From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc8869.txt | 1057 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 1057 insertions(+) create mode 100644 doc/rfc/rfc8869.txt (limited to 'doc/rfc/rfc8869.txt') diff --git a/doc/rfc/rfc8869.txt b/doc/rfc/rfc8869.txt new file mode 100644 index 0000000..feeccb0 --- /dev/null +++ b/doc/rfc/rfc8869.txt @@ -0,0 +1,1057 @@ + + + + +Internet Engineering Task Force (IETF) Z. Sarker +Request for Comments: 8869 Ericsson AB +Category: Informational X. Zhu +ISSN: 2070-1721 J. Fu + Cisco Systems + January 2021 + + + Evaluation Test Cases for Interactive Real-Time Media over Wireless + Networks + +Abstract + + The Real-time Transport Protocol (RTP) is a common transport choice + for interactive multimedia communication applications. The + performance of these applications typically depends on a well- + functioning congestion control algorithm. To ensure a seamless and + robust user experience, a well-designed RTP-based congestion control + algorithm should work well across all access network types. This + document describes test cases for evaluating performances of + candidate congestion control algorithms over cellular and Wi-Fi + networks. + +Status of This Memo + + This document is not an Internet Standards Track specification; it is + published for informational purposes. + + This document is a product of the Internet Engineering Task Force + (IETF). It represents the consensus of the IETF community. It has + received public review and has been approved for publication by the + Internet Engineering Steering Group (IESG). Not all documents + approved by the IESG are candidates for any level of Internet + Standard; see Section 2 of RFC 7841. + + Information about the current status of this document, any errata, + and how to provide feedback on it may be obtained at + https://www.rfc-editor.org/info/rfc8869. + +Copyright Notice + + Copyright (c) 2021 IETF Trust and the persons identified as the + document authors. All rights reserved. + + This document is subject to BCP 78 and the IETF Trust's Legal + Provisions Relating to IETF Documents + (https://trustee.ietf.org/license-info) in effect on the date of + publication of this document. Please review these documents + carefully, as they describe your rights and restrictions with respect + to this document. Code Components extracted from this document must + include Simplified BSD License text as described in Section 4.e of + the Trust Legal Provisions and are provided without warranty as + described in the Simplified BSD License. + +Table of Contents + + 1. Introduction + 2. Cellular Network Specific Test Cases + 2.1. Varying Network Load + 2.1.1. Network Connection + 2.1.2. Simulation Setup + 2.1.3. Expected Behavior + 2.2. Bad Radio Coverage + 2.2.1. Network Connection + 2.2.2. Simulation Setup + 2.2.3. Expected Behavior + 2.3. Desired Evaluation Metrics for Cellular Test Cases + 3. Wi-Fi Networks Specific Test Cases + 3.1. Bottleneck in Wired Network + 3.1.1. Network Topology + 3.1.2. Test/Simulation Setup + 3.1.3. Typical Test Scenarios + 3.1.4. Expected Behavior + 3.2. Bottleneck in Wi-Fi Network + 3.2.1. Network Topology + 3.2.2. Test/Simulation Setup + 3.2.3. Typical Test Scenarios + 3.2.4. Expected Behavior + 3.3. Other Potential Test Cases + 3.3.1. EDCA/WMM usage + 3.3.2. Effect of Heterogeneous Link Rates + 4. IANA Considerations + 5. Security Considerations + 6. References + 6.1. Normative References + 6.2. Informative References + Contributors + Acknowledgments + Authors' Addresses + +1. Introduction + + Wireless networks (both cellular and Wi-Fi [IEEE802.11]) are an + integral and increasingly more significant part of the Internet. + Typical application scenarios for interactive multimedia + communication over wireless include video conferencing calls in a bus + or train as well as live media streaming at home. It is well known + that the characteristics and technical challenges for supporting + multimedia services over wireless are very different from those of + providing the same service over a wired network. Although the basic + test cases as defined in [RFC8867] have covered many common effects + of network impairments for evaluating RTP-based congestion control + schemes, they remain to be tested over characteristics and dynamics + unique to a given wireless environment. For example, in cellular + networks, the base station maintains individual queues per radio + bearer per user hence it leads to a different nature of interactions + between traffic flows of different users. This contrasts with a + typical wired network setting where traffic flows from all users + share the same queue at the bottleneck. Furthermore, user mobility + patterns in a cellular network differ from those in a Wi-Fi network. + Therefore, it is important to evaluate the performance of proposed + candidate RTP-based congestion control solutions over cellular mobile + networks and over Wi-Fi networks respectively. + + [RFC8868] provides guidelines for evaluating candidate algorithms and + recognizes the importance of testing over wireless access networks. + However, it does