Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs) Submission Title: Introduction to Taiwan High Speed Rail Broadband System Date Submitted: March 10, 2015 Source: Ching-Tarng Hsieh, Industrial Technology Research Institute Contact: Ching-Tarng Hsieh, Industrial Technology Research Institute Voice: +886-3-591-7379, E-Mail: chsieh@itri.org.tw Re: IG HRRC Discussion Abstract: This contribution summarizes ITRI s work on Taiwan High Speed Rail broadband system. Purpose: To share ITRI s experience on high speed rail communications at the IG HRRC meeting and to express ITRI s interest in participating in the activities of the IG. Notice: This document has been prepared to assist the IEEE P802.15. 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 P802.15. Slide 1 1 Ching-Tarng Hsieh (ITRI)
Outline q Background q System Architecture for WiMAX q Technology Breakthrough q Achievements q System Architecture for LTE q Deployment and Handover Results q Concluding Remarks 2 Ching-Tarng Hsieh (ITRI)
Why HSR Broadband Communication? From METIS FP7 to Horizon 2020 Moving network is recognized as a high-potential scenario How to provide robust high-rate backhaul links for base stations is a major issue in high-mobility moving networks Mobile applications on HSR will be a critical topic in the development of next-generation mobile broadband technologies High throughput (Gbps) Ultra-high mobility (500 km/h) HSR: high speed rail METIS FP7 Topics 3 Ching-Tarng Hsieh (ITRI)
Challenges along THSR Track Shadowing caused by the terrain Signal is blocked by hills, tunnels, or bridges Hard to find good locations to construct base-stations Frequent handover and group handover Handover every 36 sec. (3 km distance, 300 km/hr) Over 1,000 users on one train to handover simultaneously HSR Mileage Height THSR: Taiwan high speed rail 4 Ching-Tarng Hsieh (ITRI)
Constraints of THSR Train According to Ericsson s experiment, the signal attenuation and its incident angle have the following relations: The attenuation increases with the decrease of incident angle The attenuation at different locations in a car varies significant The attenuation close to and far from base station is 18 and 30 db respectively in average, and the overall attenuation is about 25~30 db Incident angle Incident angle 5 Ching-Tarng Hsieh (ITRI)
System Architecture for WiMAX Core network: ITRI M-Taiwan WiMAX App. Lab. (MTWAL) Ground-to-train communications: WiMAX in 2.5 GHz Intra-car communications: IEEE 802.11b/g in 2.4 GHz band Inter-car communications: IEEE 802.11a in 2.4 GHz band Ground-to-train, intra-car and inter-car communications The ground network is based on ITRI MTWAL 6 Ching-Tarng Hsieh (ITRI)
Technology Breakthrough (1/4) RoF Distributed Antenna System Used to extend coverage, enhance reception, and improve frequent handover Over 8 km covered by RoF, we successfully conducted handover at 300 km/h with 40 ms latency, and achieved peak and average rate of 10 and 6.7 Mbps respectively RAU#2-n RAU#2-2 RAU#2-1 RAU#1-1 RAU#1-2 RAU#1-m Down Link Down Link Optical Fiber HEU #2-1 ~#2-n Up Link BTS System DE multiplexing/ Multiplexing System Up Link HEU #1-1 ~#1-m χ Optical Fiber RoF: radio-over-fiber 7 Ching-Tarng Hsieh (ITRI)
Technology Breakthrough (2/4) Adaptive power and MCS for high speed channel Improve reliability of intra-site handover By limiting uplink MCS index By improved power control convergence rate Increase downlink throughput By offsetting MS channel quality estimation By modifying rate control algorithm Achievement: increase throughput from 3 Mbps to 8 Mbps Peak. 17 Mbps Yangmei BS Site TCP Avg. 8 Mbps MCS: modulation and coding scheme 8 Ching-Tarng Hsieh (ITRI)
Technology Breakthrough (3/4) Enhanced MIMO antenna design at train roof To fit in Kathrein radome Orthogonal polarization and new antenna pattern design Achievement: throughput is increased from 4.7 to 8.4 Mbps Train MIMO Antenna Antenna #A Antenna #B Train MIMO Antenna MIMO antenna design spec. MIMO: multiple-input multiple-output 9 Ching-Tarng Hsieh (ITRI)
Technology Breakthrough (4/4) Live TV service based on Application-layer FEC (AL-FEC) Save Wi-Fi backhaul bandwidth usage and prevent congestion AL-FEC can eliminate 99% multicast packet loss and make multicast streaming service feasible on high speed trains Android client (Asus Transformer) 100% 90% 80% 70% 60% 50% 40% 30% 20% 10% 0% RTP Packet Loss Rate 1 1001 2001 3001 4001 5001 6001 7001 After AL-FEC decoding 100% 90% 80% 70% 60% 50% 40% 30% 20% 10% 0% RTP Packet Loss Rate 1 1001 2001 3001 4001 5001 6001 7001 ios client (ipad 3) FEC: forward error correction RTP Packet Loss Rate 90% 80% 70% 60% 50% 40% 30% 20% 10% 0% 1 1001 2001 3001 4001 5001 6001 7001 After AL-FEC decoding RTP Packet Loss Rate 100% 90% 80% 70% 60% 50% 40% 30% 20% 10% 0% 1 1001 2001 3001 4001 5001 6001 7001 10 Ching-Tarng Hsieh (ITRI)
