Private:Ahmed Reading Summaries

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Will summarize the readings here..

Peer-to-Peer and SVC

  • Peer-Driven Video Streaming: Multiple Descriptions versus Layering
  • Layered Coding vs. Multiple Descriptions for Video Streaming over Multiple Paths
  • Evaluation of the H.264 Scalable Video Coding in Error Prone IP Networks
  • Overview of the Scalable Video Coding Extension of the H.264/AVC Standard
  • Enabling Adaptive Video Streaming in P2P Systems

Long Term Evolution (LTE)

  • Mobile Video Transmission Using Scalable Video Coding
  • LTE - An Introduction
  • Optimal Transmission Scheduling for Scalable Wireless Video Broadcast with Rateless Erasure Correction Code
  • Dynamic Session Control for Scalable Video Coding over IMS
  • Scheduling and Resource Allocation for SVC Streaming over OFDM Downlink Systems
  • Mobile Broadband: Including WiMAX and LTE
    • Chapter-11: Long Term Evolution of 3GPP
  • 3G Evolution HSPA and LTE for Mobile Broadband
    • Chapter-11: MBMS: Multimedia Broadcast Multicast Service
  • The UMTS Long Term Evolution: From Theory to Practice
    • Chapter-2: Network Architecture
    • Chapter-14: Broadcast Operation

Acronyms

  • 3GPP 3rd Generation Partnership Project
  • BM-SC Broadcast Multicast Service Centre
  • CN Core Network
  • CP Cyclic Prefix
  • EPC Evolved Packet Core
  • EPS Evolved Packet System
  • ICI InterCell Interference
  • LTE Long Term Evolution
  • MANE Media-Aware Network Element
  • MBMS Multimedia Broadcast Multicast Service
  • MIMO Multiple Input Multiple Output
  • OFDM Orthogonal Frequency Division Multiplexing
  • OFDMA Orthogonal Frequency Division Multiple Access
  • SAE System Architecture Evolution
  • SC-FDMA Single Carrier Frequency Division Multiple Access
  • TTI Transmission Time Interval
  • UE User Equipment
  • UTRAN UMTS Terrestrial Radio Access Network


Long Term Evolution of 3GPP

LTE PHY Layer
  • Based on OFDMA with cyclic prefix in downlink, and on SC-FDMA with a cyclic prefix in the uplink
  • Three duplexing modes are supported: full duplex FDD, half duplex FDD, and TDD
  • Two frame structure types:
    • Type-1 shared by both full- and half-duplex FDD
    • Type-2 applicable to TDD
  • Type-1 radio frame has a length of 10 ms and contains 20 slots (slot duration is 0.5 ms)
  • Two adjacent slots constitute a subframe of length 1 ms
  • Supported modulation schemes are: QPSK, 16QAM, 64QAM
  • Broadcast channel only uses QPSK
  • Maximum information block size = 6144 bits
  • CRC-24 used for error detection
Type-1 Frame
Type-2 Frame
OFDMA Downlink
  • Scheduler in eNB (base station) allocates resource blocks (which are the smallest elements of resource allocation) to users for predetermined amount of time
  • Slots consist of either 6 (for long cyclic prefix) or 7 (for short cyclic prefix) OFDM symbols
  • Longer cyclic prefixes are desired to address longer fading
  • Number of available subcarriers changes depending on transmission bandwidth (but subcarrier spacing is fixed)
  • To enable channel estimation in OFDM transmission, known reference symbols are inserted into the OFDM time-frequency grid. In LTE, these reference symbols are jointly referred to as downlink reference signals.
  • Three types of reference signals are defined for the LTE downlink:
    • Cell-specific downlink reference signals
      • transmitted in every downlink subframe, and span the entire downlink cell bandwidth.
    • UE-specific reference signal
      • only transmitted within the resource blocks assigned for DL-SCH transmission to that specific terminal
    • MBSFN reference signals


Downlink Resource Block
Slot Structure
Structure of cell-specific reference signal within a pair of resource blocks


LTE MAC Layer
  • eNB scheduler controls the time/frequency resources for a given time for uplink and downlink
  • Scheduler dynamically allocates resources to UEs at each Transmission Time Interval (TTI)
  • Depending on channel conditions, scheduler selects best multiplexing for UE
  • Downlink LTE considers the following schemes as a scheduler algorithm:
    • Frequency Selective Scheduling (FSS)
    • Frequency Diverse Scheduling (FDS)
    • Proportional Fair Scheduling (PFS)
  • Link adaptation is performed through adaptive modulation and coding


