IEEE C802.16m-08/1046r1 Project Title Date
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IEEE C802.16m-08/1046r1 Project IEEE 802.16 Broadband Wireless Access Working Group <http://ieee802.org/16> Title Prioritized QoS Framework – Network Entry for IEEE 802.16m Date Submitted 2008-09-05 Source(s) An Nguyen DHS/NCS D. J. Shyy MITRE Re: An.P.Nguyen@dhs.gov djshyy@mitre.org MAC: Network Entry In response to IEEE 802.16m-08/033, Call for Contributions and Comments on Project 802.16m System Description Document (SDD) (2008-08-01) Abstract The document describes prioritized QoS framework in network entry used to support the priority access in 802.16m Purpose Request consideration of prioritized QoS framework in network entry contained herein for the 802.16m SDD. Notice Release Patent Policy This document does not represent the agreed views of the IEEE 802.16 Working Group or any of its subgroups. It represents only the views of the participants listed in the “Source(s)” field above. It is offered as a basis for discussion. It is not binding on the contributor(s), who reserve(s) the right to add, amend or withdraw material contained herein. The contributor grants a free, irrevocable license to the IEEE to incorporate material contained in this contribution, and any modifications thereof, in the creation of an IEEE Standards publication; to copyright in the IEEE’s name any IEEE Standards publication even though it may include portions of this contribution; and at the IEEE’s sole discretion to permit others to reproduce in whole or in part the resulting IEEE Standards publication. The contributor also acknowledges and accepts that this contribution may be made public by IEEE 802.16. The contributor is familiar with the IEEE-SA Patent Policy and Procedures: <http://standards.ieee.org/guides/bylaws/sect6-7.html#6> and <http://standards.ieee.org/guides/opman/sect6.html#6.3>. Further information is located at <http://standards.ieee.org/board/pat/pat-material.html> and <http://standards.ieee.org/board/pat>. IEEE C802.16m-08/1046r1 Prioritized QoS Framework in Network Entry for IEEE 802.16m 1 Introduction Priority access is one of important requirements of Emergency Telecommunications Service (ETS) [1]. ETS is a telecommunications service to facilitate emergency recovery operations for restoring the community infrastructure and for returning the population to normal living conditions after serious disasters and events, such as floods, earthquakes, hurricanes, and terrorist attacks. The ETS will be provided through shared resources from the public telecommunications infrastructure, which includes wireline, wireless, satellite, broadband cable, and any hybrid networks. ETS traffic needs to access, traverse, and egress these networks. Voice, video and data services are supported by ETS. IEEE 802.16m has requirements on priority for the government and public safety. In Section 5.8 of IEEE 802.16m-07/002r4, it said “IEEE 802.16m shall be able to support public safety first responders, military and emergency services such as call-prioritization, preemption, push-to-talk”. Priority access is also a SPWG requirement in Mobile WiMAX [2]. In Release 1.5, “R-[193] The WIMAX network SHALL provide high priority for special circumstances such as emergency services and deadlock situations. Such high priority SHALL be protected with appropriate additional levels of authentication.” Priority access is required for National Security and Emergency Preparedness (NS/EP) users. In this contribution, we propose prioritized QoS framework in network entry to be considered by 802.16m. 1.1 Purpose The major purpose of this document is to propose prioritized QoS framework in network entry to support the priority access in 802.16m. 1.2 All the identified prioritized QoS framework in network entry is our recommendations to be included in 802.16m SDD. Document Organization Section 2 presents prioritized QoS framework in network entry to support priority access to be considered by 802.16m Section 3 presents more detailed ETS requirements, especially in the area of priority access. Section 4 is our SDD text proposal. 