For HSDPA in WCDMA/UMTs, UE will be assigned a number of SF16 channelization codes by the base station during fast scheduling.
Assuming a theoretical effective code rate of 1.0 and 16QAM modulation, the data rate achieved by each SF16 channelization code is given by
Chip rate / SF * (bits per modulation symbol) * (code rate) = 3.84M / 16 * 4 * 1.0 = 0.96 Mb/s.
while the peak data rate is 0.96 * N Mb/s, where N is the number of assigned SF16 code blocks.
If the UE is assigned 15 codes, which is the maximum possible number of codes since the 1 remaining SF16 or 16*SF256 channelization code resource has to be reserved for HS-SCCH, associated DPCH and downlink common control channels, the peak rate is 0.96*15=14.4 Mb/s.
So, why is the peak rate only 7.2 Mb/s for a UE, as alleged in commercials presented by China Unicom, the only WCDMA carrier in the Heaven Kingdom?
The answer lies in the HS-DSCH physical layer category. Only UEs with a capability to use up to 15 codes, such as Category 9 or 10 UEs, can reach the maximum data rate of 14.4Mb/s. Best UEs available on the market are usually Category-8 UEs that can only use up to 10 codes, resulting in a peak rate of 0.96*10=9.6 Mb/s. So why is it 7.2Mb/s?
By consulting 3GPP specification 25.306 (Table 5.1a), you'll find that for a UE that can use up to 10 codes, the possible HS-DSCH transport block is 14,411 bits. For a TTI of 2ms, the peak rate is 14411bits/2ms ~= 7.2 Mb/s, whose corresponding physical layer data rate is 9.6Mb/s, where the 2.4 Mb/s in difference is consumed by channel coding and other physical layer overhead.
Now we have found the answer. The 7.2Mb/s peak rate alleged by China Unicom is actually the MAC-hs throughput for Category-8 terminals.
Notes:GSM
<伊落丹> illidan.modeler [at] gmail.com
Northern Capital, Republic of Pandaren
Of the Net, by the Net, for the Net
History
In 1982, the European Conference of Postal and Telecommunications Administrations (CEPT) created the Groupe Spécial Mobile (GSM) to develop a standard for a mobile telephone system that could be used across Europe.
In 1987, a memorandum of understanding was signed by 13 countries to develop a common cellular telephone system across Europe. Finally the system created by SINTEF lead by Torleiv Maseng was selected.
In 1989, GSM responsibility was transferred to the European Telecommunications Standards Institute (ETSI) and phase I of the GSM specifications were published in 1990. The first GSM network was launched in 1991 by Radiolinja in Finland with joint technical infrastructure maintenance from Ericsson.
By the end of 1993, over a million subscribers were using GSM phone networks being operated by 70 carriers across 48 countries.
Network structure
The network behind the GSM seen by the customer is large and
complicated in order to provide all of the services which are required.
It is divided into a number of sections and these are each covered in
separate articles.
Packet control unit
The packet control unit (PCU) is a late addition to the GSM
standard. It performs some of the processing tasks of the BSC, but for
packet data. The allocation of channels between voice and data is
controlled by the base station, but once a channel is allocated to the
PCU, the PCU takes full control over that channel.
The PCU can be built into the base station, built into the BSC or
even, in some proposed architectures, it can be at the SGSN site. In
most of the cases, the PCU is a separate node communicating extensively
with the BSC on the radio side and the SGSN on the Gb side.
Physical and Logical Channels
Traffic Channels (TCHs)
Full-Rate TCH
Full-Rate Speech Channel (TCH/FS) : Carries speech digitized at a raw data rate of 13 kbps, sent at 22.8 Kbps.
Full-Rate Data Channel for 9600 bps (TCH/F9.6) : Carries data sent at 9.6 Kbps. With FEC code, the data is sent at 22.8 Kbps.
Full-Rate Data Channel for 4800 bps (TCH/F4.8) : Carries data sent at 4.8 Kbps. With FEC code, the data is sent at 22.8 Kbps.
Full-Rate Data Channel for 2400 bps (TCH/F2.4) : Carries data sent at 2.4 Kbps. With FEC code, the data is sent at 22.8 Kbps.
Half-Rate TCH
Half-Rate Speech Channel (TCH/HS) : Carries speech digitized at 6.5 Kbps, sent at 11.4 Kbps.
Half-Rate Data Channel for 4800 bps (TCH/H4.8) : Carries data sent at 4.8 Kbps. With FEC code, the data is sent at 11.4 Kbps.
Full-Rate Data Channel for 2400 bps (TCH/H2.4) : Carries data sent at 2.4 Kbps. With FEC code, the data is sent at 11.4 Kbps.
(For more details about FEC channel coding, turn to [7].)
Control Channels (CCHs)
Broadcast Channels (BCHs)
Broadcast Control Channel (BCCH) - DOWNLINK -
Frequency Correction Channel (FCCH) - DOWNLINK -
Synchronization Channel (SCH) - DOWNLINK -
Common Control Channels (CCCHs)
Paging Channel (PCH) - DOWNLINK -
Random Access Channel (RACH) - UPLINK -
Access Grant Channel (AGCH) - DOWNLINK -
Dedicated Control Channels (DCCHs)
Stand-alone Dedicated Controls (SDCCHs) - UPLINK/DOWNLINK -
Slow Associated Control Channel (SACCH) - UPLINK/DOWNLINK -
Fast Associated Control Channel (FACCHs) - UPLINK/DOWNLINK -
BCHs
- BCCH:
This channel contains system parameters needed to identify the network
and gain access. These paramters include the Location Area Code (LAC),
the Mobile Network Code (MNC), the frequencies of neighboring cells,
and access parameters.
