A8.2.1 Case 1: No overlap
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Figure 384: iRSS_blocking case 1: no overlap
where:
lower: offset - BWILT/2 – emission mask asymmetry[1]
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A8.2.2 Case 2: Partial overlap with fILT > fVLR
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Figure 385: iRSS_blocking case 2: partial overlap with fILT > fVLR
Note: the blue coloured range is covered by the iRSS_unwanted calculation and therefore not taken into account in the iRSS_blocking calculation.
where:
lower: BWVLR/2
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A8.2.3 Case 3: Partial overlap with fILT < fVLR
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Figure 386: iRSS_blocking case 3: partial overlap with fILT < fVLR
Note: the blue coloured range is covered by the iRSS_unwanted calculation and therefore not taken into account in the iRSS_blocking calculation.
where:
upper: - BWVLR/2
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A8.2.4 Case 4: Total overlap with BWVLR < BWILT
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Figure 387: iRSS_blocking case 4: Total overlap with BWVLR < BWILT
Note: the blue coloured range is covered by the iRSS_unwanted calculation and therefore not taken into account in the iRSS_blocking calculation.
where:
lower: offset - BWILT/2 – emission mask asymmetry
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A8.2.5 Case 5: total overlap with BWVLR > BWILT
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Figure 388: iRSS_blocking case 5: total overlap with BWVLR > BWILT
In this case, there is no blocking as the interference is completely covered by the unwanted calculation. The blocking attenuation is therefore set to 1000 dB.
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The integral requires positive values of the blocking mask, i.e. the blocking mode has to be considered first.
where:
and
n = range/dF and range = upper-lower
The parameter maskValue(f) corresponds to the following equations (see section 1.4.6).
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- For generic systems in user-defined mode, it corresponds to the mask specified in the receiver settings;
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maskValue(f) = BlockUD (dB).
- For generic systems defined with blocking modes different to user-defined (i.e. sensitivity and protection ratio);
- Protection Ratio (dB):
maskValue(f) = BlockPR (dB) + C/(N+I) (dB) + (N+I)/N (dB) - I/N (dB)
- Sensitivity Mode (dBm):
maskValue(f) = BlockSens (dBm) – SensitivityVLR (dBm) + C/(N+I) (dB) – I/N (dB)
- For cellular systems:
- If the mask is defined in positive values (ACS), then maskValue(f) corresponds to the mask specified in the receiver settings;
- If the mask is defined in negative values, then maskValue(f) corresponds to the calculated positive mask using the input parameters Standard Desensitization and I/N_target (see section A8.2.8).
A8.2.7 Considerations on the bandwidths used in the integral
Calculation of BW for GENERIC systems
The algorithm is based on the mask entries and takes the values as relative to the carrier (dBc) at the zero offset.
It consists of two loops, one for the upper part of the mask, the second for the lower part.
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Calculation of BW for OFDMA
For a Base Station: the total number of resource blocks (max. RBs per BS) multiplied by the bandwidth of one resource block.
For a User Equipment: the bandwidth is: the number of RBs per MS (UE) multiplied by the bandwidth or one resource block.
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Calculation of BW for CDMA
The algorithm uses the reference bandwidth of the system, which is the same for either BS or UE (user defined in CDMA general settings). .
A8.2.88 Conversion of negative blocking mask values in cellular receivers (OFDMA and CDMA)
In case of receivers of cellular systems (OFDMA and CDMA), if the mask has negative values, it needs to be converted using the following input parameters in the receiver settings:
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If the mask is entered as positive values then these parameters are not used.
Figure 389: Input parameters for cellular receivers blocking masks
Default values of standard desensitisation and Target I/N are specified in the table below.
Table 67: Default values of standard desensitisation and Target I/N
|
| Standard Desensitization (dB) | Target I/N (dB) |
OFDMA UL | +6 | -6 | |
OFDMA DL | +6 | -6 | |
CDMA UL | +6 | -6 | |
CDMA DL | +3 | -6 |
The algorithm to convert negative blocking mask values is as follows:
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