2 802.16m Prioritized QoS Framework in Network Entry to Support Priority Access To support priority access in 802.16m, the following procedures are required • User subscription • Service priority invocation (service priority indication) • User authentication (user identity; verifies the service indication is from priority user) • Service authorization (specifies the service privileges of priority user) • Service priority treatment (service differentiation) IEEE C802.16m-08/1046r1 This document discusses the techniques used for service priority treatment. To provide service priority treatment using 802.16m networks, the following techniques are required: • Prioritized network entry (initial ranging) • Prioritized (initial) service flow setup and admission • Prioritized session setup and maintenance • Prioritized bandwidth request for admitted service flow • Prioritized handover The congestion points for radio access occur at contention-based and allocation-based transmission (shown in Figure 1). contention-based transmission is mainly used for initial ranging and bandwidth request. capacity. The The allocation-based is to allocate OFDMA This contribution discusses the prioritized QoS framework to support priority access for contention based transmission, specially in network entry. ASN 16e MS 16m MS R1 R1 16m BS R6 ASN Gateway R6 16m MS R1 16m BS • Contention-based radio resource • Initial ranging • Bandwidth request • Allocation-based radio resource • Service flow admission Figure 1: Radio Access Congestion Points . 2.1 Protocol Functions for Priority Access The protocol functions for priority access are shown in Figure 2. The priority access capability is supported by different logic entities in the MAC Common Part Sublayer. Network Entry Management entity is responsible for priority access to the contention resource such as initial ranging. Connection Management entity is responsible for service flow setup between BS and MS. And scheduler is for dynamic radio bandwidth allocation. All these entities shall coordinate with Radio Resource Management entity about the resource availability. Local Radio Resource stores local radio bandwidth utilization. Radio Resource Management is the entity to access and update the real-time radio resource information. 3 IEEE C802.16m-08/1046r1 16m MS 16m BS Application Layer Application Layer MAC MAC Convergence Sublayer Convergence Sublayer Common Part Sublayer Common Part Sublayer Network Entry Management Local Radio Resource Radio Resource Management Network Entry Management Local Radio Resource R1 Connection Management Connection Management Radio Resource Management Scheduler Scheduler Security Sublayer Security Sublayer PHY PHY Figure 2: 802.16m Protocol Functions for Priority Access The 802.16e has the following network entry steps: • Scanning • Obtaining parameters • Initial ranging • Exchanging capabilities • Authentication • Registration • IP connectivity • Creating transport connection (Adding service, service flow admission) • Bandwidth Request for admitted service flow The priority treatments for initial ranging, creating transport connection and bandwidth request steps are discussed in the following sections. 2.2 Prioritized Contention Resolution 2.2.1 Introduction 4 IEEE C802.16m-08/1046r1 In IEEE 802.16e, initial ranging and bandwidth request use contention-based scheme to access the network. Initial ranging is for a new mobile station (MS) to join the network which requires a long preamble. The bandwidth request is for a MS to request uplink (UL) allocation which requires a short preamble. The non-real time polling service (nrtPS) (for FTP) and best effort (for web browsing) use bandwidth request via contention-based or by piggybacking the requests to granted data allocations [3]. Initial ranging and bandwidth request adopt PN code sequences to mitigate collisions. The code is spread over multiple subchannels in one symbol. The minimal allocation for initial ranging is 6 adjacent subchannels and 2 symbols (also called UL initial ranging slot). The minimal allocation for bandwidth request is 6 adjacent subchannels and one symbol. The above definitions follow those in the WiMAX Forum Mobile System Profile. There are 144 tones in 6 subchannels. Since each tone is BPSK modulated, a PN code sequence for initial ranging and bandwidth request is 144 bits [3]. The number of codes is 256 in one sector, and these 256 codes are shared among initial ranging, periodic ranging, bandwidth request, and handover ranging. The collision detection is when a MS does not get the expected response in a given time. The resolution is to use