Channel structure

1. Channel Structure and Function
ZTE University

2. Objectives
 At the end of this course, you will be able to
master:
 Classification of channels
 Structure and Function of channels

3. Content
Classification of channels
Structure and Function of channels
Physical layer procedure

4. RNS RNS
CN
RNC
RNC
Iu Iu
Iur
Iub Iub
Iub Iub
Architecture of UMTS
UE
NodeB
NodeB
NodeB
NodeB

5. Channel Type
 Physical channel
 Transport channel
 Logical channel
Node B
RNC
Physical channel
Transport channel
Logical channel
UE

6. Concept of channel
PHY layer
MAC layer
RLC layer
Transport channel
Physical channel
Logical channel
L1
L2

7. Channel Type
 Logical channels:
 Describe what is transported (i.e., the information to be
transmitted)
 Transport channels:
 Describe how the logical channels are to be transmitted.
 Physical channels:
 Represent the “transmission media” providing the
platform through which the information is actually
transferred.

8. Protocol stack of the Uu interface
L3
control
control
control
control
Logical
Channels
Transport
Channels
C-plane signalling U-plane information
PHY
L2/MAC
L1
RLC
DC
Nt
GC
L2/RLC
MAC
RLC
RLC
RLC
RLC
RLC
RLC
RLC
Duplication avoidance
UuS boundary
BMC
L2/BMC
control
PDCP
PDCP L2/PDCP
DC
Nt
GC
Radio
Bearers
RRC

9. Logical Channels
Control Channel (CCH) Broadcast Control Channel (BCCH)
Paging Control Channel (PCCH)
Dedicated Control Channel (DCCH)
Common Control Channel (CCCH)
Traffic Channel (TCH) Dedicated Traffic Channel (DTCH)
Common Traffic Channel (CTCH)

10. Transport Channel
Random Access Channel (RACH)
Broadcast Channel (BCH)
Paging Channel (PCH)
Forward Access Channel (FACH)
Common Packet Channel (CPCH)
Common Transport Channels
DedicatedTransportChannels
Downlink Shared Channel (DSCH)
Dedicated Channel (DCH)

11. Physical Channel
Dedicated Physical Channel (DPCH)
Physical Random Access Channel (PRACH)
Physical Common Packet Channel (PCPCH)
Uplink Physical Channels
Secondary Common Control Physical Channel (S-CCPCH)
Common Pilot Channel (CPICH)
Primary Common Control Physical Channel (P-CCPCH)
Synchronization Channel (SCH)
Physical Downlink Shared Channel (PDSCH)
Downlink Physical Channels
Acquisition Indication Channel (AICH)
Page Indication Channel (PICH)
Dedicated Physical Channel (DPCH)

12. Logic
Channel
Transport
Channel
CCCH
DCCH
DTCH
RACH CPCH DCH
Uplink Downlink
PCCH BCCH
DCCH
DTCH
CCCH CTCH
PCH BCH FACH DSCH DCH
Mapping relationship
Transport
Channel
CCCH
DCCH
DTCH
RACH CPCH DCH
Uplink Downlink
PCCH BCCH
DCCH
DTCH
CCCH CTCH
PCH BCH FACH DSCH DCH

13. Mapping relationship
Transport Channels
DCH
RACH
CPCH
BCH
FACH
PCH
DSCH
Physical Channels
Dedicated Physical Data Channel (DPDCH)
Dedicated Physical Control Channel (DPCCH)
Physical Random Access Channel (PRACH)
Physical Common Packet Channel (PCPCH)
Common Pilot Channel (CPICH)
Primary Common Control Physical Channel (P-CCPCH)
Secondary Common Control Physical Channel (S-CCPCH)
Synchronization Channel (SCH)
Physical Downlink Shared Channel (PDSCH)
Acquisition Indication Channel (AICH)
Page Indication Channel (PICH)

14. Content
Classification of channels
Structure and Function of channels
Physical layer procedure

15. WCDMA frame structure

16. Physical Channels(1)
 The physical channel is in a 3-layer structure by
the time:
 Superframe
 One superframe lasts 720ms, and consists of 72 radio frames.
 radio frame
 One radio frame has a period of 10ms, and comprises 15
timeslots with the same length. Corresponding to 38400 chips,
it is a basic unit of the physical layer.
 Timeslot
 A timeslot is a unit composed of a bit domain, corresponding to
2560 chips. The bit number and structure of a timeslot depends
on the specific type of the physical channel.

