# |
Criterion |
Discussion |
1 |
Meets system requirements |
How well does the proposed PHY protocol meet the requirements described in the current version of the 802.16 System Requirements (Document IEEE 802.16s-99/00)? |
2 |
Spectrum efficiency |
Defined in terms of single sector capacity assuming all available spectrum is being utilized (either in terms of Gbps/Available Spectrum or in terms of Mbps/MHz) |
3 |
Simplicity of implementation |
How well does the proposed PHY allow for simple implementation or how does it leverage on existing technologies? |
4 |
CPE cost optimization |
How does the proposed PHY affect CPE cost? |
5 |
Spectrum resource flexibility |
Flexibility in the use of the frequency band (i.e., minimum frequency band required to operate and migration capabilities) |
6 |
System diversity flexibility |
How flexible is the proposed PHY to any other system variations and future technology improvements or new services? |
7 |
Protocol Interfacing complexity |
Interaction with other layers of the protocol, specifically MAC and NMS |
8 |
Implication on other network interfaces |
Intrinsic transport efficiency of telecomm and datacomm services |
9 |
Reference system gain* |
Sector coverage performance for a typical BWA deployment scenario (supply, reference system gain) |
10 |
Robustness to interference |
Resistance to intra-system interference (i.e., frequency re-use) and external interference cause by other systems |
11 |
Robustness to channel impairments |
Rain fading, multipath, atmospheric effects |
* In order to compare between PHY proposals, we define the reference system gain (RSG) as the output power of the transmitter minus the receiver threshold at a given working point, including back-off required for proper transmission. We will assume a 0 dBW transmitter (prior to back-off), and an ideal LNA (0 dB NF) and BER of 10 -6 post coding.
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