1. July 2017
Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs)
Submission Title: [Suitability Evaluation of FEC Schemes]
Date Submitted: [9 July, 2017]
Source: [Joerg ROBERT] Company [Friedrich-Alexander University Erlangen-Nuernberg]
Address [Am Wolfsmantel 33, Erlangen, Germany]
Voice:[ ], FAX: [ ],
Re: []
Abstract: [This document presents the suitability evaluation for different FEC schemes that may be used for LPWAN.]
Purpose: [Presentation within IG LPWA]
Notice: This document has been prepared to assist the IEEE P It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein.
Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P
Joerg ROBERT, FAU Erlangen-Nuernberg

2. Suitability Evaluation of FEC Schemes
July 2017
Suitability Evaluation of FEC Schemes
Joerg Robert, FAU Erlangen-Nuernberg
Joerg Robert, FAU Erlangen-Nuernberg

3. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2017
No FEC ( I / II )
Simple transmission of the data without forward error-correcting codes
Pros
Simple
Cons
Significant performance loss (> 10dB) wrt. theory
Very inefficient for long packets
Does not allow for long-range due to low performance
Sensitive wrt. interference
<author>, <company>

4. No FEC ( II / II ) Channel Model Indoor Outdoor Rural Outdoor Urban
July 2017
No FEC ( II / II )
Channel Model
Indoor
Outdoor Rural
Outdoor Urban
Interference Model
Dense
Medium
Low
None
Active Interfering Users
Very High
High
Medium
Low
Frequency Regulation
ETSI
FCC
ETSI/FCC
None
Availability
> 90%
> 99%
> 99.9%
Power Supply
CR 2025
2xAA
Energy Harvesting
External
Cell Radius
> 50km
< 50km
< 10km
< 5km
< 1km
Node Velocity
3 km/h
30 km/h
120 km/h
Data Length
<= 16 bytes
<= 64 bytes
<= 256 bytes
> 256 bytes
Joerg Robert, FAU Erlangen-Nuernberg

5. Reed Solomon / BCH ( I / II )
<month year>
doc.: IEEE <doc#>
July 2017
Reed Solomon / BCH ( I / II )
Use of Reed Solomon or BCH Code
Pros
Relatively Simple
Acceptable performance with hard decision data
Good performance in case of block errors
Good performance in case of high rate
Cons
Significant performance loss wrt. theory
Only limited block length available
Limited performance in case of bit errors (e.g. AWGN channel)
<author>, <company>

6. Reed Solomon / BCH ( II / II )
July 2017
Reed Solomon / BCH ( II / II )
Channel Model
Indoor
Outdoor Rural
Outdoor Urban
Interference Model
Dense
Medium
Low
None
Active Interfering Users
Very High
High
Medium
Low
Frequency Regulation
ETSI
FCC
ETSI/FCC
None
Availability
> 90%
> 99%
> 99.9%
Power Supply
CR 2025
2xAA
Energy Harvesting
External
Cell Radius
> 50km
< 50km
< 10km
< 5km
< 1km
Node Velocity
3 km/h
30 km/h
120 km/h
Data Length
<= 16 bytes
<= 64 bytes
<= 256 bytes
> 256 bytes
Joerg Robert, FAU Erlangen-Nuernberg

7. Convolutional Code ( I / II )
<month year>
doc.: IEEE <doc#>
July 2017
Convolutional Code ( I / II )
Encode the data using convolutional encoder, decoding typically based on Viterbi algorithm
Pros
Very simple encoding
Acceptable decoding performance
Good performance in case of bit errors (e.g. AWGN channel)
Good performance in case of block errors with interleaver
Cons
Good performance (close to theoretical limits) only for short block length
Requires soft-information for full performance
<author>, <company>

8. Convolutional Code ( II / II )
July 2017
Convolutional Code ( II / II )
Channel Model
Indoor
Outdoor Rural
Outdoor Urban
Interference Model
Dense
Medium
Low
None
Active Interfering Users
Very High
High
Medium
Low
Frequency Regulation
ETSI
FCC
ETSI/FCC
None
Availability
> 90%
> 99%
> 99.9%
Power Supply
CR 2025
2xAA
Energy Harvesting
External
Cell Radius
> 50km
< 50km
< 10km
< 5km
< 1km
Node Velocity
3 km/h
30 km/h
120 km/h
Data Length
<= 16 bytes
<= 64 bytes
<= 256 bytes
> 256 bytes
Joerg Robert, FAU Erlangen-Nuernberg

9. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2017
Turbo Code ( I / II )
Turbo Codes are based on concatenated convolutional codes with iterative decoding
Pros
Very simple encoding
Good performance in case of bit errors (e.g. AWGN channel)
Good performance in case of block errors with interleaver
Cons
High decoding complexity (only for use in powerful base-station)
Requires soft-information for full performance
Requires long block lengths for good performance
<author>, <company>

10. Turbo Code ( II / II ) Channel Model Indoor Outdoor Rural
July 2017
Turbo Code ( II / II )
Channel Model
Indoor
Outdoor Rural
Outdoor Urban
Interference Model
Dense
Medium
Low
None
Active Interfering Users
Very High
High
Medium
Low
Frequency Regulation
ETSI
FCC
ETSI/FCC
None
Availability
> 90%
> 99%
> 99.9%
Power Supply
CR 2025
2XAA
Energy Harvesting
External
Cell Radius
> 50km
< 50km
< 10km
< 5km
< 1km
Node Velocity
3 km/h
30 km/h
120 km/h
Data Length
<= 16 bytes
<= 64 bytes
<= 256 bytes
> 256 bytes
Joerg Robert, FAU Erlangen-Nuernberg

11. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2017
LDPC Code ( I / II )
Low Density Parity Check (LDPC) Code are based on block codes with spare code matrices
Pros
Acceptable encoding complexity
Good performance in case of bit errors (e.g. AWGN channel)
Cons
High decoding complexity (only for use in powerful base-station)
Requires soft-information for full performance
Requires long block lengths for good performance
Sensitive wrt. erasures/puncturing (e.g. in case of block fading)
Normally fixed block length (inflexible)
<author>, <company>

12. LDPC Code ( II / II ) Channel Model Indoor Outdoor Rural Outdoor Urban
July 2017
LDPC Code ( II / II )
Channel Model
Indoor
Outdoor Rural
Outdoor Urban
Interference Model
Dense
Medium
Low
None
Active Interfering Users
Very High
High
Medium
Low
Frequency Regulation
ETSI
FCC
ETSI/FCC
None
Availability
> 90%
> 99%
> 99.9%
Power Supply
CR 2025
2XAA
Energy Harvesting
External
Cell Radius
> 50km
< 50km
< 10km
< 5km
< 1km
Node Velocity
3 km/h
30 km/h
120 km/h
Data Length
<= 16 bytes
<= 64 bytes
<= 256 bytes
> 256 bytes
Joerg Robert, FAU Erlangen-Nuernberg

13. doc.: IEEE 802.15-<doc#>
<month year>
doc.: IEEE <doc#>
July 2017
Polar Code ( I / II )
New code class for short codes that is currently discussed for 5G for protecting signaling information
Pros
Very good performance also in case of short block lengths
Cons
High decoding complexity as special decoder is required (only for use in powerful base-station)
Requires soft-information for full performance
IPR status unclear
Optimized for short block length
<author>, <company>

14. Polar Code ( II / II ) Channel Model Indoor Outdoor Rural
July 2017
Polar Code ( II / II )
Channel Model
Indoor
Outdoor Rural
Outdoor Urban
Interference Model
Dense
Medium
Low
None
Active Interfering Users
Very High
High
Medium
Low
Frequency Regulation
ETSI
FCC
ETSI/FCC
None
Availability
> 90%
> 99%
> 99.9%
Power Supply
CR 2025
2XAA
Energy Harvesting
External
Cell Radius
> 50km
< 50km
< 10km
< 5km
< 1km
Node Velocity
3 km/h
30 km/h
120 km/h
Data Length
<= 16 bytes
<= 64 bytes
<= 256 bytes
> 256 bytes
Joerg Robert, FAU Erlangen-Nuernberg

15. Any Questions or Comments?
July 2017
Any Questions or Comments?
Joerg Robert, FAU Erlangen-Nuernberg