17. Physical Channels(2)
 The frame structure of the physical channels is shown:
Tslot #1 Tslot #2 Tslot #I Tslot #15
Ttimeslot= 2560 chip
Frame #0 Frame #1 Frame #I Frame #71
Tframe=10 ms
Tsuperframe=720 ms

18. Uplink physical channel
 2 UL Dedicated physical channel (DPDCH and
DPCCH)
 2 UL Common physical channel (PRACH and
PCPCH)
UL Common physical
channel
UL Dedicated physical
channel
Dedicated physical
Control channel DPCCH
Dedicated physical
data channel
DPDCH
Physical random
Access channel
PRACH
Physical common
Packet channel
PCPCH

19. Uplink Dedicated physical channel

20. PRACH
 Physical Random Access Channel
 PRACH consists preamble part and message part
 Random access transmit 1or more 4096 chips length
preambles and 10ms or 20ms length message part.
Message part
Preamble
4096 chips 10 ms (one radio frame)
Preamble Preamble
Message part
Preamble
4096 chips 20 ms (two radio frames)
Preamble Preamble
PRACH transmitted structure

21. PRACH
 Physical Random Access Channel
 10ms message part is split into 15 timeslots, each timeslot consists
of 2560chips.
 Each timeslot includes data part and control part. They are
transmitted in parallel .
 Data part :SF=32~256 , control part: SF=256.
Pilot
Npilot bits
Data
Ndata bits
Slot #0 Slot #1 Slot #i Slot #14
Tslot = 2560 chips, 10*2k
bits (k=0..3)
Message part radio frame T
RACH = 10 ms
Data
Control
TFCI
NTFCI bits

22. Downlink physical channel
 DL physical channel include Dedicated physical channel、1 Shared
physical channel and five Common control channels.
DPCH
SCH
CPICH
PICH
AICH
CCPCH
PDSCH
DL common physical
channel

23. Downlink dedicated physical channel

24. CPICH

25. CPICH
 There is 2 types of CPICH:P-CPICH and S-CPICH
 P-CPICH:
 P-CPICH of different cell uses the same Cch,256,0 OVSF code to
spread ,the bit rate of P-CPICH is also fixed.
 The P-CPICH is scrambled by the primary scrambling code.
 There is one and only P-CPICH per cell.
 The P-CPICH is broadcast over the entire cell. it is used to search cell
primary
 scrambling code during cell selection procedure. And it is also used
for measurement and estimation during handover, cell selection and cell
re-selection.
 S-CPICH:
 A arbitrary channelization code of SF=256 is used for the S-CPICH.
 A S-CPICH is scrambled by either the primary or a secondary scrambling
code.
 There may be 0,1 or several S-CPICH per cell.
 A S-CPICH may be transmitted over the entire cell or part of the cell. It is
may be a phase reference for a dl DPCH, but it is decided by high layer
signalling.

26. P-CCPCH

27. SCH (1)
 The Synchronization Channel (SCH) is a downlink signal
used for cell search.
 The SCH consists of two sub channels, the Primary and
Secondary SCH.
 The 10 ms radio frames of the Primary and Secondary
SCH are divided into 15 slots, each of length 2560 chips.
Structure of synchronization channel

28. SCH (2)
 P-SCH
 The Primary SCH consists of a modulated code of length
256 chips. The modulated code need not spreading and
scrambling.
 The primary synchronization code (PSC) is transmitted once
every slot
 The PSC is the same for every cell in the system.
 S-SCH
 The Secondary SCH consists of repeatedly transmitting a
length 15 sequence of modulated codes of length 256 chips.
 the Secondary Synchronization Codes (SSC), transmitted in
parallel with the Primary SCH.
 Each SSC is chosen from a set of 16 different codes of
length 256.
 This sequence on the Secondary SCH indicates which of the
code groups the cell's downlink scrambling code belongs to.

