Presentation is loading. Please wait.

Presentation is loading. Please wait.

HIPER LAN (High Performance Radio LAN).  Two main standards families for Wireless Lan:  IEEE 802.11 (802.11b, 802.11a, 802.11g...)  ETSI Hiperlan (Hiperlan.

Published byDamon Palmer Modified over 9 years ago

Similar presentations

Presentation on theme: "HIPER LAN (High Performance Radio LAN).  Two main standards families for Wireless Lan:  IEEE 802.11 (802.11b, 802.11a, 802.11g...)  ETSI Hiperlan (Hiperlan."— Presentation transcript:

1 HIPER LAN (High Performance Radio LAN)

2  Two main standards families for Wireless Lan:  IEEE 802.11 (802.11b, 802.11a, 802.11g...)  ETSI Hiperlan (Hiperlan Type 1, Type 2, HiperAccess, HiperLink...)  HiperLAN Family Hiperlan 1Hiperlan2HiperAccessHiperLink DescriptionWireless Ethernet Wireless ATMWireless Local Loop Wireless Point- to-Point Freq. Range5GHz 17GHz PHY Bit Rate23.5Mbps6~54Mbps ~25Mbps (data rate) ~155Mbps (data rate)

3  Motivation of HiperLAN  Massive Growth in wireless and mobile communications  Emergence of multimedia applications  Demands for high-speed Internet access  Deregulation of the telecommunications industry

4  The History, Present and Future  HiperLAN Type 1  Developed by ETSI during 1991 to 1996  Goal: to achieve higher data rate than IEEE 802.11 data rates: 1~2 Mbps, and to be used in ad hoc networking of portable devices  Support asynchronous data transfer, carrier-sense multiple access multiple access with collision avoidance (CSMA/CA), no QoS guaranteed.

5  HiperLAN Type 2  Goal: Providing high-speed (raw bit rate ~54Mbps) communications access to different broadband core networks and moving terminals  Features: connection-oriented, QoS guaranteed, security mechanism, highly flexibility  HiperAccess and HiperLink  In parallel to developing the HIPERLAN Type 2 standards, ETSI BRAN has started work on standards complementary to HIPERLAN Type 2

6 MAC CAC PHY HiperLAN Type 1 Reference Model PHY MAC EC ACFDCC RLC DLC CL HiperLAN Type 2 Reference Model Control PlaneUser Plane MAC: Medium Access SublayerEC: Error Control CAC: Channel Access Control SublayerRLC: Radio Link Control PHY: Physical LayerRRC: Radio Resource Control DLC: Data Link Control LayerACF: Association Control Function CL: Convergence LayerDCC: DLC Connection Control  Architecture RRC

7 CAC: Channel Access Control Sublayer  This sub layer deals with the access request to the channels.  The accomplishing of the request is dependent on the usage of the channel and the priority request.

8 HIPERLAN2 Protocol Stack

9  DLC: MAC Sublayer " The medium access control creates frames of 2 ms duration as shown in Figure. With a constant symbol length of four μs this results in 500 OFDM symbols.

10 Each MAC frame is further sub-divided into four phases with variable boundaries: Broadcast phase: The AP of a cell broadcasts the content of the current frame plus information about the cell (identification, status, resources). Downlink phase: Transmission of user data from an AP to the MTs. Uplink phase: Transmission of user data from MTs to an AP. Random access phase: Capacity requests from already registered MTs and access requests from non-registered MTs.

11 HiperLAN2 defines six different so-called transport channels for data transfer in the above listed phases. These transport channels describe the basic message format within a MAC frame.  Broadcast channel (BCH): This channel conveys basic information for the radio cell to all MTs. This comprises the identification and current transmission power of the AP. The length is 15 bytes.  Frame channel (FCH): This channel contains a directory of the downlink and uplink phases (LCHs, SCHs, and empty parts). This also comprises the PHY mode used. The length is a multiple of 27 bytes.

12  Access feedback channel (ACH): This channel gives feedback to MTs regarding the random access during the RCH of the previous frame. The length is 9 bytes.  Long transport channel (LCH): This channel transports user and control data for downlinks and uplinks. The length is 54 bytes.  Short transport channel (SCH): This channel transports control data for downlinks and uplinks. The length is 9 bytes. " Random channel (RCH): This channel is needed to give an MT the opportunity to send information to the AP/CC even without a granted SCH. The length is 9 bytes.

13  DLC: Error Control  Acknowledged mode: selective-repeat ARQ  Repetition mode: typically used for broadcast  Unacknowledged mode: unreliable, low latency  DLC: other features  Radio network functions: Dynamic frequency selection; handover; link adaptation; multibeam antennas; power control  QoS support: Appropriate error control mode selected; Scheduling performed at MAC level; link adaptation; internal functions (admission, congestion control, and dropping mechanisms) for avoiding overload

14 Radio Link Control Sublayer  It offers connection oriented systems,offering QoS.  Three main control functions  Association control function (ACF): authentication, key management, association, disassociation, encryption  Radio resource control function (RRC): handover, dynamic frequency selection, mobile terminal alive/absent, power saving, power control  DLC user connection control function (DCC): setup and release of user connections, multicast and broadcast

15 Convergence Layer HiperLAN2 supports two different types of CLs: cell-based and packet-based. cell-based CL expects data packets of fixed size (cells, e.g., ATM cells). packet-based CL handles packets that are variable in size (e.g., Ethernet )

Download ppt "HIPER LAN (High Performance Radio LAN).  Two main standards families for Wireless Lan:  IEEE 802.11 (802.11b, 802.11a, 802.11g...)  ETSI Hiperlan (Hiperlan."

