Method and arrangement for user equipment switching between carriers in different frequency bands

The invention claimed is: 1. A method for controlling a user equipment in a multi-carrier communication network, the multi-carrier communication network comprising at least one base station, the user equipment comprising a radio interface adapted to communicate via a plurality of frequency bands, wherein the radio interface is configured with a first downlink carrier and with a first uplink carrier in a first frequency band and with a second downlink carrier and with a second uplink carrier in a second, different, frequency band, the method comprising causing the user equipment to: schedule the radio interface to receive data via the first downlink carrier and to transmit data via the first uplink carrier while maintaining association with both the first and the second downlink carriers and both the first and the second uplink carriers; monitor the first downlink carrier for a scheduling signal for the second downlink carrier and the second uplink carrier; and responsive to receipt of the scheduling signal, use the scheduling signal to cause the radio interface to receive data via the second downlink carrier and to transmit data via the second uplink carrier, and monitor for a further scheduling signal for the first downlink carrier and the first uplink carrier to cause the radio interface to receive data via the first downlink carrier and to transmit data via the first uplink carrier while maintaining an active communication connection with both the first and the second downlink carriers and both the first and the second uplink carriers to permit automatic switching between the first and the second downlink carriers and the first and the second uplink carriers. 2. The method according to claim 1 , wherein the scheduling signal is received via a High Speed Shared Control Channel (HS-SCCH) order, or via a Transport Format Resource Combination (TFRC) signaling message. 3. The method according to claim 1 , wherein the scheduling signal received by the user equipment is indicative of an instruction to transmit and receive data via the second frequency band. 4. The method according to claim 1 , the method comprising sending an acknowledgement (ACK) before any downlink data is received via the second downlink carrier. 5. A user equipment configured to communicate in a multi-carrier communication network, the multi-carrier communication network comprising at least one base station, the user equipment comprising a radio interface adapted to communicate via a plurality of frequency bands, wherein the radio interface is configured with a first downlink carrier and with a first uplink carrier in a first frequency band and with a second downlink carrier and with a second uplink carrier in a second, different, frequency band, the user equipment comprising a processor and at least one memory, wherein the processor and the at least one memory are configured to cause the user equipment to at least: schedule the radio interface to receive data via the first downlink carrier and to transmit data via the first uplink carrier while maintaining association with both the first and the second downlink carriers and both the first and the second uplink carriers; monitor the first downlink carrier for a scheduling signal for the second downlink carrier and the second uplink carrier; and responsive to receipt of the scheduling signal, use the scheduling signal to cause the radio interface to receive data via the second downlink carrier and to transmit data via the second uplink carrier, and monitor for a further scheduling signal for the first downlink carrier and the first uplink carrier to cause the radio interface to receive data via the first downlink carrier and to transmit data via the first uplink carrier while maintaining an active communication connection with both the first and the second downlink carriers and both the first and the second uplink carriers to permit automatic switching between the first and the second downlink carriers and the first and the second uplink carriers. 6. The user equipment according to claim 5 , wherein the scheduling signal is received via a High Speed Shared Control Channel (HS-SCCH) order, or via a Transport Format Resource Combination (TFRC) signaling message. 7. The user equipment according to claim 5 , wherein the received scheduling signal is indicative of an instruction to transmit and receive data via the second frequency band. 8. The user equipment according to claim 5 , wherein the processor and the at least one memory are configured to cause transmission of an acknowledgement (ACK) before any downlink data is received via the second downlink carrier. 9. A non-transitory computer-readable storage medium having computer-readable instructions stored thereon for controlling a user equipment in a multi-carrier communication network, the multi-carrier communication network comprising at least one base station, the user equipment comprising a radio interface adapted to communicate via a plurality of frequency bands, wherein the radio interface is configured with a first downlink carrier and with a first uplink carrier in a first frequency band and with a second downlink carrier and with a second uplink carrier in a second, different, frequency band, the computer-readable instructions, when executed by the user equipment, cause the user equipment to perform the steps of: scheduling the radio interface to receive data via the first downlink carrier and to transmit data via the first uplink carrier while maintaining association with both the first and the second downlink carriers and both the first and the second uplink carriers; monitoring the first downlink carrier for a scheduling signal for the second downlink carrier and the second uplink carrier; and responsive to receipt of the scheduling signal, using the scheduling signal to cause the radio interface to receive data via the second downlink carrier and to transmit data via the second uplink carrier, and monitoring for a further scheduling signal for the first downlink carrier and the first uplink carrier to cause the radio interface to receive data via the first downlink carrier and to transmit data via the first uplink carrier while maintaining an active communication connection with both the first and the second downlink carriers and both the first and the second uplink carriers to permit automatic switching between the first and the second downlink carriers and the first and the second uplink carriers.