20 Four Carrier HSDPA Operation (FDD only)

25.3083GPPHigh Speed Downlink Packet Access (HSDPA)Overall descriptionRelease 17Stage 2TS

Four Carrier HSDPA operation is characterized as simultaneous reception of up to four HS-DSCH transport channels. Certain categories of UEs may be configured with Four Carrier HSDPA operation with or without MIMO/MIMO mode with four transmit antennas in CELL_DCH state. Four Carrier HSDPA operation may be activated and deactivated using HS-SCCH orders.

When the UE is configured with Four Carrier HSDPA operation, a common transmitting MAC-ehs entity is used for data transmission, and the HS-DSCH channels shall be operated in the following manner:

– The transmitting and receiving MAC-ehs entity support up to four HS-DSCH transport channels.

– Each of these HS-DSCH transport channels has its own associated uplink and downlink signalling, and own HARQ entity (further composed of multiple HARQ processes).

– Reordering, duplicate detection, segmentation and reassembly functions are joint for these HS-DSCH transport channels and HARQ entities.

When the UE is configured with Four Carrier HSDPA operation:

– There is one serving HS-DSCH cell and up to three secondary serving HS-DSCH cells.

– The TSN field in the MAC-ehs header is extended to 14 contiguous bits.

– The mobility procedures, as defined in section 9, are supported based on the serving HS-DSCH cell. A serving cell change similar to the one shown in Figure 18-1 is possible for Four Carrier HSDPA operation.

– The DRX status is common for all serving HS-DSCH cells. The DRX activation and deactivation is possible with HS-SCCH orders.

– HS-SCCH-less operation is restricted to the serving HS-DSCH cell.

– Transmit diversity is configurable per downlink frequency.

– Certain categories of UEs may be configured to operate in MIMO mode or MIMO mode with four transmit antennas per serving HS-DSCH cell, as follows:

– MIMO operation per serving HS-DSCH cell is performed as per section 13.

– MIMO mode with four transmit antennas operation per serving HS-DSCH cell is performed as per section 13c.

– HS-DPCCH is be used to carry feedback information (ACK/NACK, CQI and precoding control information) related to the HS-DSCH transport channels.

– CQI reports related to all activated serving HS-DSCH cells are transmitted

– The maximum number of MAC-ehs PDUs per TTI is 12, when three serving HS-DSCH cells are active. The maximum number of MAC-ehs PDUs per TTI is 16, when four serving HS-DSCH cells are active.

– Certain categories of UEs may be configured to operate in multiple radio frequency as follows:

– The UE is configured with up to four HS-DSCH transport channels which are carried over 1 or 2 radio frequency bands.

– The downlink frequencies within a single frequency band are configured adjacent or non-adjacent if UE supports non-contiguous multi-cell operation. Non-adjacent operation of downlink frequencies due to the deactivation of the configured downlink frequencies within a single frequency band may take place. A UE may be configured with non-adjacent downlink frequencies within a single frequency band with MIMO when the UE has signalled support for this combination.

– Four Carrier HSDPA operation may be configured with Dual Cell E-DCH operation, as described in [3]. DCH is supported if the UE has only one Configured Uplink frequency.

– Synchronization and RLF:

– For physical channel establishment for the downlink frequencies associated with an Activated Uplink Frequency, the rules as specified for Dual Cell E-DCH operation are applied.

– Physical channel establishment is not performed for the downlink frequencies not associated with an Activated Uplink Frequency.

– RLF is based on the primary downlink frequency.

– Measurements:

– If only one uplink frequency is configured, the UE performs intra-frequency measurement only on the primary downlink frequency.

– If two uplink frequencies are configured, the UE performs intra-frequency measurement on the corresponding primary downlink frequency and secondary downlink frequency.