a truncated binary exponential backoff window. There are a few concerns of the 802.16e contention-based messaging protocols. First, based on the WiBro deployments, their capacity is actually the bottleneck of the network. Second, configurations for initial ranging and bandwidth request can be specified only on a per sector basis, i.e., they cannot be defined on a per user class per sector basis. As a result, no service differentiation can be provided to MSs for initial ranging or bandwidth request within a sector. We propose to have the parameters for initial ranging and bandwidth request to be specified on a per user class per sector basis for IEEE 802.16m. In this paper, we analyze the performance of prioritized initial ranging and illustrate its benefits using the Mobile WiMAX System Simulator [4]. 2.2.2 Simulation Configurations 2.2.2.1 802.16e Initial Ranging Configuration As previously described, the basic allocation for contention-based signaling is that two symbols are needed for initial ranging slot (since the UL synchronization has not been achieved yet) and one symbol is for bandwidth request [5]. In the current IEEE 802.16 Rev2/D6, for the OFDMA PHY, after completion of contention-based initial ranging during network entry, BS shall send a CDMA allocation IE to MS. The CDMA allocation IE corresponds to a particular CDMA initial ranging code. After the MS receives the CDMA allocation IE, the MS sends a RNG-REQ containing MAC address using UL resource pointed by CDMA_Allocation_IE. When BS receives the RNG-REQ message, it shall respond with a RNG-RSP (with matching MAC address) message. The RNG- RSP contains the CIDs (Basic & Primary Management) correspond with MAC address of the MS. If RNG-RSP message is lost, T3 of MS will expire, and MS shall perform contention-based initial ranging again. There are two reasons that a MS does not get RNG-RSP. One is code collision (i.e., multiple MSs choose the same code) and the other is excessive interference. Reference 5 indicated that 30 ranging codes per initial ranging slot can be received at the BS at the 5 IEEE C802.16m-08/1046r1 same time without having excessive interference. However, when talking to WiMAX chip set vendor at the IEEE 802.16 standards meetings July 2008, only 3 or 4 codes can be received at the same time. To support prioritized initial ranging, there are two proposals. One is to boost up the transmit power of the initial ranging code, and the other is to reserve certain codes (and their associated resources) for the priority users. The following analyzes the performance of the latter proposal. Traffic assumptions: Intel’s contribution [6] assumes 10 MHz/10 MHz FDD and 60 VoIP calls/MHz/sector. Document [SRD] defines the VoIP capacity [active users/MHz/sector] to be > 30.) more than what is generated by the number of VoIP calls. (The 802.16m System Requirement However, the traffic load for initial ranging is For example, all the following scenarios generate initial ranging load. The user powers on their 802.16 device and stays idle (idle users), the user attempts to initiate a connection (i.e., data, VoIP, video) (active users) or National Security/Emergency Preparedness (NS/EP) users need to access the network during emergency. Hence, the traffic load is much higher than the assumption of considering only VoIP load. Instead of pin pointing a specific traffic load, we use a parametric approach to model the traffic load. the performance of prioritized initial ranging under various traffic loads. That is to say that we analyze We assume that among the sector load for initial ranging, R% is for regular calls and P% is for priority calls, where R = 90 and P = 10 [7]. The initial ranging arrival follows Poisson distribution. Parameters: Initial ranging region: The time between initial ranging regions (1 – 8 frames) Number of initial ranging codes (1 – 256) Number of initial ranging slots (1 – 2) Interference analysis: Two types of code interference analysis are modeled: 1. Multiple users choose the same code (code collision) 2. Excessive interference at the receiver (code interference) Code interference threshold (4 or 8) Mitigation techniques: 6 IEEE C802.16m-08/1046r1 We investigate the effectiveness of the following mitigation techniques using modeling and simulation. a. Dedicated code b. Dedicated initial ranging slot c. Orthogonal code; this solves the code collision, but does not resolve code interference. Dedicated subchannel (orthogonal frequency) and dedicated symbol (orthogonal time); this solves code interference. Time between dedicated initial ranging regions Dedicated frame (orthogonal time); this solves code interference. 