Achievements Two trains have been providing broadband services since Sep. 2012 The radio access technologies and bandwidth used : ground to train: WiMAX backhaul (~8.4Mbps) on-board : Wi-Fi access (~90Mbps) The accumulated number of accesses of the Wi-Fi network is over 1 million On-board: WiFi AP-to-User90 Mbps WiFi AP Notebook (Tx) WiFi AP On-board: WiFi AP-to-AP141 Mbps WiFi AP WiFi AP WiFi AP WiFi AP CAR1 CAR2 11 Ching-Tarng Hsieh (ITRI)
System Architecture for LTE Two-hop architecture is exploited UEs on train use FD-LTE small cells The FD-LTE small cells use TD-LTE wireless backhaul to connect core network The advantages of two-hop architecture: Reduced power consumption for UE Simpler processing and signaling overhead for enb Core Network TD- LTE enb Router TD- LTE enb Router UE: user equipment 12 Ching-Tarng Hsieh (ITRI)
Field Trial Deployment Handover (HO) performance was investigated 3 enbs (P01, P11,P12) are deployed, where RoF systems with five RAUs (P02~P06) and four RAUs (P07~P10) are connected to P01 and P11, respectively, for signal coverage extension in two tunnels (Litoushan Tunnel 0.7 km, Hukou Tunnel 4 km). The handover is classified as intra handover (intra-ho) and inter handover (inter-ho) Hsinchu Station Litoushan Tunnel (~0.7 Km) Hukou Tunnel (~4 Km) Hukou Yangmei P01 ~72.479K P02 70.744K P03 70.145K P04 69.533K P05 68.879K P06 68.362K P07 67.310K P08 66.290K P09 65.210K P10 64.215K P11 63.651K P12 60.721K RRU RRU enb RAU RAU RAU RAU RAU RAU RAU RAU RAU RRU RRU enb RRU enb 1.052 km 1.02 km 1.08 km 0.995 km 2.930 km 1.735 km 0.599 km 0.654 km 0.517 km 0.564 km 0.612 km Intra-HO Inter-HO Intra-HO Inter-HO S1C1 S1C2 S2C1 S2C2 S3C1 RoF: radio over fiber; RAU: remote antenna unit 13 Ching-Tarng Hsieh (ITRI)
RSRP and Attach Performance (1/2) Radio link failure (RLF) occurred at 525 sec It corresponds to the location of the first inter-ho in the long tunnel (Hukou tunnel) Attach was complete at 625 sec, followed by another RLF before 700 sec HO procedure RSRP (dbm) LTE enb RAU at Hsinchu RAU at Hukou Tunnel RSRP General Level S1C1 Stop at HSR Hsinchu Station * S1C1à S1C2 (complete) Rel. Time (sec.) S1C2(RAU) S2C1(RAU) S2C2 S3C1 x * * x * S2C1à S2C2 (complete) x* * S2C2à S3C1 (Incomplete) * x Ping reply area Backhaul UE Attach Request Backhaul UE Attach Complete x Backhaul UE is released Inter-site HO Request Intra-site HO Request South Direction North Field trial on 2014/12/05 RSRP: reference signal receiving power 14 Ching-Tarng Hsieh (ITRI)
RSRP and Attach Performance (2/2) To solve the RLF issue during inter-site HO, one RAU (P10) was shut down and some enb parameters were further adjusted 2 intra-ho and 2 inter-ho were executed successfully without RLF (continuous ping reply without interruption) LTE enb RAU at Hsinchu RAU at Hukou RAU OFF Tunnel * Backhaul UE Attach Request Backhaul UE Attach Complete x Backhaul UE is released Inter-site HO Request Intra-site HO Request Stop at HSR Hsinchu Station S1C1 S1C2(RAU) S2C1(RAU) S2C2 S3C1 Ping reply area RSRP (dbm) RSRP General Level * S1C1à S1C2 (complete) S1C2à S2C1 (complete) S2C1à S2C2 (complete) S2C2à S3C1 (complete) x South Direction North Rel. Time (sec) Field trial on 2014/12/17 15 Ching-Tarng Hsieh (ITRI)
Concluding Remarks ITRI is cooperating with Ericsson to build a LTE HSR test-bed as the foundation for next-generation moving network research. There is on-going effort to improve the throughput performance, including enhanced MIMO antenna design, load balancing with wireless backhaul diversity, etc. ITRI looks forward to participating in the IG and cooperating with other parties to share our knowledge as well as expand our vision and visibility. 16 Ching-Tarng Hsieh (ITRI)
17 Ching-Tarng Hsieh (ITRI)
LTE System Parameters Cell S1C1 at Hsinchu South S1C2 at Hsinchu North (RoF) S2C1 at Hukou South (RoF) S2C2 at Hukou North S3C1 at Yangmei State ON ON ON ON ON Physical CID 303 304 308 306 310 Sync. Dev. <= 10 us <= 10 us <= 10 us <= 10 us <= 10 us Tx. Mode 2 2 2 2 2 Bandwidth 15 MHz 15 MHz 15MHz 15 MHz 15 MHz EARFCN 37875 37875 37875 37875 37875 Power PUCCH -107 dbm -107 dbm -107 dbm -107 dbm -107 dbm Power PUSCH -93 dbm -93 dbm -93 dbm -93 dbm -93 dbm EARFCN: EUTRA Absolute radio-frequency channel number 18 Ching-Tarng Hsieh (ITRI)