Inserting virtual carrier in conventional OFDM host carrier in communications system

The invention claimed is: 1. A base station, comprising: processing circuitry configured to communicate with a first mobile terminal of a first type and a second mobile terminal of a second type; receive, from the first mobile terminal, first uplink data on a first group of sub-carriers of a plurality of sub-carriers over a first bandwidth; receive, from the second mobile terminal, second uplink data on a second group of sub-carriers of the plurality of sub-carriers, wherein the second group of sub-carriers is within the first group of sub-carriers over a second bandwidth, the second bandwidth is smaller than the first bandwidth, the second group of sub-carriers form a virtual carrier inserted within the first bandwidth, a remaining plurality of the sub-carriers of the first group of sub-carriers excluding the second group of sub-carriers form a host carrier, terminals of the first type communicate via the host carrier and terminals of the second type communicate via the virtual carrier, a single physical random access channel (PRACH) resource is located on the host carrier, a first time slot in the single PRACH resource is allocated for access to terminals of the first type that communicate via the host carrier, and a second time slot, different from the first time slot, in the single PRACH resource is allocated for access to terminals of the second type that communicate via the virtual carrier; receive, on a sub-carrier of the single PRACH resource located on the host carrier, a random access request message requesting uplink radio resources; allocate resources within the host carrier to the terminal in response to and based on the random access request message being received in the first time slot; and allocate resources within the virtual carrier to the terminal in response to and based on the random access request message being received in the second time slot. 2. The base station according to claim 1 , wherein the processing circuitry is further configured to transmit a signal indicating a position of the single PRACH resource on a downlink signaling channel. 3. The base station according to claim 1 , wherein the base station is arranged in accordance with 3GPP Long Term Evolution specifications. 4. The base station according to claim 1 , wherein the processing circuitry is configured to receive the random access request message on the single PRACH resource in accordance with an allocation of the single PRACH resource, the allocation comprising a time period common to a plurality of mobile terminals of the second type and differing from an allocation for another mobile terminal of the first type. 5. The base station according to claim 1 , wherein the random access request message comprises one of a first plurality of random access preambles, the first plurality of random access preambles being commonly allocated to a plurality of mobile terminals of the second type and differing from a second plurality of preambles for use by a mobile terminal of the first type. 6. The base station according to claim 1 , wherein the processing circuitry is further configured to transmit first downlink data on a third group of sub-carriers of the plurality of sub-carriers over a third bandwidth; and transmit second downlink data on a fourth group of sub-carriers over a fourth bandwidth of the plurality of sub-carriers, the fourth bandwidth is different than the second bandwidth, the fourth bandwidth is smaller than the third bandwidth, and the fourth group of sub-carriers is within the third group of sub-carriers. 7. A base station, comprising: processing circuitry configured to communicate with a first mobile terminal of a first type and a second mobile terminal of a second type; receive, from the first mobile terminal, first uplink data on a first group of sub-carriers of a plurality of sub-carriers over a first bandwidth; receive, from the second mobile terminal, second uplink data on a second group of sub-carriers of the plurality of sub-carriers, wherein the second group of sub-carriers is within the first group of sub-carriers over a second bandwidth, the second bandwidth is smaller than the first bandwidth, the second group of sub-carriers form a virtual carrier inserted within the first bandwidth, a remaining plurality of the sub-carriers of the first group of sub-carriers excluding the second group of sub-carriers form a host carrier, terminals of the first type communicate via the host carrier and terminals of the second type communicate via the virtual carrier, a single physical random access channel (PRACH) resource is located on the host carrier, a first time slot in the single PRACH resource is allocated for access to terminals of the first type that communicate via the host carrier, and a second time slot, different from the first time slot, in the single PRACH resource is allocated for access to terminals of the second type that communicate via the virtual carrier; receive, on a sub-carrier of the single PRACH resource located on the host carrier, a random access request message requesting uplink radio resources; allocate resources within the virtual host carrier to the terminal in response to and based on the random access request message being received in the first time slot; and allocate resources within the virtual carrier in response to and based on the random access request message being received in the second time slot. 8. The base station according to claim 7 , wherein the processing circuitry is further configured to transmit a signal indicating a position of the single PRACH resource on a downlink signaling channel. 9. The base station according to claim 7 , wherein the base station is arranged in accordance with 3GPP Long Term Evolution specifications. 10. The base station according to claim 7 , wherein the random access request message is transmitted on a same group of sub-carriers of the first group of sub-carriers and at a same time as random access request messages transmitted on the single PRACH resource by another mobile terminal of the first type. 11. The base station according to claim 7 , wherein the processing circuitry is configured to receive the random access request message on the single PRACH resource in accordance with an allocation of the single PRACH resource, the allocation comprising a time period common to a plurality of mobile terminals of the second type and differing from an allocation for another mobile terminal of the first type. 12. The base station according to claim 7 , wherein the random access request message comprises one of a first plurality of random access preambles, the first plurality of random access preambles being commonly allocated to a plurality of mobile terminals of the second type and differing from a second plurality of preambles for use by a mobile terminal of the first type. 13. The base station according to claim 7 , wherein the processing circuitry is further configured to transmit first downlink data on a third group of sub-carriers of the plurality of sub-carriers over a third bandwidth; and transmit second downlink data on a fourth group of sub-carriers over a fourth bandwidth of the plurality of sub-carriers, the fourth bandwidth is different than the second bandwidth, the fourth bandwidth is smaller than the third bandwidth, and the fourth group of sub-carriers is within the third group of sub-carriers. 14. A method for a base station, the method comprising: communicating, by processing circuitry of the base station, with a first mobile terminal of a first type and a second mobile terminal of a second type;