Similar presentations

Doc.: IEEE 802.15-00/238r0 Submission July 2000 Jamshid Khun-Jush, EricssonSlide 1.

Doc.: IEEE /238r0 Submission July 2000 Jamshid Khun-Jush, EricssonSlide 1.
Special Topics in Wireless Networking: MAC design and cross-layer issues.

Special Topics in Wireless Networking: MAC design and cross-layer issues.
Lecture 5: IEEE 802. 11 Wireless LANs (Cont.). Mobile Communication Technology according to IEEE (examples) Local wireless networks WLAN 802.11 802.11a.

Lecture 5: IEEE Wireless LANs (Cont.). Mobile Communication Technology according to IEEE (examples) Local wireless networks WLAN a.
Technical Seminar Presentation - 2005 Presented by :- Plaban Kumar Rout (EC200117047) “Wireless ATM & Congestion Control ” Presented by Plaban Kumar Rout.

Technical Seminar Presentation Presented by :- Plaban Kumar Rout (EC ) “Wireless ATM & Congestion Control ” Presented by Plaban Kumar Rout.
HIPERLAN: HIgh PErformance Radio Local Area Networks By Lei Fang Wenyi Zhang 5 th November 2001.

HIPERLAN: HIgh PErformance Radio Local Area Networks By Lei Fang Wenyi Zhang 5 th November 2001.
HIPERLAN HIgh PErformance Radio Local Area Networks.

HIPERLAN HIgh PErformance Radio Local Area Networks.
Wireless LANS Part 2 Justin Champion Room C208 - Tel: 3273 www.staffs.ac.uk/personal/engineering_and_technology/jjc1.

Wireless LANS Part 2 Justin Champion Room C208 - Tel:
Performance Evaluation Study for HiperLan WLAN Protocol Omar A. Elprince Student#220510.

Performance Evaluation Study for HiperLan WLAN Protocol Omar A. Elprince Student#
IP Convergence Layer for HIPERLAN/2 Workshop IP in Telekommunikationsnetzen 25./26. Januar 2001, Bremen Servane Bonjour, France Telecom Philippe Bertin,

IP Convergence Layer for HIPERLAN/2 Workshop IP in Telekommunikationsnetzen 25./26. Januar 2001, Bremen Servane Bonjour, France Telecom Philippe Bertin,
5: DataLink Layer5-1 Asynchronous Transfer Mode: ATM r 1990’s/00 standard for high-speed (155Mbps to 622 Mbps and higher) Broadband Integrated Service.

5: DataLink Layer5-1 Asynchronous Transfer Mode: ATM r 1990’s/00 standard for high-speed (155Mbps to 622 Mbps and higher) Broadband Integrated Service.
“Performance Comparison of the Radio Link Protocols of IEEE 802.11a and HIPERLAN/2” – Hui Li, et al. Presentation byTom Bruns.

“Performance Comparison of the Radio Link Protocols of IEEE a and HIPERLAN/2” – Hui Li, et al. Presentation byTom Bruns.
Department of Computer Engineering University of California at Santa Cruz Networking Systems (1) Hai Tao.

Department of Computer Engineering University of California at Santa Cruz Networking Systems (1) Hai Tao.
ATM: DESCRIPTIONS M. RAZIF AZMAL B. M. OTHMANWET020093 SHAH RIZAD B. ISMAIL WET020155 RASHA AFZAL B. SHAFII WET020147 AHMAD AFIFI B. MOHD ZAKI WET020002.

ATM: DESCRIPTIONS M. RAZIF AZMAL B. M. OTHMANWET SHAH RIZAD B. ISMAIL WET RASHA AFZAL B. SHAFII WET AHMAD AFIFI B. MOHD ZAKI WET
Wimax – Wireless Broadband

Wimax – Wireless Broadband
The 802.11 Protocol Stack Part of the 802.11 protocol stack.

The Protocol Stack Part of the protocol stack.
Protocols and the TCP/IP Suite Asynchronous Transfer Mode (ATM)

Protocols and the TCP/IP Suite Asynchronous Transfer Mode (ATM)
5-1 Data Link Layer r What is Data Link Layer? r Wireless Networks m Wi-Fi (Wireless LAN) r Comparison with Ethernet.

5-1 Data Link Layer r What is Data Link Layer? r Wireless Networks m Wi-Fi (Wireless LAN) r Comparison with Ethernet.
13/08/2015 Broadband Access including Fixed Wireless Access ETSI BRAN Overview 1GSC-9, Seoul SOURCE:ETSI BRAN Chairman TITLE:ETSI BRAN Broadband Access.

13/08/2015 Broadband Access including Fixed Wireless Access ETSI BRAN Overview 1GSC-9, Seoul SOURCE:ETSI BRAN Chairman TITLE:ETSI BRAN Broadband Access.
The Medium Access Control Sublayer Chapter 4. The Channel Allocation Problem Static Channel Allocation in LANs and MANs Dynamic Channel Allocation in.

The Medium Access Control Sublayer Chapter 4. The Channel Allocation Problem Static Channel Allocation in LANs and MANs Dynamic Channel Allocation in.
WMAN, part 1 S-72.3240 Wireless Personal, Local, Metropolitan, and Wide Area Networks1 Contents IEEE 802.16 family of standards Protocol layering TDD frame.

WMAN, part 1 S Wireless Personal, Local, Metropolitan, and Wide Area Networks1 Contents IEEE family of standards Protocol layering TDD frame.

Similar presentations

Ads by Google