not describe any specific test cases for performance + evaluation of candidate algorithms. This document describes test + cases specifically targeting cellular and Wi-Fi networks. + +2. Cellular Network Specific Test Cases + + A cellular environment is more complicated than its wireline + counterpart since it seeks to provide services in the context of + variable available bandwidth, location dependencies, and user + mobilities at different speeds. In a cellular network, the user may + reach the cell edge, which may lead to a significant number of + retransmissions to deliver the data from the base station to the + destination and vice versa. These radio links will often act as a + bottleneck for the rest of the network and will eventually lead to + excessive delays or packet drops. An efficient retransmission or + link adaptation mechanism can reduce the packet loss probability, but + some packet losses and delay variations will remain. Moreover, with + increased cell load or handover to a congested cell, congestion in + the transport network will become even worse. Besides, there exist + certain characteristics that distinguish the cellular network from + other wireless access networks such as Wi-Fi. In a cellular network: + + * The bottleneck is often a shared link with relatively few users. + + - The cost per bit over the shared link varies over time and is + different for different users. + + - Leftover/unused resources can be consumed by other greedy + users. + + * Queues are always per radio bearer, hence each user can have many + such queues. + + * Users can experience both inter- and intra-Radio Access Technology + (RAT) handovers (see [HO-def-3GPP] for the definition of + "handover"). + + * Handover between cells or change of serving cells (as described in + [HO-LTE-3GPP] and [HO-UMTS-3GPP]) might cause user plane + interruptions, which can lead to bursts of packet losses, delay, + and/or jitter. The exact behavior depends on the type of radio + bearer. Typically, the default best-effort bearers do not + generate packet loss, instead, packets are queued up and + transmitted once the handover is completed. + + * The network part decides how much the user can transmit. + + * The cellular network has variable link capacity per user. + + - It can vary as fast as a period of milliseconds. + + - It depends on many factors (such as distance, speed, + interference, different flows). + + - It uses complex and smart link adaptation, which makes the link + behavior ever more dynamic. + + - The scheduling priority depends on the estimated throughput. + + * Both Quality of Service (QoS) and non-QoS radio bearers can be + used. + + Hence, a real-time communication application operating over a + cellular network needs to cope with a shared bottleneck link and + variable link capacity, events like handover, non-congestion-related + loss, and abrupt changes in bandwidth (both short term and long term) + due to handover, network load, and bad radio coverage. Even though + 3GPP has defined QoS bearers [QoS-3GPP] to ensure high-quality user + experience, it is still preferable for real-time applications to + behave in an adaptive manner. + + Different mobile operators deploy their own cellular networks with + their own set of network functionalities and policies. Usually, a + mobile operator network includes a range of radio access technologies + such as 3G and 4G/LTE. Looking at the specifications of such radio + technologies, it is evident that only the more recent radio + technologies can support the high bandwidth requirements from real- + time interactive video applications. Future real-time interactive + applications will impose even greater demand on cellular network + performance, which makes 4G (and beyond) radio technologies more + suitable for such genre of application. + + The key factors in defining test cases for cellular networks are: + + * Shared and varying link capacity + + * Mobility + + * Handover + + However, these factors are typically highly correlated in a cellular + network. Therefore, instead of devising separate test cases for + individual important events, we have divided the test cases into two + categories. It should be noted that the goal of the following test + cases is to evaluate the performance of candidate algorithms over the + radio interface of the cellular network. Hence, it is assumed that + the radio interface is the bottleneck link between the communicating + peers and that the core network does not introduce any extra + congestion along the path. Consequently, this document has left out + of scope the combination of multiple access technologies involving + both cellular and Wi-Fi users. In this latter case, the shared + bottleneck is likely at the wired backhaul link. These test cases + further assume a typical real-time telephony scenario where one real- + time session consists of one voice stream and one video stream. + + Even though it is possible to carry out tests over operational + cellular networks (e.g., LTE/5G), and actually such tests are already + available today, these tests cannot in general be carried out in a + deterministic fashion to ensure repeatability. The main reason is + that these networks are controlled by cellular operators, and there + exists various amounts of competing traffic in the same cell(s). In + practice, it is only in underground mines that one can carry out near + deterministic testing. Even there, it is not guaranteed either as + workers in the mines may carry with them their personal mobile + phones. Furthermore, the underground mining setting may not reflect + typical usage patterns in an urban setting. We, therefore, recommend + that a cellular network simulator be used for the test cases defined + in this document, for example -- the LTE simulator in [NS-3]. + +2.1. Varying Network Load + + The goal of this test is to evaluate the performance of the candidate + congestion control algorithm under varying network load. The network + load variation is created by adding and removing network users, + a.k.a. User Equipment (UE), during the simulation. In this test + case, each user/UE in the media session is an endpoint following RTP- + based congestion control. User arrivals follow a Poisson + distribution proportional to the length of the call, to keep the + number of users per cell fairly constant during the evaluation + period. At the beginning of the simulation, there should be enough + time to warm up the network. This is to avoid running the evaluation + in an empty network where network nodes have empty buffers and low + interference at the beginning of the simulation. This network + initialization period should be excluded from the evaluation period. + Typically, the evaluation period starts 30 seconds after test + initialization. + + This test case also includes user mobility and some competing + traffic. The latter includes both the same types of flows (with same + adaptation algorithms) and different types of flows (with different + services and congestion control schemes). + +2.1.1. Network Connection + + Each mobile user is connected to a fixed user. The connection + between the mobile user and fixed user consists of a cellular radio + access, an Evolved Packet Core (EPC), and an Internet connection. + The mobile user is connected to the EPC using cellular radio access + technology, which is further connected to the Internet. At the other + end, the fixed user is connected to the Internet via a wired + connection with sufficiently high bandwidth, for instance, 10 Gbps, + so that the system bottleneck is on the cellular radio access + interface. The wired connection in this setup does not introduce any + network impairments to the test; it only adds 10 ms of one-way + propagation delay. + + The path from the fixed user to the mobile users is defined as + "downlink", and the path from the mobile users to the fixed user is + defined as "uplink". We assume that only uplink or downlink is + congested for mobile users. Hence, we recommend that the uplink and + downlink simulations are run separately. + + uplink + ++))) +--------------------------> + ++-+ ((o)) + | | / \ +-------+ +------+ +---+ + +--+ / \----+ +-----+ +----+ | + / \ +-------+ +------+ +---+ + UE BS EPC Internet fixed + <--------------------------+ + downlink + + Figure 1: Simulation Topology + +2.1.2. Simulation Setup + + The values enclosed within "[ ]" for the following simulation + attributes follow the same notion as in [RFC8867]. The desired + simulation setup is as follows: + + Radio environment: + + Deployment and propagation model: 3GPP case 1 (see + [HO-deploy-3GPP]) + + Antenna: Multiple-Input and Multiple-Output (MIMO), 2D or 3D + antenna pattern + + Mobility: [3 km/h, 30 km/h] + + Transmission bandwidth: 10 MHz + + Number of cells: multi-cell deployment (3 cells per Base Station + (BS) * 7 BS) = 21 cells + + Cell radius: 166.666 meters + + Scheduler: Proportional fair with no priority + + Bearer: Default bearer for all traffic + + Active Queue Management (AQM) settings: AQM [on, off] + + End-to-end Round Trip Time (RTT): [40 ms, 150 ms] + + User arrival model: Poisson arrival model + + User intensity: + + Downlink user intensity: {0.7, 1.4, 2.1, 2.8, 3.5, 4.2, 4.9, 5.6, + 6.3, 7.0, 7.7, 8.4, 9,1, 9.8, 10.5} + + Uplink user intensity: {0.7, 1.4, 2.1, 2.8, 3.5, 4.2, 4.9, 5.6, + 6.3, 7.0} + + Simulation duration: 91 s + + Evaluation period: 30 s - 60 s + + Media traffic: + + Media type: Video + + Media direction: [uplink, downlink] + + Number of media sources per user: One (1) + + Media duration per user: 30 s + + Media source: same as defined in Section 4.3 of [RFC8867] + + Media type: Audio + + Media direction: [uplink, downlink] + + Number of media sources per user: One (1) + + Media duration per user: 30 s + + Media codec: Constant Bit Rate (CBR) + + Media bitrate: 20 Kbps + + Adaptation: off + + Other traffic models: + + Downlink simulation: Maximum of 4 Mbps/cell (web browsing or FTP + traffic following default TCP congestion control [RFC5681]) + + Uplink simulation: Maximum of 2 Mbps/cell (web browsing or FTP + traffic following default TCP congestion control [RFC5681]) + +2.1.3. Expected Behavior + + The investigated congestion control algorithms should