LTE Radio Interface Architecture

  • Data to be transmitted in the downlink enters the processing chain in the form of IP packets on one of the SAE bearers
  • IP packets are passed through multiple protocol entities:
    • Packet Data Convergence Protocol (PDCP) performs IP header compression, to reduce the number of bits to transmit over the radio interface, based on Robust Header Compression (ROHC) in addition to ciphering and integrity protection of the transmitted data
    • Radio Link Control (RLC) is responsible for segmentation/concatenation, retransmission handling, and in-sequence delivery to higher layers
      • offers services to the PDCP in the form of radio bearers
    • Medium Access Control (MAC) handles hybrid-ARQ retransmissions and uplink and downlink scheduling at the eNodeB
      • offers services to the RLC in the form of logical channels
    • Physical Layer (PHY) handles coding/decoding, modulation/demodulation, multi-antenna mapping, and other typical physical layer functions
      • offers services to the MAC layer in the form of transport channels
RLC
  • Depending on the scheduler decision, a certain amount of data is selected for transmission from the RLC SDU buffer and the SDUs are segmented/concatenated to create the RLC PDU. Thus, for LTE the RLC PDU size varies dynamically
  • In each RLC PDU, a header is included, containing, among other things, a sequence number used for in-sequence delivery and by the retransmission mechanism
  • A retransmission protocol operates between the RLC entities in the receiver and transmitter. By monitoring the sequence numbers of the incoming PDUs, the receiving RLC can identify missing PDUs
  • Although the RLC is capable of handling transmission errors due to noise, unpredictable channel variations, etc., error-free delivery is in most cases handled by the MAC-based hybrid-ARQ protocol
MAC
  • A logical channel is defined by the type of information it carries and is generally classified as:
    • a control channel, used for transmission of control and configuration information necessary for operating an LTE system
    • a traffic channel, used for the user data
  • A transport channel is defined by how and with what characteristics the information is transmitted over the radio interface
  • Data on a transport channel is organized into transport blocks. In each Transmission Time Interval (TTI), at most one transport block of a certain size is transmitted over the radio interface to/from a mobile terminal in absence of spatial multiplexing
  • Associated with each transport block is a Transport Format (TF), specifying how the transport block is to be transmitted over the radio interface (it includes information such as transport-block size, the modulation scheme, and the antenna mapping)
  • By varying the transport format, the MAC layer can realize different data rates. Rate control is therefore also known as transport-format selection
  • In LTE, radio access is shared-channel transmission, that is time–frequency resources are dynamically shared between users. The scheduler is part of the MAC layer and controls the assignment of uplink and downlink resources
  • The downlink scheduler (better viewed as a separate entity although part of the MAC layer) is responsible for dynamically controlling the terminal(s) to transmit to and, for each of these terminals, the set of resource blocks upon which the terminal’s DL-SCH should be transmitted
  • The scheduling strategy is implementation specific and not specified by 3GPP
    • the overall goal of most schedulers is to take advantage of the channel variations between mobile terminals and preferably schedule transmissions to a mobile terminal on resources with advantageous channel condition
  • Most scheduling strategies need information about:
    • channel conditions at the terminal
    • buffer status and priorities of the different data flows
    • interference situation in neighboring cells (if some form of interference coordination is implemented)
  • Note that in addition to time domain scheduling, LTE also enables channel-dependent scheduling in the frequency domain
  • The mobile terminal transmits channel-status reports reflecting the instantaneous channel quality in the time and frequency domains, in addition to information necessary to determine the appropriate antenna processing in case of spatial multiplexing
  • Interference coordination, which tries to control the inter-cell interference on a slow basis, is also part of the scheduler
  • Hybrid ARQ is not applicable for all types of traffic (broadcast transmissions typically do not rely on hybrid ARQ). Hence, hybrid ARQ is only supported for the DL-SCH and the UL-SCH
  • In hybrid ARQ, multiple parallel stop-and-wait processes are used (this can result in data being delivered from the hybrid-ARQ mechanism out-of-sequence, in-sequence delivery is ensured by the RLC layer)
Physical Layer
  • In the downlink, the DL-SCH is the main channel for data transmission, but the processing for PCH and MCH is similar
  • A CRC, used for error detection in the receiver, is attached, followed by Turbo coding for error correction
  • Rate matching is used not only to match the number of coded bits to the amount of resources allocated for the DL-SCH transmission, but also to generate the different redundancy versions as controlled by the hybrid-ARQ protocol
  • After rate matching, the coded bits are modulated using QPSK, 16QAM, or 64QAM, followed by antenna mapping
  • The output of the antenna processing is mapped to the physical resources used for the DL-SCH
  • The resources, as well as the transport-block size and the modulation scheme, are under control of the scheduler (of the MAC layer)
  • For the broadcast of system information on the BCH, a mobile terminal must be able to receive this information channel as one of the first steps prior to accessing the system. Consequently, the transmission format must be known to the terminals a priori and there is no dynamic control of any of the transmission parameters from the MAC layer in this case