2.2.2.2 Simulation Results Simulation is conducted for the following cases. Case Regular Priority IR Regular Priority IR Time Time Code IR code code IR slot slot between between interference range range number number regular IR priority IR threshold region region (every nth (every nth frame) frame) I.1 1-64 65-72 1 1 1 1 4 I.2 1-72 N/A 1 N/A 1 N/A 4 I.3 1-64 65-72 1 1 1 1 8 I.4 1-72 N/A 1 N/A 1 N/A 8 I.5 1-32 33-36 1 1 1 1 8 I.6 1-36 N/A 1 N/A 1 N/A 8 II.1 1-64 65-72 1 2 1 1 4 II.5 1-32 33-36 1 2 1 1 8 III.1 1-72 1-72 1 N/A 1, 2, 3, 8 4 4,5,6,7 In Case I.1, there is only one initial ranging slot, but regular and priority users have their dedicated codes. In Case I.2, there is only one initial ranging slot, but regular and priority users share the code space. As shown in Figure 3, Case I.1 performs worse than case I.2 which means if there are no orthogonal resources in time and/or frequency (e.g. initial ranging slot) for priority users, division of code space does not help. The reason is that since the dominating interference factor is excessive interference, division of the code space does not provide any benefit. 7 IEEE C802.16m-08/1046r1 Initial Raning Performance Analysis for 802.16e/m Networks 1 0.9 0.8 0.7 Probability 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 8 Total IR Arrival Rate (= lt where t = 5 ms) overall IR success rate (I.2) reg interference (I.1) cc pri to pri (I.1) regular IR success rate (I.1) overall interference (I.2) cc pri to reg (I.1) priority IR success rate (I.1) cc all to all (I.2) cc reg to pri (I.1) pri interference (I.1) cc reg to reg (I.1) Figure 3: Initial Ranging Performance for Cases I.1 and I.2 Cases I.3 and I.4 are similar to Cases I.1 and I.2 except the code interference threshold is increased from 4 to 8. However, the overall trend does not change (the performance curves are not shown here). Cases I.5 and I.6 (shown in Figure 4) are similar to Cases I.3 and I.4 except that the code space for regular user and priority user is reduced by half. The overall trend is still the same as that in Figure 3. However, the dominating interference factor is a function of the initial ranging load. For smaller initial ranging load, the dominating interference factor is code collision; for high initial ranging load, the dominating interference factor is the code interference. The interference threshold determines at what traffic load the excessive interference becomes the dominating factor. Since service differentiation is more needed during high load, the code space division does not help these two cases either. 8 IEEE C802.16m-08/1046r1 Initial Raning Performance Analysis for 802.16e/m Networks 1 0.9 0.8 0.7 Probability 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 8 Total IR Arrival Rate (= lt where t = 5 ms) regular IR success rate (I.5) reg interference (I.5) cc pri to pri (I.5) overall IR success rate (I.6) overall interference (I.6) cc pri to reg (I.5) priority IR success rate (I.5) cc all to all (I.6) cc reg to pri (I.5) pri interference (I.5) cc reg to reg (I.5) Figure 4: Initial Ranging Performance for Cases I.5 and I.6 In Case II.1, one initial ranging slot is for regular users while another initial ranging slot is dedicated to priority users. Case II.1 shows a different trend (see Figure 5). The probability of success for priority initial ranging can be maintained about 90% for all initial ranging arrival load. 9 IEEE C802.16m-08/1046r1 Initial Raning Performance Analysis for 802.16e/m Networks 1 0.9 0.8 0.7 Probability 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 8 Total IR Arrival Rate (= lt where t = 5 ms) priority IR success rate (II.1) pri interference (II.1) regular IR success rate (II.1) cc reg to reg (II.1) reg interference (II.1) cc pri to pri (II.1) Figure 5: Initial Ranging Performance Analysis for Cases II.1 Case II.5 has a similar trend as Case II.1 (the performance curves are not shown here). The differences between Case II.5 and Case II.1 are that the former has half of the codes and more relaxed code interference threshold. Case III.1 assigns 7 frames (out of