...
- Distribute sufficiently many UEs randomly throughout the system area such that to each cell within the HO margin of 3 dB the same number K of users is allocated as active UEs
- Calculate the pathloss from each UE to all cells and find the smallest pathloss
- Link the UE randomly to a cell to which the pathloss is within the smallest pathloss plus the HO margin of 3 dB
- Select K UEs randomly from all the UEs linked to one cell as active UEs. These K active UEs will be scheduled during this snapshot
- Note: a full load system is assumed by default, namely, all available RBs will be allocated to active UEs. And each UE is scheduled with the same number N of RBs. This behaviour can be overridden (see 9.3.6) and the system can be partially loaded, each UE is still scheduled with the same number (
) of RBs.Mathinline body $N$
- Perform UL power control
- Calculate UL C/I for all active UEs in all cells.
- Loop over all cells from j=1 to
toUnit body $j=1$
(the number of cells in the system area e.g. 57 for 19 sites with tri-sector antennas)Unit body ${{N}_{cell}}$ - Loop over all active UEs from k=1 to K
toUnit body $k=1$ Unit body $K$ - For the k-th active UE in the j-th cell (i.e. UE_
) its C/I is denoted byUnit body $U{{E}_{j,k}}$ 
Unit body $\frac{C(j,k)}{I(j,k)}$
.Unit body $k=1$ to $K$
- Loop over all cells from j=1 to
Determine the throughput for each UE with its C/I according to the link-to-system level mapping.
Collect statistics.