Methods for efficient use of unlicensed spectrum

The invention claimed is: 1. A method performed by a transmit node to perform a transmission in a frequency spectrum requiring Listen-Before-Talk, LBT, comprising: performing an LBT procedure for a plurality of channels each comprising a group of contiguous Physical Resource Blocks (PRBs) within a transmit bandwidth of the transmit node to thereby determine a subset of the plurality of channels that are available for transmission, wherein resources in the group of contiguous PRBs are divided into a plurality of interlaces; and transmitting a transmission using at least one of the plurality of interlaces in a subset of the resources that correspond to the subset of the plurality of channels determined to be available, wherein the transmitting comprises one of: transmitting the transmission concurrently on the subset of the plurality of channels independent of whether the subset of the plurality of channels is adjacent; merging at least two adjacent channels among the subset of the plurality of channels into a merged channel and transmitting the transmission on the merged channel; and merging the at least two adjacent channels among the subset of the plurality of channels into the merged channel and transmitting the transmission concurrently on the merged channel and at least one of the subset of the plurality of channels non-adjacent to the merged channel. 2. The method of claim 1 wherein the subset of the plurality of channels comprises at least two channels. 3. The method of claim 1 wherein the subset of the plurality of channels comprises at least two adjacent channels from the plurality of channels, and transmitting the transmission using the at least one of the plurality of interlaces comprises transmitting the transmission in at least two adjacent resources that correspond to the at least two adjacent channels. 4. The method of claim 3 wherein the merging the at least two adjacent channels utilizes at least some resources in at least one guard band between the at least two adjacent resources. 5. The method of claim 1 wherein the subset of the resources used for the transmission comprise a first resource that is adjacent to a second resource wherein the first and second resources are separated by a guard band, and resources in the guard band that are allocated for the at least one of the plurality of interlaces used for the transmission are also used for the transmission. 6. The method of claim 1 wherein a central frequency for at least one resource is offset such that there is subcarrier level alignment between two or more interlaces in the plurality of interlaces. 7. The method of claim 1 wherein a central frequency for at least one resource is offset such that there is physical resource block level alignment between two or more interlaces in the plurality of interlaces. 8. The method of claim 7 wherein an index of interlaces in each resource are cyclic-shifted such that physical resource blocks of a same interlace in all resources are uniformly distributed. 9. The method of claim 1 wherein the transmit node is a User Equipment, UE, and the transmission is an uplink transmission. 10. A transmit node for performing a transmission in a frequency spectrum requiring Listen-Before-Talk, LBT, comprising: one or more transmitters; and processing circuitry associated with the one or more transmitters, the processing circuitry configured to cause the transmit node to: perform an LBT procedure for a plurality of channels each comprising a group of contiguous Physical Resource Blocks (PRBs) within a transmit bandwidth of the transmit node to thereby determine a subset of the plurality of channels that are available for transmission, wherein resources in the group of contiguous PRBs are divided into a plurality of interlaces; and transmit a transmission using at least one of the plurality of interlaces in a subset of the resources that correspond to the subset of the plurality of channels determined to be available, wherein transmitting the transmission comprises one of: transmit the transmission concurrently on the subset of the plurality of channels independent of whether the subset of the plurality of channels is adjacent; merge at least two adjacent channels among the subset of the plurality of channels into a merged channel and transmitting the transmission on the merged channel; and merge at least two adjacent channels among the subset of the plurality of channels into a merged channel and transmitting the transmission on the merged channel; and merging the at least two adjacent channels among the subset of the plurality of channels into the merged channel and transmitting the transmission concurrently on the merged channel and at least one of the subset of the plurality of channels non-adjacent to the merged channel. 11. The transmit node of claim 10 wherein the subset of the plurality of channels comprises at least two channels. 12. The transmit node of claim 10 wherein the subset of the plurality of channels comprises at least two adjacent channels from the plurality of channels, and the transmission is transmitted using the at least one of the plurality of interlaces comprises transmitting the transmission in at least two adjacent resources that correspond to the at least two adjacent channels. 13. The transmit node of claim 12 wherein the merging the at least two adjacent channels utilizes at least some resources in at least one guard band between the at least two adjacent resources. 14. The transmit node of claim 10 wherein the subset of the resources used for the transmission comprise a first resource that is adjacent to a second resource wherein the first and second resources are separated by a guard band, and resources in the guard band that are allocated for the at least one of the plurality of interlaces used for the transmission are also used for the transmission. 15. The transmit node of claim 10 wherein a central frequency for at least one resource is offset such that there is subcarrier level alignment between two or more interlaces in the plurality of interlaces. 16. The transmit node of claim 10 wherein a central frequency for at least one resource is offset such that there is physical resource block level alignment between two or more interlaces in the plurality of interlaces. 17. The transmit node of claim 16 wherein an index of interlaces in each resource are cyclic-shifted such that physical resource blocks of a same interlace in all resources are uniformly distributed. 18. The transmit node of claim 10 wherein the transmit node is a User Equipment, UE, and the transmission is an uplink transmission.