- FCCH: This channel is used by the MS as a frequency reference. This channel contains frequency correction bursts.
- SCH:
This channel is used by the MS to learn the Base Station Information
Code (BSIC) as well as the TDMA frame number (FN). This lets the MS
know what TDMA frame they are on within the hyperframe.
CCCHs
- PCH:
This channel is used to inform the MS that it has incoming traffic. The
traffic could be a voice call, SMS, or some other form of traffic.
- RACH:
This channel is used by a MS to request an initial dedicated channel
from the BTS. This would be the first transmission made by a MS to
access the network and request radio resources. The MS sends an Access
Burst on this channel in order to request access
- AGCH: This channel is used by a BTS to notify the MS of the assignement of an initial SDCCH for initial signaling.
DCCHs
- SDCCH: This channel is used for signalling and call setup between the MS and the BTS.
- SACCH:
This channel is a continuous stream channel that is used for control
and supervisory signals associated with the traffic channels.
- FACCH:
This channel is used for control requirements such as handoffs. There
is no TS and frame allocation dedicated to a FAACH. The FAACH is a
burst-stealing channel, it steals a Timeslot from a TCH.
Frame Structure
For
a frame for traffic channe, a super frame consists of 51 multiframe
that is made of 26 TDMA frames. For a frame for control channel, a
super frame consists of 26 multiframe that contains 51 TDMA frames.
Each TDMA frame spans 4.615 ms, consisting of 8 time slots, during each
of which a user sends data called "burst". Of a normal burst, the
payload (information-bearing part) occupies two 57 bit blocks.
Data Rates
The gross data rate is 32500bits/120ms = 270.83 kbit/s, resulting in 270.83/8 =
33.854 kbit/s per user. User data is actually sent at
24.7 kbit/s (57 bits * 2 / 4.615ms), excluding the overhead in the burst.
Slow Frequency Hopping
GSM
employs slow frequency hopping (SFH) to mitigate the effects of
multipath fading and interference. Each burst belonging to a particular
physical channel will be transmitted on a different carrier frequency
in each TDAM frame. Thus the hopping rate is equal to the frame rate
(i.e.' 217 frames/s). The only physical channels that are not allowed
to hop are the broadcast and common control channels (i.e. the FCH,
SCH, BCCH, PCH and AGCH).
The effect of frequency hopping on interference
In
a non-frequency hopping GSM system, an MS will tend to experience
interference from the same set of MSs in neighbouring co-channel cells.
In a frequency hopped system, the hopping patterns (i.e. the sequence
of transmission frequencies) are different in co-channel cells and the
MS will experience interference from a different set of MSs on each
burst. This effectively randomises the interference and each MS will
experience an average level of interference.
Literature
1. [web] "GSM."
Wikipedia, The Free Encyclopedia. 16 Apr 2009, 16:20 UTC. 18 Apr 2009 <
http://en.wikipedia.org/w/index.php?title=GSM&oldid=284232567>
2. [web] "Base Station subsystem."
Wikipedia, The Free Encyclopedia. 30 Mar 2009, 19:49 UTC. 20 Apr 2009 <
http://en.wikipedia.org/w/index.php?title=Base_Station_subsystem&oldid=280712891>
3. [book] [Rappaport 2001] Section 11.3 "Global System for Mobile"
4. [book] [Tanenbaum 2004] Sec. 2.6.2 "Second-Generation Mobile Phones: Digital Voice"
5. [web] "GSM Network Architecture". 29 Apr 2009. <
http://www.gsmfordummies.com/architecture/arch.shtml >
6. [web] "Logical Channels". 29 Apr 2009. <
http://www.gsmfordummies.com/tdma/logical.shtml >
7. [book] [Steele 2001] Sec. 2.3.9 "Speech transmission"
UMTS (Universal Mobile Telecommuniations System)
<伊落丹> illidan.modeler [at] gmail.com
Northern Capital, Republic of Pandaren
System Architecture
UTRAN
UTRAN, short for
UMTS
Terrestrial
Radio
Access
Network, is a collective term for the
Node B's and
Radio Network Controllers which make up the
UMTS radio access network.
The UTRAN allows connectivity between the
UE (user equipment) and the
core network. The UTRAN contains the base stations, which are called
Node Bs, and
Radio Network Controllers
(RNC). The RNC provides control functionalities for one or more Node
Bs. A Node B and an RNC can be the same device, although typical
implementations have a separate RNC located in a central office serving
multiple Node Bs.
The RNC and its corresponding Node Bs are called the
Radio Network Subsystem (RNS). There can be more than one RNS present in an UTRAN.
Radio Resource Control
RRC handles the
control plane signalling of Layer 3 between the
UEs and
UTRAN.
The major part of the control signalling between UE and UTRAN is RRC messages. RRC messages carry all parameters required to set up, modify and release layer 2 and layer 1 protocol entities. RRC messages also carry in their payload all higher layer signalling (mobility management (MM), connection management (CM), session management (SM), etc.). The mobility of user equipment in the connected mode is controlled by RRC signalling (measurements, handovers, cell updates, etc.).
Literature
1. [web] "UMTS Terrestrial Radio Access Network."
Wikipedia, The Free Encyclopedia. 20 Apr 2009, 09:51 UTC. 21 Apr 2009 <
http://en.wikipedia.org/w/index.php?title=UMTS_Terrestrial_Radio_Access_Network&oldid=284982903>.
2. [book] [Holma 2007] Section 7.8 "The Radio Resource Control Protocol"
3. [web] "Radio Resource Control."
Wikipedia, The Free Encyclopedia. 12 Feb 2009, 04:30 UTC. 5 May 2009 <
http://en.wikipedia.org/w/index.php?title=Radio_Resource_Control&oldid=270157640>.