every 8 frames) for regular user traffic and 1 frame (out of every 8 frames) for priority user traffic. A similar trend as that in Case II.1 can be observed in Figure 6. Although the probability of success for priority initial ranging degrades with higher initial ranging load, its performance is better than that of regular user. 10 IEEE C802.16m-08/1046r1 Initial Raning Performance Analysis for 802.16e/m Networks 1 0.9 0.8 0.7 Probability 0.6 0.5 0.4 0.3 0.2 0.1 0 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6 6.5 7 7.5 8 Total IR Arrival Rate (= lt where t = 5 ms) priority IR success rate (III.1) reg interference (II.5) regular IR success rate (III.1) cc reg to reg (III.1) pri interference (III.1) cc pri to pri (III.1) Figure 6: Initial Ranging Performance Analysis for Cases III.1 2.2.2.3 Observation In most of the cases, the excessive interference is the dominating factor of interference. As a result, division of the code space (without dedicated slot or time for priority users) does not provide any benefit. Division of code space must be accompanied by dedicated time/frequency resources. 2.2.3 Guidelines a. Assign one or more dedicated initial ranging slot for regular user and one dedicated initial ranging slot for priority user for a larger channel bandwidth (e.g. 10 MHz). Also assign a set of dedicated codes for regular user and another dedicated set for priority user. b. Assign one or more dedicated initial ranging frames for regular user and one dedicated initial ranging frame for priority user for a smaller channel bandwidth (e.g. 5 MHz). c. The above guidelines are also applicable to bandwidth request. 11 IEEE C802.16m-08/1046r1 2.2.4 Conclusion The techniques used in Cases II and III are recommended. Case II requires the use of an additional initial ranging slot while Case III incurs additional delay (on the order of ten’s of ms) for initial ranging request. 3 Priority Access Requirements 3.1 Priority Access Service ETS is a super set of all emergency services for an authorized select group of users. Wireless Priority Service (WPS) is one of ETS that is on wireless networks. The Wireless Priority Service should provide end-to-end treatment across the network (e.g., access, transport, and egress) so that higher communication session completion rates, as compared with public communication session completion rates, would be successfully achieved. Communication sessions in this context include voice, multimedia, and data.” [1] DHS/NCS has worked with service providers as well as equipment vendors to get WPS implemented [8]: “Priority access service is intended to facilitate emergency response and recovery operations in response to natural and manmade disasters and events, such as floods, earthquakes, hurricanes, and terrorist attacks. Priority access service is also intended to support both national and international emergency communications.” “Priority access service is based upon, and complies with, the FCC Second Report and Order (R&O) 00-242 (Wireless Telecommunications (WT) Docket No. 96-86). “Priority access service is intended to allow qualified and authorized National Security and Emergency Preparedness (NS/EP) users to obtain priority access to radio traffic channels and core network resources during situations when Commercial Mobile Radio Service (CMRS) provider network congestion is blocking call attempts”. WiMAX network should provide the Priority Service too. The end-to-end priority service needs to cover radio accessing, data transportation and interconnection with other networks. Priority access service only focuses on the radio accessing part of the priority service. The NS/EP authorized user shall have higher priority level to obtain radio resource to access WiMAX network to facilitate emergency recovery. End-to-end ETS is across different telecommunication networks and different countries. There are ETS standardization activities around the globe. The following standards bodies have ETS activities: • ITU (International Telecommunication Union) • IETF (Internet Engineering Task Force) • ETSI (European Telecommunications Standards Institute) • ATIS (Alliance for Telecommunications Industry Solution) • TIA (Telecommunications Industry Association) 12 IEEE C802.16m-08/1046r1 • 3GPP (3rd Generation Partnership Project) • 3GPP2 (3rd Generation Partnership Project 2) 3.2 Service Scenarios We address two types of calling scenarios. Scenarios are presented to develop the requirements and technical solutions for priority access. Scenario 1: Mobile originating call. It is for authorized user to initiate a voice, data or video call to any party using 802.16m technology. Scenario 2: Mobile terminating call. It is for authorized user to call another authorized user reachable using 802.16m technology. 