result in + maximum possible network utilization and stability in terms of rate + variations, lowest possible end-to-end frame latency, network + latency, and Packet Loss Rate (PLR) at different cell load levels. + +2.2. Bad Radio Coverage + + The goal of this test is to evaluate the performance of the candidate + congestion control algorithm when users visit part of the network + with bad radio coverage. The scenario is created by using a larger + cell radius than that in the previous test case. In this test case, + each user/UE in the media session is an endpoint following RTP-based + congestion control. User arrivals follow a Poisson distribution + proportional to the length of the call, to keep the number of users + per cell fairly constant during the evaluation period. At the + beginning of the simulation, there should be enough time to warm up + the network. This is to avoid running the evaluation in an empty + network where network nodes have empty buffers and low interference + at the beginning of the simulation. This network initialization + period should be excluded from the evaluation period. Typically, the + evaluation period starts 30 seconds after test initialization. + + This test case also includes user mobility and some competing + traffic. The latter includes the same kind of flows (with same + adaptation algorithms). + +2.2.1. Network Connection + + Same as defined in Section 2.1.1. + +2.2.2. Simulation Setup + + The desired simulation setup is the same as the Varying Network Load + test case defined in Section 2.1 except for the following changes: + + Radio environment: Same as defined in Section 2.1.2 except for the + following: + + Deployment and propagation model: 3GPP case 3 (see + [HO-deploy-3GPP]) + + Cell radius: 577.3333 meters + + Mobility: 3 km/h + + User intensity: {0.7, 1.4, 2.1, 2.8, 3.5, 4.2, 4.9, 5.6, 6.3, 7.0} + + Media traffic model: Same as defined in Section 2.1.2 + + Other traffic models: + + Downlink simulation: Maximum of 2 Mbps/cell (web browsing or FTP + traffic following default TCP congestion control [RFC5681]) + + Uplink simulation: Maximum of 1 Mbps/cell (web browsing or FTP + traffic following default TCP congestion control [RFC5681]) + +2.2.3. Expected Behavior + + The investigated congestion control algorithms should result in + maximum possible network utilization and stability in terms of rate + variations, lowest possible end-to-end frame latency, network + latency, and Packet Loss Rate (PLR) at different cell load levels. + +2.3. Desired Evaluation Metrics for Cellular Test Cases + + The evaluation criteria document [RFC8868] defines the metrics to be + used to evaluate candidate algorithms. Considering the nature and + distinction of cellular networks, we recommend that at least the + following metrics be used to evaluate the performance of the + candidate algorithms: + + * Average cell throughput (for all cells), shows cell utilization. + + * Application sending and receiving bitrate, goodput. + + * Packet Loss Rate (PLR). + + * End-to-end media frame delay. For video, this means the delay + from capture to display. + + * Transport delay. + + * Algorithm stability in terms of rate variation. + +3. Wi-Fi Networks Specific Test Cases + + Given the prevalence of Internet access links over Wi-Fi, it is + important to evaluate candidate RTP-based congestion control + solutions over test cases that include Wi-Fi access links. Such + evaluations should highlight the inherently different characteristics + of Wi-Fi networks in contrast to their wired counterparts: + + * The wireless radio channel is subject to interference from nearby + transmitters, multipath fading, and shadowing. These effects lead + to fluctuations in the link throughput and sometimes an error- + prone communication environment. + + * Available network bandwidth is not only shared over the air + between concurrent users but also between uplink and downlink + traffic due to the half-duplex nature of the wireless transmission + medium. + + * Packet transmissions over Wi-Fi are susceptible to contentions and + collisions over the air. Consequently, traffic load beyond a + certain utilization level over a Wi-Fi network can introduce + frequent collisions over the air and significant network overhead, + as well as packet drops due to buffer overflow at the + transmitters. This, in turn, leads to excessive delay, + retransmissions, packet losses, and lower effective bandwidth for + applications. Note further that the collision-induced delay and + loss patterns are qualitatively different from those caused by + congestion over a wired connection. + + * The IEEE 802.11 standard (i.e., Wi-Fi) supports multi-rate + transmission capabilities by dynamically choosing the most + appropriate modulation and coding scheme (MCS) for the given + received signal strength. A different choice in the MCS Index + leads to different physical-layer (PHY-layer) link rates and + consequently different application-layer throughput. + + * The presence of legacy devices (e.g., ones operating only in IEEE + 802.11b) at a much lower PHY-layer link rate can significantly + slow