.6

n3

0.6

n18

0.3

n77

0.8

CA_n1-n3-n28-n41

n1

0.5

n3

0.5

n28

0.5

n41

0.33

0.84

CA_n1-n3-n28-n77

n1

0.6

n3

0.6

n28

0.6

n77

0.8

CA_n1-n3-n28-n78

n1

0.6

n3

0.6

n28

0.6

n78

0.8

CA_n1-n3-n28-n79

n1

0.3

n3

0.3

n28

0.6

n79

0.8

CA_n1-n3-n41-n77

n1

0.6

n3

0.6

n41

0.33

0.84

n77

0.8

CA_n1-n3-n77-n79

n1

0.6

n3

0.6

n77

0.8

n79

0.8

CA_n1-n5-n7-n78

n1

0.6

n5

0.6

n7

0.6

n78

0.8

CA_n1-n7-n8-n40

n1

0.6

n7

0.8

n8

0.6

n40

0.9

CA_n1-n7-n8-n78

n1

0.6

n7

0.6

n8

0.6

n78

0.8

CA_n1-n7-n28-n78

n1

0.6

n7

0.6

n28

0.6

n78

0.8

CA_n1-n7-n40-n78

n1

0.6

n7

0.5

n40

0.5

n78

0.8

CA_n1-n8-n40-n78

n1

0.5

n8

0.3

n40

0.5

n78

0.8

CA_n1-n8-n78-n79

n1

0.3

n8

0.6

n78

0.8

n79

0.5

CA_n1-n18-n28-n41

n1

0.6

n18

0.5

n28

0.6

n41

0.5

CA_n1-n18-n28-n77

n1

0.6

n18

0.5

n28

0.6

n77

0.8

CA_n1-n18-n41-n77

n1

0.5

n18

0.5

n41

0.5

n77

0.8

CA_n1-n28-n40-n78

n1

0.3

n28

0.6

n40

0.5

n78

0.8

CA_n1-n28-n41-n77

n1

0.6

n28

0.6

n41

0.6

n77

0.8

CA_n1-n28-n77-n79

n1

0.6

n28

0.6

n77

0.8

n79

0.8

CA_n2-n5-n30-n66

n2

0.5

n5

0.3

n30

0.3

n66

0.5

CA_n2-n5-n30-n77

n2

0.6

n5

0.6

n30

0.3

n77

0.8

CA_n2-n5-n48-n66

n2

0.6

n5

0.3

n48

0.8

n66

0.6

CA_n2-n5-n48-n77

n2

0.6

n5

0.3

n48

0.8

n77

0.8

CA_n2-n5-n66-n77

n2

0.5

n5

0.3

n66

0.5

n77

0.8

CA_n2-n12-n30-n66

n2

0.5

n12

0.8

n30

0.3

n66

0.5

CA_n2-n12-n30-n77

n2

0.6

n12

0.5

n30

0.3

n77

0.8

CA_n2-n12-n66-n77

n2

0.6

n12

0.8

n66

0.6

n77

0.8

CA_n2-n14-n30-n66

n2

0.5

n14

0.3

n30

0.3

n66

0.5

CA_n2-n14-n30-n77

n2

0.6

n14

0.5

n30

0.3

n77

0.8

CA_n2-n14-n66-n77

n2

0.6

n14

0.6

n66

0.6

n77

0.8

CA_n2-n29-n30-n66

n2

0.5

n30

0.3

n66

0.5

CA_n2-n29-n30-n77

n2

0.6

n30

0.3

n77

0.8

CA_n2-n29-n66-n77

n2

0.6

n66

0.6

n77

0.8

CA_n2-n48-n66-n77

n2

0.6

n48

0.8

n66

0.6

n77

0.8

CA_n2-n66-n71-n78

n2

0.5

n66

0.5

n71

0.3

n78

0.5

CA_n3-n5-n7-n78

n3

0.6

n5

0.6

n7

0.6

n78

0.8

CA_n3-n7-n28-n78

n3

0.6

n7

0.6

n28

0.6

n78

0.6

CA_n3-n18-n28-n41

n3

0.5

n18

0.4

n28

0.4

n41

0.33

0.84

CA_n3-n18-n28-n77

n3

0.6

n18

0.5

n28

0.5

n77

0.8

CA_n3-n18-n41-n77

n3

0.6

n18