MBMS

  • Introduced for WCDMA (UMTS) in Release 6
  • Supports multicast/broadcast services in a cellular system
  • Same content is transmitted to multiple users located in a specific area (MBMS service area) in a unidirectional fashion
  • MBMS extends existing 3GPP architecture by introducing:
    • MBMS Bearer Service delivers IP multicast datagrams to multiple receivers using minimum radio and network resources and provides an efficient and scalable means to distribute multimedia content to mobile phones
    • MBMS User Services
      • streaming services - a continuous data flow of audio and/or video is delivered to the user's handset
      • download services - data for the file is delivered in a scheduled transmission timeslot
  • The p-t-m MBMS Bearer Service does neither allow control, mode adaptation, nor retransmitting lost radio packets (thus, QoS provided for transport of multimedia applications is in general not sufficiently high to support a significant portion of the users for either download or streaming applications)
  • Consequently, 3GPP included an application layer FEC based on Raptor codes for MBMS
  • MBMS User Services may be distributed over p-t-p links if decided to be more efficient
  • The Broadcast Multicast Service Center (BM-SC) node is responsible for authorization and authentication of content provider, charging, and overall data flow through Core Network (CN)
  • In case of multicast, a request to join the session has to be sent to become member of the corresponding MBMS service group
  • In contrast to previous releases of Universal Terrestrial Radio Access Network (UTRAN), in MBMS a data stream intended for multiple users is not split until necessary (in UTRAN, one stream per user existed both within CN and RAN)
  • MBMS services are power limited and maximize the diversity without relying on feedback from users
  • Two techniques are used to provide diversity:
    • Macro-diversity: combining transmission from multiple cells
      • Soft combining: combines the soft bits received from the different radio links prior to (Turbo) coding
      • Selection combining: decoding the signal received from each cell individually, and for each TTI selects one (if any) of the correctly decoded data blocks for further processing by higher layers
    • Time-diversity: against fast fading through a long Transmission Time Interval (TTI) and application-level coding
      • because broadcast cannot rely on feedback (feedback links are not available for p-t-m bearers on the radio access network), MBMS uses application-level forward error-correcting coding, namely Systematic Raptor codes
  • Streaming data are encapsulated in RTP and transported using the FLUTE protocol when delivering over MBMS bearers
  • MAC layer maps and multiplexes the RLC-PDUs to the transport channel and selects the transport format depending on the instantaneous source rate
  • MBMS uses the Multimedia Traffic Channel (MTCH), which enables p-t-m distribution. This channel is mapped to the Forward Access Channel (FACH), which is finally mapped to the Secondary-Common Control Physical Channel (S-CCPCH)
  • The TTI is transport channel specific and can be selected from the set {10 ms, 20 ms, 40 ms, 80 ms} for MBMS
MBMS Protocol Stack


Evolved Multicast Broadcast Multimedia Services (eMBMS)

  • Is a multimedia service performed either with a single-cell broadcast or multicell mode (aka MBMS Single Frequency Network (MBSFN))
  • In an MBSFN area, all eNBs are synchronized to perform sumulcast transmission from multiple cells (each cell transmitting identical waveform)
  • There are three types of cells within an MBSFN area: transmitting/receiving, transmitting only, and reserved
  • If user is close to a base station, delay of arrival between two cells could be quite large, so the subcarrier spacing is reduced to 7.5 KHz and longer CP is used


Related Research Papers Summaries

Mobile Video Transmission Using Scalable Video Coding
  • In current system architectures, the differentiation of data is very coarse (each flow is only differentiated among four classes: conversational, streaming, interactive, and background). Individual packets within each flow are all treated the same.
  • Investigating per packet QoS would enable general packet marking strategies (such as Differentiated Services). This can be done by either:
    • Mapping SVC priority information to Differentiated Services Code Point (DSCP) to introduce per packet QoS
    • Making the scheduler media-aware (e.g. by including some MANE-like functinality), and therefore able to use priority information in the SVC NAL unit header
  • Many live-media distribution protocols are based on RTP, including p-t-m transmission (e.g. DVB-H or MBMS). Provision of different layers, on different multicast addresses for example, allows for applying protection strength on different layers
  • By providing signalling in the RTP payload header as well as in the SDP session signalling, adaptation (for bitrate or device capability) can be applied in the network by nodes typically known as MANE


Downlink OFDM Scheduling and Resource Allocation for Delay Constrained SVC Streaming
  • Problem Definition:
    • Designing an efficient multi-user video streaming protocols that fully exploit the resource allocation flexibility in OFDM and performance scalabilities in SVC
  • Maximize average PSNR for all video users under a total downlink transmission power constraint based on a stochastic subgradient-based scheduling framework
  • Authors generalize their previous downlink OFDM resource allocation algorithm for elastic data traffic to real-time video streaming by further considering dynamically adjusted priority weights based on the current video content, deadline requirements, and the previous transmission results
  • Main steps:
    • Divide video data into subflows based on the contribution of distortion decrease and the delay requirements of individual video frames
    • Calculate the weights of current subflows according to their rate-distortion properties, playback deadline requirements, and the previous transmission results
    • Use a rate-distortion weighted transmission scheduling strategy, based on the existing gradient related approach
    • To overcome the deadline approaching effect, deliberately add a product to the weight calculation which increases when the deadline approaches


References


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