down the rest of a modern Wi-Fi network. As discussed in + [Heusse2003], the main reason for such anomaly is that it takes + much longer to transmit the same packet over a slower link than + over a faster link, thereby consuming a substantial portion of air + time. + + * Handover from one Wi-Fi Access Point (AP) to another may lead to + excessive packet delays and losses during the process. + + * IEEE 802.11e has introduced the Enhanced Distributed Channel + Access (EDCA) mechanism to allow different traffic categories to + contend for channel access using different random back-off + parameters. This mechanism is a mandatory requirement for the Wi- + Fi Multimedia (WMM) certification in Wi-Fi Alliance. It allows + for prioritization of real-time application traffic such as voice + and video over non-urgent data transmissions (e.g., file + transfer). + + In summary, the presence of Wi-Fi access links in different network + topologies can exert different impacts on the network performance in + terms of application-layer effective throughput, packet loss rate, + and packet delivery delay. These, in turn, will influence the + behavior of end-to-end real-time multimedia congestion control. + + Unless otherwise mentioned, the test cases in this section choose the + PHY- and MAC-layer parameters based on the IEEE 802.11n standard. + Statistics collected from enterprise Wi-Fi networks show that the two + dominant physical modes are 802.11n and 802.11ac, accounting for 41% + and 58% of connected devices, respectively. As Wi-Fi standards + evolve over time -- for instance, with the introduction of the + emerging Wi-Fi 6 (based on IEEE 802.11ax) products -- the PHY- and + MAC-layer test case specifications need to be updated accordingly to + reflect such changes. + + Typically, a Wi-Fi access network connects to a wired infrastructure. + Either the wired or the Wi-Fi segment of the network can be the + bottleneck. The following sections describe basic test cases for + both scenarios separately. The same set of performance metrics as in + [RFC8867]) should be collected for each test case. + + We recommend carrying out the test cases as defined in this document + using a simulator, such as [NS-2] or [NS-3]. When feasible, it is + encouraged to perform testbed-based evaluations using Wi-Fi access + points and endpoints running up-to-date IEEE 802.11 protocols, such + as 802.11ac and the emerging Wi-Fi 6, so as to verify the viability + of the candidate schemes. + +3.1. Bottleneck in Wired Network + + The test scenarios below are intended to mimic the setup of video + conferencing over Wi-Fi connections from the home. Typically, the + Wi-Fi home network is not congested, and the bottleneck is present + over the wired home access link. Although it is expected that test + evaluation results from this section are similar to those in + [RFC8867], it is still worthwhile to run through these tests as + sanity checks. + +3.1.1. Network Topology + + Figure 2 shows the network topology of Wi-Fi test cases. The test + contains multiple mobile nodes (MNs) connected to a common Wi-Fi AP + and their corresponding wired clients on fixed nodes (FNs). Each + connection carries either an RTP-based media flow or a TCP traffic + flow. Directions of the flows can be uplink (i.e., from mobile nodes + to fixed nodes), downlink (i.e., from fixed nodes to mobile nodes), + or bidirectional. The total number of uplink/downlink/bidirectional + flows for RTP-based media traffic and TCP traffic are denoted as N + and M, respectively. + + Uplink + +----------------->+ + +------+ +------+ + | MN_1 |)))) /=====| FN_1 | + +------+ )) // +------+ + . )) // . + . )) // . + . )) // . + +------+ +----+ +-----+ +------+ + | MN_N | ))))))) | | | |========| FN_N | + +------+ | | | | +------+ + | AP |=========| FN0 | + +----------+ | | | | +----------+ + | MN_tcp_1 | )))) | | | |======| FN_tcp_1 | + +----------+ +----+ +-----+ +----------+ + . )) \\ . + . )) \\ . + . )) \\ . + +----------+ )) \\ +----------+ + | MN_tcp_M |))) \=====| FN_tcp_M | + +----------+ +----------+ + +<-----------------+ + Downlink + + Figure 2: Network Topology for Wi-Fi Test Cases + +3.1.2. Test/Simulation Setup + + Test duration: 120 s + + Wi-Fi network characteristics: + + Radio propagation model: Log-distance path loss propagation model + (see [NS3WiFi]) + + PHY- and MAC-layer configuration: IEEE 802.11n + + MCS Index at 11: Raw data rate at 52 Mbps, 16-QAM (Quadrature + amplitude modulation) and 1/2 coding rate + + Wired path characteristics: + + Path capacity: 1 Mbps + + One-way propagation delay: 50 ms + + Maximum end-to-end jitter: 30 ms + + Bottleneck queue type: Drop tail + + Bottleneck queue size: 300 ms + + Path loss ratio: 0% + + Application characteristics: + + Media traffic: + + Media type: Video + + Media direction: See Section 3.1.3 + + Number of media sources (N): See Section 3.1.3 + + Media timeline: + + Start time: 0 s + + End time: 119 s + + Competing traffic: + + Type of sources: Long-lived TCP or CBR over UDP + + Traffic direction: See Section 3.1.3 + + Number of sources (M): See Section 3.1.3 + + Congestion control: Default TCP congestion control [RFC5681] + or CBR traffic over UDP + + Traffic timeline: See Section 3.1.3 + +3.1.3. Typical Test Scenarios + + Single uplink RTP-based media flow: N=1 with uplink direction and + M=0. + + One pair of bidirectional RTP-based media flows: N=2 (i.e., one + uplink flow and one downlink flow); M=0. + + One pair of bidirectional RTP-based media flows: N=2; one uplink on- + off CBR flow over UDP: M=1 (uplink). The CBR flow has ON time at + t=0s-60s and OFF time at t=60s-119s. + + One pair of bidirectional RTP-based media flows: N=2; one uplink + off-on CBR flow over UDP: M=1 (uplink). The CBR flow has OFF time + at t=0s-60s and ON time at t=60s-119s. + + One RTP-based media flow competing against one long-lived TCP flow + in the uplink direction: N=1 (uplink) and M=1 (uplink). The TCP + flow has start time at t=0s and end time at t=119s. + +3.1.4. Expected Behavior + + Single uplink RTP-based media flow: The candidate algorithm is + expected to detect the path capacity constraint, to converge to + the bottleneck link capacity, and to adapt the flow to avoid + unwanted oscillations when the sending bit rate is approaching the + bottleneck link capacity. No excessive oscillations in the media + rate should be present. + + Bidirectional RTP-based media flows: The candidate algorithm is + expected to converge to the bottleneck capacity of the wired path + in both directions despite the presence of measurement noise over + the Wi-Fi connection. In the presence of background TCP or CBR + over UDP traffic, the rate of RTP-based media flows should adapt + promptly to the arrival and departure of background traffic flows. + + One RTP-based media flow competing with long-lived TCP flow in the + uplink direction: The candidate algorithm is expected to avoid + congestion collapse and to stabilize at a fair share of the + bottleneck link capacity. + +3.2. Bottleneck in Wi-Fi Network + + The test cases in this section assume that the wired segment along + the media path is well-provisioned, whereas the bottleneck exists + over the Wi-Fi access network. This is to mimic the application + scenarios typically encountered by users in an enterprise environment + or at a coffee house. + +3.2.1. Network Topology + + Same as defined in Section 3.1.1. + +3.2.2. Test/Simulation Setup + + Test duration: 120 s + + Wi-Fi network characteristics: + + Radio propagation model: Log-distance path loss propagation model + (see [NS3WiFi]) + + PHY- and MAC-layer configuration: IEEE 802.11n + + MCS Index at 11: Raw data rate at 52 Mbps, 16-QAM (Quadrature + amplitude modulation) and 1/2 coding rate + + Wired path characteristics: + + Path capacity: 100 Mbps + + One-Way propagation delay: 50 ms + + Maximum end-to-end jitter: 30 ms + + Bottleneck queue type: Drop tail + + Bottleneck queue size: 300 ms + + Path loss ratio: 0% + + Application characteristics + + Media traffic: + + Media type: Video + + Media direction: See Section 3.2.3 + + Number of media sources (N): See Section 3.2.3 + + Media timeline: + + Start time: 0 s + + End time: 119 s + + Competing traffic: + + Type of sources: long-lived TCP or CBR over UDP + + Number of sources (M): See Section 3.2.3 + + Traffic direction: See Section 3.2.3 + + Congestion control: Default TCP congestion control [RFC5681] + or CBR traffic over UDP + + Traffic timeline: See Section 3.2.3 + +3.2.3. Typical Test Scenarios + + This section describes a few test scenarios that are deemed as + important for understanding the behavior of a candidate RTP-based + congestion control scheme over a Wi-Fi network. + + Multiple RTP-based media flows sharing the wireless downlink: N=16 + (all downlink); M=0. This test case is for studying the impact of + contention on the multiple concurrent media flows. For an 802.11n + network, given the MCS Index of 11 and the corresponding link rate + of 52 Mbps, the total application-layer throughput (assuming + reasonable distance, low interference, and infrequent contentions + caused by competing streams) is around 20 Mbps. A total of N=16 + RTP-based media flows (with a maximum rate of 1.5 Mbps each) are + expected to saturate the wireless interface in this experiment. + Evaluation of a given candidate scheme should focus on whether the + downlink media flows can stabilize at a fair share of the total + application-layer throughput. + + Multiple RTP-based media flows sharing the wireless uplink: N=16 + (all uplink); M=0. When multiple clients attempt to transmit + media packets uplink over the Wi-Fi network, they introduce more + frequent contentions and potential collisions. Per-flow + throughput is expected to be lower than that in the previous + downlink-only scenario. Evaluation of a given candidate scheme + should focus on whether the uplink flows can stabilize at a fair + share of the total application-layer throughput. + + Multiple bidirectional RTP-based media flows: N=16 (8 uplink and 8 + downlink); M=0. The goal of this test is to evaluate the + performance of the candidate scheme in terms of bandwidth fairness + between uplink and downlink flows. + + Multiple bidirectional RTP-based media