Two-tier PON virtualization with scheduler synchronization supporting application-level ultra-low latency in MEC based cloud-RAN, using MESH-PON

Sandip Das; Frank Slyne; Daniel Kilper; Marco Ruffini

doi:10.1364/JOCN.482208

Journal of Optical Communications and Networking
Vol. 15,
Issue 7,
pp. C100-C107
(2023)
•https://doi.org/10.1364/JOCN.482208

Two-tier PON virtualization with scheduler synchronization supporting application-level ultra-low latency in MEC based cloud-RAN, using MESH-PON

Sandip Das, Frank Slyne, Daniel Kilper, and Marco Ruffini

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Sandip Das, Frank Slyne, Daniel Kilper, and Marco Ruffini, "Two-tier PON virtualization with scheduler synchronization supporting application-level ultra-low latency in MEC based cloud-RAN, using MESH-PON," J. Opt. Commun. Netw. 15, C100-C107 (2023)

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About this Article
History
- Original Manuscript: December 1, 2022
- Revised Manuscript: February 1, 2023
- Manuscript Accepted: February 16, 2023
- Published: May 30, 2023
Virtual Issues
Journal of Optical Communications and Networking ECOC 2022 (2023)

Abstract

Ultra-low end-to-end latency is one of the most important requirements in 5G networks and beyond to support latency-critical applications. Cloud radio access networks and multi-access edge computing (MEC) are considered as the key driving technology that can help reduce end-to-end latency. However, the use of MEC nodes poses radical changes to the access network architecture. As it brings the processing and networking services closer to the edge, it often requires network functions [for example, the centralized unit/distributed unit (CU/DU) stack and application processing] to be distributed across different MEC sites. Therefore, a transport mechanism is needed to efficiently coordinate and connect network functions across MEC nodes. To address this challenge, we propose a two-tier virtualized passive optical network (PON) transport method with scheduler coordination over a virtualized and sliced MESH-PON architecture. While a MESH-PON architecture enables direct communication between MEC nodes hosting CUs/DUs and/or the application processing, our method provides a two-tier virtualized PON transport scheme with coordinated schedulers. This approach greatly reduces latency incurred in transporting signals across the different PON tiers, while maintaining the flexibility of multi-tier methods. We show that our proposed scheme can achieve end-to-end application-level latency below 1 or 2 ms, depending on the network configurations.

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	Values
Parameters	Config-1	Config-2
NR bandwidth (per RU)	100 MHz
NR numerology (µ)	1	2
NR slot time ( $T_{s l o t}^{μ}$ )	0.5 ms	0.25 ms
Maximum number of PRBs ( $N_{P R B}^{B W (j)}$ )	270	135
Number of PRBs per user ( $N_{P R B}^{u s e r}$ )	5
Traffic type	{Normal, URLLC}
Percentage of PRBs reserved for CGS (URLLC traffic)	{10%, 20%}
Number of MIMO layers per RU ( $v_{L a y e r s}^{(j)}$ )	4
Number of antennas per RU ( $N_{a n t}$ )	4
Modulation order ( $Q_{m}^{(j)}$ )	256 QAM
Number of component carriers for carrier aggregation ( $J$ )	1
Scaling factor ( $f^{(j)}$ )	1
$R_{max}$	948/1024
Overhead ( $O H^{(j)}$ )	0.1 (for frequency range FR1 and UL)
OFDM symbol duration including CP (in µs) ( $T_{s}^{μ} = 10^{- 3} / (14 * 2^{μ})$ )	35.714 µs	17.85 µs

Parameters	Values
(TWDM-PON) Uplink capacity per OLT channel (CO-OLT, MEC-OLT)	50 Gbps
Fiber propagation delay	4.5 µs/km
OLT grant cycle duration	125 µs
Ethernet (eCPRI) frame size	2048 bytes
Inter-packet gap for eCPRI packets	$10^{- 7} s$
ONU response time	35 µs
CU/DU stack processing delay	0.5 ms, 0.25 ms
eCPRI 7.2 rate calculation parameters	$N_{R E, i} = 156$ , $N_{r e s, i} = 8$
	$N_{r e g}^{P U C C H} = 1$
	$N_{R E}^{P U C C H} = 156$
	$N_{r e s}^{P U C C H} = 8$
	$N_{b i n s}^{P R A C H} = 839$
	$N_{r e s, P R A C H} = 10$
	$T_{P R A C H} = 10 m s$
	$N_{R E, S R S} = 12$
	$N_{r e s, S R S} = 8$
	$N_{s c r r, S R S} = ((N_{P R B}^{BW (j)} -$ $N_{r e g}^{P U C C H}) * N_{R E, S R S})$
	$T_{S R S} = 1 m s$

	Values
Parameters	Config-1	Config-2
NR bandwidth (per RU)	100 MHz
NR numerology (µ)	1	2
NR slot time ( $T_{s l o t}^{μ}$ )	0.5 ms	0.25 ms
Maximum number of PRBs ( $N_{P R B}^{B W (j)}$ )	270	135
Number of PRBs per user ( $N_{P R B}^{u s e r}$ )	5
Traffic type	{Normal, URLLC}
Percentage of PRBs reserved for CGS (URLLC traffic)	{10%, 20%}
Number of MIMO layers per RU ( $v_{L a y e r s}^{(j)}$ )	4
Number of antennas per RU ( $N_{a n t}$ )	4
Modulation order ( $Q_{m}^{(j)}$ )	256 QAM
Number of component carriers for carrier aggregation ( $J$ )	1
Scaling factor ( $f^{(j)}$ )	1
$R_{max}$	948/1024
Overhead ( $O H^{(j)}$ )	0.1 (for frequency range FR1 and UL)
OFDM symbol duration including CP (in µs) ( $T_{s}^{μ} = 10^{- 3} / (14 * 2^{μ})$ )	35.714 µs	17.85 µs

Parameters	Values
(TWDM-PON) Uplink capacity per OLT channel (CO-OLT, MEC-OLT)	50 Gbps
Fiber propagation delay	4.5 µs/km
OLT grant cycle duration	125 µs
Ethernet (eCPRI) frame size	2048 bytes
Inter-packet gap for eCPRI packets	$10^{- 7} s$
ONU response time	35 µs
CU/DU stack processing delay	0.5 ms, 0.25 ms
eCPRI 7.2 rate calculation parameters	$N_{R E, i} = 156$ , $N_{r e s, i} = 8$
	$N_{r e g}^{P U C C H} = 1$
	$N_{R E}^{P U C C H} = 156$
	$N_{r e s}^{P U C C H} = 8$
	$N_{b i n s}^{P R A C H} = 839$
	$N_{r e s, P R A C H} = 10$
	$T_{P R A C H} = 10 m s$
	$N_{R E, S R S} = 12$
	$N_{r e s, S R S} = 8$
	$N_{s c r r, S R S} = ((N_{P R B}^{BW (j)} -$ $N_{r e g}^{P U C C H}) * N_{R E, S R S})$
	$T_{S R S} = 1 m s$

Abstract

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Equations (4)

Journal of Optical Communications and Networking