0.4

n41

0.33

0.84

n77

0.8

CA_n3-n28-n41-n77

n3

1

n28

0.5

n41

0.31/0.82

n77

0.8

CA_n3-n28-n41-n78

n3

1

n28

0.5

n41

0.31/0.82

n78

0.8

CA_n3-n28-n77-n79

n3

0.6

n28

0.5

n77

0.8

n79

0.8

CA_n5-n25-n66-n77

n5

0.6

n25

0.6

n66

0.6

n77

0.8

CA_n5-n25-n66-n78

n5

0.6

n25

0.6

n66

0.6

n78

0.8

CA_n5-n30-n66-n77

n5

0.6

n30

0.3

n66

0.6

n77

0.8

CA_n5-n48-n66-n77

n5

0.6

n48

0.8

n66

0.6

n77

0.8

CA_n7-n8-n40-n78

n7

0.5

n8

0.3

n40

0.5

n78

0.8

CA_n7-n25-n66-n77

n7

0.5

n25

0.6

n66

0.6

n77

0.8

CA_n7-n25-n66-n78

n7

0.5

n25

0.6

n66

0.6

n78

0.8

CA_n12-n30-n66-n77

n12

0.8

n30

0.3

n66

0.6

n77

0.8

CA_n13-n25-n66-n77

n13

0.5

n25

0.6

n66

0.6

n77

0.8

CA_n14-n30-n66-n77

n14

0.6

n30

0.3

n66

0.6

n77

0.8

CA_n18-n28-n41-n77

n18

0.5

n28

0.5

n41

0.33

0.84

n77

0.8

CA_n25-n38-n66-n78

n25

0.6

n38

0.6

n66

0.6

n78

0.8

CA_n25-n41-n66-n71

n25

0.5

n41

0.5

n66

0.5

n71

0.3

CA_n25-n41-n66-n77

n25

0.5

n41

0.83/1.34

n66

0.5

n77

0.8

CA_n25-n41-n66-n78

n25

0.5

n41

0.83/1.34

n66

0.5

n78

0.8

CA_n25-n41-n71-n77

n25

0.5

n41

0.5

n71

0.6

n77

0.8

CA_n25-n41-n71-n78

n25

0.5

n41

0.5

n71

0.6

n78

0.8

CA_n25-n66-n71-n77

n25

0.5

n66

0.5

n71

0.6

n77

0.8

CA_n25-n66-n71-n78

n25

0.6

n66

0.6

n71

0.6

n78

0.8

CA_n29-n30-n66-n77

n30

0.3

n66

0.6

n77

0.8

CA_n41-n66-n70-n78

n41

0.5

n66

0.6

n70

0.6

n78

0.8

CA_n41-n66-n71-n77

n41

0.33/0.84

n66

1

n71

0.5

n77

0.8

CA_n41-n66-n71-n78

n41

0.33/0.84

n66

1

n71

0.5

n78

0.8

NOTE 1: Applicable for the frequency range of 2515-2690 MHz.

NOTE 2: Applicable for the frequency range of 2496-2515 MHz

NOTE 3: The requirement is applied for UE transmitting on the frequency range of 2545 – 2690 MHz.

NOTE 4: The requirement is applied for UE transmitting on the frequency range of 2496 – 2545 MHz

6.2A.4.2.6 ΔTIB,c for Inter-band CA (five bands)

Table 6.2A.4.2.6-1: ΔTIB,c due to NR CA (five bands)

Inter-band CA combination

NR Band

ΔTIB,c (dB)

CA_n1-n3-n5-n7-n78

n1

0.6

n3

0.6

n5

0.6

n7

0.6

n78

0.8

CA_n1-n3-n7-n28-n78

n1

0.7

n3

0.7

n7

0.7

n28

0.6

n78

0.8

CA_n2-n5-n48-n66-n77

n2

0.6

n5

0.3

n48

0.8

n66

0.6

n77

0.8