flows with on-off CBR + traffic over UDP: N=16 (8 uplink and 8 downlink); M=5 (uplink). The + goal of this test is to evaluate the adaptation behavior of the + candidate scheme when its available bandwidth changes due to the + departure of background traffic. The background traffic consists + of several (e.g., M=5) CBR flows transported over UDP. These + background flows are ON at time t=0-60s and OFF at time t=61-120s. + + Multiple bidirectional RTP-based media flows with off-on CBR + traffic over UDP: N=16 (8 uplink and 8 downlink); M=5 (uplink). The + goal of this test is to evaluate the adaptation behavior of the + candidate scheme when its available bandwidth changes due to the + arrival of background traffic. The background traffic consists of + several (e.g., M=5) parallel CBR flows transported over UDP. + These background flows are OFF at time t=0-60s and ON at times + t=61-120s. + + Multiple bidirectional RTP-based media flows in the presence of + background TCP traffic: N=16 (8 uplink and 8 downlink); M=5 + (uplink). The goal of this test is to evaluate how RTP-based + media flows compete against TCP over a congested Wi-Fi network for + a given candidate scheme. TCP flows have start time at t=40s and + end time at t=80s. + + Varying number of RTP-based media flows: A series of tests can be + carried out for the above test cases with different values of N, + e.g., N=[4, 8, 12, 16, 20]. The goal of this test is to evaluate + how a candidate scheme responds to varying traffic load/demand + over a congested Wi-Fi network. The start times of the media + flows are randomly distributed within a window of t=0-10s; their + end times are randomly distributed within a window of t=110-120s. + +3.2.4. Expected Behavior + + Multiple downlink RTP-based media flows: Each media flow is expected + to get its fair share of the total bottleneck link bandwidth. + Overall bandwidth usage should not be significantly lower than + that experienced by the same number of concurrent downlink TCP + flows. In other words, the behavior of multiple concurrent TCP + flows will be used as a performance benchmark for this test + scenario. The end-to-end delay and packet loss ratio experienced + by each flow should be within an acceptable range for real-time + multimedia applications. + + Multiple uplink RTP-based media flows: Overall bandwidth usage by + all media flows should not be significantly lower than that + experienced by the same number of concurrent uplink TCP flows. In + other words, the behavior of multiple concurrent TCP flows will be + used as a performance benchmark for this test scenario. + + Multiple bidirectional RTP-based media flows with dynamic + background traffic carrying CBR flows over UDP: The media flows are + expected to adapt in a timely fashion to the changes in available + bandwidth introduced by the arrival/departure of background + traffic. + + Multiple bidirectional RTP-based media flows with dynamic + background traffic over TCP: During the presence of TCP background + flows, the overall bandwidth usage by all media flows should not + be significantly lower than those achieved by the same number of + bidirectional TCP flows. In other words, the behavior of multiple + concurrent TCP flows will be used as a performance benchmark for + this test scenario. All downlink media flows are expected to + obtain similar bandwidth as each other. The throughput of each + media flow is expected to decrease upon the arrival of TCP + background traffic and, conversely, increase upon their departure. + Both reactions should occur in a timely fashion, for example, + within 10s of seconds. + + Varying number of bidirectional RTP-based media flows: The test + results for varying values of N -- while keeping all other + parameters constant -- is expected to show steady and stable per- + flow throughput for each value of N. The average throughput of + all media flows is expected to stay constant around the maximum + rate when N is small, then gradually decrease with increasing + value of N till it reaches the minimum allowed rate, beyond which + the offered load to the Wi-Fi network exceeds its capacity (i.e., + with a very large value of N). + +3.3. Other Potential Test Cases + +3.3.1. EDCA/WMM usage + + The EDCA/WMM mechanism defines prioritized QoS for four traffic + classes (or Access Categories). RTP-based real-time media flows + should achieve better performance in terms of lower delay and fewer + packet losses with EDCA/WMM enabled when competing against non- + interactive background traffic such as file transfers. When most of + the traffic over Wi-Fi is dominated by media, however, turning on WMM + may degrade performance since all media flows now attempt to access + the wireless transmission medium more aggressively, thereby causing + more frequent collisions and collision-induced losses. This is a + topic worthy of further investigation. + +3.3.2. Effect of Heterogeneous Link Rates + + As discussed in [Heusse2003], the presence of clients operating over + slow PHY-layer link rates (e.g., a legacy 802.11b device) connected + to a modern network may adversely impact