3.3 Requirements The associated requirements for priority access service [1] include: • Ubiquitous Services: – Able to make a call/session in times of disaster, national emergency, or for executive/governmental communications relating to National Security / Emergency Preparedness (NS/EP). – • • • Availability: – It is available to NS/EP users at all times. – End-to-end QoS should be provided based on 802.16e QoS classes and parameters QoS Security – • It applies to voice, video, and data services “Networks must have protection against corruption and intrusion such as unauthorized access, control and traffic” Priority treatment – “ETS communications should be provided preferential end-to-end treatment so that higher communication session completion rates, as compared with public communication session completion rates, would be successfully achieved” 4 Text Proposal [---------------------------------------------------Start of Text Proposal--------------------------------------------------] Section 10 Medium Access Control Sub-Layer 10.x Network Entry 13 IEEE C802.16m-08/1046r1 Assign one or more dedicated initial ranging slot for regular user and one dedicated initial ranging slot for priority user for a larger channel bandwidth (e.g. 10 MHz). Also assign a set of dedicated codes for regular user initial ranging and another dedicated set for priority user initial ranging. Optionally, assign one or more dedicated initial ranging frames for regular user and one dedicated initial ranging frame for priority user for a smaller channel bandwidth (e.g. 5 MHz). [---------------------------------------------------End of Text Proposal--------------------------------------------------] 5. References [1] “Overview of Standards in Support of Emergency Telecommunication Service (ETS),” ATIS-pp-0100009, November 2006. [2]”Recommendations and Requirements for Networks based on WiMAX Forum Certified Products,” WiMAX Forum Release 1.5, Jan. 2007 [3] D. Staehle and R. Pries, “Comparative study of the IEEE 802.16 random access mechanisms,” IEEE NGMAST, 2007 [4] D. J. Shyy, "Interference and Delay Analysis of Mobile WiMAX Networks", OPNETWORK Conference, Aug. 2008. [5] J. You etal, “Capacity evaluation of the OFDMA-CDMA ranging subsystem in IEEE 802.16-2004”, IEEE 2005. [6] S. Azizi and X. Yang, “Requirements for ranging sequences design for IEEE 802.16m,” C802.16m-UL_ctrl-08/013r1, 2008. [7] “Wireless Priority Service (WPS) Industry Requirements Document for the Initial Operating Capability (IOC) for CDMA-based System”, Feb. 2002. [8] Wireless Priority Service (WPS) Industry Requirements for UMTS – Phase 1 – Redirection to GSM,” DHS/NCS IR Document, Version 0.3, April 2005 [9] Quality of Service Attributes for Diameter,” draft-ietf-dime-qos-attributes-02.txt [10] “Quality of Service Parameters for Usage with the AAA Framework,” draft-ietf-dime-qos-parameters-01.txt [11] “RSVP Extensions for Emergency Services,” draft-ietf-tsvwg-emergency-rsvp-03.txt [12] “QoS NSLP QSPEC Template,” draft-ietf-nsis-qspec-18.txt [13] Report ITU-R.[PPDR]: “Radiocommunication objectives and requirements for public protection and disaster relief (PPDR)” [14] Recommendation H.460.4 – Call priority designation for H.323 calls [15] Draft recommendation H.SETS – security for ETS (H.235) [16] E.106 – Description of an international emergency preference scheme (IEPS) [17] Draft Recommendation U.roec – network requirements and capabilities to support ETS [18] RFC3523: “Internet Emergency Preparedness (IEPREP) Telephony Topology Terminology” [19] TETRA: “Mobile narrowband and wideband communications for public safety applications” [20] TR41.4 TSB146: “Telecommunications – IP Telephony Infrastructure – IP Telephony Support for Emergency Calling Service) [21] 3GPP TS 22.153, “Technical Specification Group Services and System Aspects; Multimedia priority service”, Release 8. [22] 3GPP S.R0017-0, “Multimedia Priority Service (MMPS) for MMD-based Networks – Stage 1 Requirements” 14