the overall performance of + the network. Additional test cases can be devised to evaluate the + effect of clients with heterogeneous link rates on the performance of + the candidate congestion control algorithm. Such test cases, for + instance, can specify that the PHY-layer link rates for all clients + span over a wide range (e.g., 2 Mbps to 54 Mbps) for investigating + its effect on the congestion control behavior of the real-time + interactive applications. + +4. IANA Considerations + + This document has no IANA actions. + +5. Security Considerations + + The security considerations in [RFC8868] and the relevant congestion + control algorithms apply. The principles for congestion control are + described in [RFC2914], and in particular, any new method must + implement safeguards to avoid congestion collapse of the Internet. + + Given the difficulty of deterministic wireless testing, it is + recommended and expected that the tests described in this document + would be done via simulations. However, in the case where these test + cases are carried out in a testbed setting, the evaluation should + take place in a controlled lab environment. In the testbed, the + applications, simulators, and network nodes ought to be well-behaved + and should not impact the desired results. It is important to take + appropriate caution to avoid leaking nonresponsive traffic with + unproven congestion avoidance behavior onto the open Internet. + +6. References + +6.1. Normative References + + [HO-deploy-3GPP] + 3GPP, "Physical layer aspects for evolved Universal + Terrestrial Radio Access (UTRA)", TS 25.814, October 2006, + . + + [IEEE802.11] + IEEE, "Standard for Information technology-- + Telecommunications and information exchange between + systems Local and metropolitan area networks--Specific + requirements Part 11: Wireless LAN Medium Access Control + (MAC) and Physical Layer (PHY) Specifications", + IEEE 802.11-2012, + . + + [NS3WiFi] "ns3::YansWifiChannel Class Reference", + . + + [RFC5681] Allman, M., Paxson, V., and E. Blanton, "TCP Congestion + Control", RFC 5681, DOI 10.17487/RFC5681, September 2009, + . + + [RFC8867] Sarker, Z., Singh, V., Zhu, X., and M. Ramalho, "Test + Cases for Evaluating Congestion Control for Interactive + Real-Time Media", RFC 8867, DOI 10.17487/RFC8867, January + 2021, . + + [RFC8868] Singh, V., Ott, J., and S. Holmer, "Evaluating Congestion + Control for Interactive Real-Time Media", RFC 8868, + DOI 10.17487/RFC8868, January 2021, + . + +6.2. Informative References + + [Heusse2003] + Heusse, M., Rousseau, F., Berger-Sabbatel, G., and A. + Duda, "Performance anomaly of 802.11b", IEEE INFOCOM 2003, + Twenty-second Annual Joint Conference of the IEEE Computer + and Communications Societies, + DOI 10.1109/INFCOM.2003.1208921, March 2003, + . + + [HO-def-3GPP] + 3GPP, "Vocabulary for 3GPP Specifications", 3GPP + TS 21.905, December 2009, . + + [HO-LTE-3GPP] + 3GPP, "Evolved Universal Terrestrial Radio Access + (E-UTRA); Radio Resource Control (RRC); Protocol + specification", 3GPP TS 36.331, December 2011, + . + + [HO-UMTS-3GPP] + 3GPP, "Radio Resource Control (RRC); Protocol + specification", 3GPP TS 25.331, December 2011, + . + + [NS-2] "ns-2", December 2014, + . + + [NS-3] "ns-3 Network Simulator", . + + [QoS-3GPP] 3GPP, "Policy and charging control architecture", 3GPP + TS 23.203, June 2011, . + + [RFC2914] Floyd, S., "Congestion Control Principles", BCP 41, + RFC 2914, DOI 10.17487/RFC2914, September 2000, + . + +Contributors + + The following individuals contributed to the design, implementation, + and verification of the proposed test cases during earlier stages of + this work. They have helped to validate and substantially improve + this specification. + + Ingemar Johansson of Ericsson AB + contributed to the description and validation of cellular test cases + during the earlier stage of this document. + + Wei-Tian Tan of Cisco Systems designed and set up a + Wi-Fi testbed for evaluating parallel video conferencing streams, + based upon which proposed Wi-Fi test cases are described. He also + recommended additional test cases to consider, such as the impact of + EDCA/WMM usage. + + Michael A. Ramalho of AcousticComms Consulting + (previously at Cisco Systems) applied lessons from Cisco's internal + experimentation to the draft versions of the document. He also + worked on validating the proposed test cases in a virtual-machine- + based lab setting. + +Acknowledgments + + The authors would like to thank Tomas Frankkila, Magnus Westerlund, + Kristofer Sandlund, Sergio Mena de la Cruz, and Mirja Kühlewind for + their valuable inputs and review comments regarding this document. + +Authors' Addresses + + Zaheduzzaman Sarker + Ericsson AB + Torshamnsgatan 23 + SE-164 83 Stockholm + Sweden + + Phone: +46 10 717 37 43 + Email: zaheduzzaman.sarker@ericsson.com + + + Xiaoqing Zhu + Cisco Systems + Building 4 + 12515 Research Blvd + Austin, TX 78759 + United States of America + + Email: xiaoqzhu@cisco.com + + + Jiantao Fu + Cisco Systems + 771 Alder Drive + Milpitas, CA 95035 + United States of America + + Email: jianfu@cisco.com -- cgit v1.2.3