29. S-CCPCH

30. PICH
 PICH carries PI（Page Indication），SF=256，
radio frame=10ms，consists 300bits，288 bits
for paging indication，12 bits Tx Off。
 PICH relates to S-CCPCH which mapping to PCH。
b1
b0
288 bits for paging indication
12 bits (transmission
off)
One radio frame (10 ms)
b287 b288 b299
PICH frame structure

31. Content
Classification of channels
Structure and Function of channels
Physical layer procedure

32. Cell Search
 UE has to get the system information before it
registers with the network and access to services.
 The system information is beared in the BCH
channel, and its data is mapped into the Primary
CCPCH.
 So the cell search procedure is mainly to decode
the data of P-CCPCH.

33. Cell search procedure (1)
 The cell search is typically carried out in three
steps:
 Step1: Slot synchronization
 During the first step of the cell search procedure the UE
uses the SCH channel's primary synchronization code
to acquire slot synchronization to a cell.
 This is typically done with a single matched filter (or any
similar device) matched to the primary synchronization
code which is common to all cells. The slot timing of the
cell can be obtained by detecting peaks in the matched
filter output.

34. Sketch of Slot Synchronization

35. Cell search procedure (2)
 Step2: Frame synchronization and code-group
identification
 During the second step of the cell search procedure, the
UE uses the SCH channel's secondary synchronization
code to find frame synchronization and identify the code
group of the cell found in the first step.
 This is done by correlating the received signal with all
possible secondary synchronization code sequences,
and identifying the maximum correlation value. Since
the cyclic shifts of the sequences are unique the code
group as well as the frame synchronization is
determined.

36. …
Downlink Scrambling Code Grouping
No. 511 Scrambling Code
Group
8176
8177
8191
8176：PSC
8177：SSC
…
8191：SSC
No. 510 Scrambling Code Group
8160
8161
8175
8160：主扰码
8161：辅扰码
…
8175：辅扰码
No. 504 Scrambling Code
Group
8064
8065
8079
8064：主扰码
8065：辅扰码
…
8079：辅扰码
…
No. 7 Scrambling Code
Group
112
113
127
8176：PSC
8177：辅扰码
…
8191：辅扰码
No. 1 Scrambling Code
Group
16
17
31
16：PSC
17：SSC
…
31：SSC
No. 0 Scrambling Code
Group
0
1
15
0：PSC
1：SSC
…
15：SSC
No.63 Primary Scrambling Code Group
… …
No.0 Primary Scrambling Code Group

37. Mapping of the Secondary Synchronization Code

38. Cell search procedure (3)
 Step3: Scrambling-code identification
 During the third and last step of the cell search
procedure, the UE determines the exact primary
scrambling code used by the cell.
 The primary scrambling code is typically identified
through symbol-by-symbol correlation over the CPICH
with all codes within the code group identified in the
second step.
 After the primary scrambling code has been
identified, the Primary CCPCH can be detected so
that the cell specific BCH information can be read.

39. Cell search procedure

40. Summary of the process
Channel
Synchronization
acquired
Note
Primary
SCH
Chip, Slot, Symbol
Synchronization
Synchronization 256 chips
The same in all cells
Secondary
SCH
Frame Synchronization,
Code Group
(one of 64)
15-code sequence of secondary
synchronization codes. There are 16
secondary synchronization codes. There
are 64 S-SCH sequences corresponding to
the 64 scrambling code groups 256 chips,
different for different cells and slot intervals
Common
Pilot CH
Scrambling code (one
of 8)
To find the primary scrambling code from
common pilot CH
PCCPCH Synchronization,
BCCH info
Fixed 30 kbps channel spreading factor 256

41. RACH procedure
 UE decodes BCH to find out the available RACH sub-channels and
their scrambling codes and signatures
 It selects randomly one of the available sub-channels and signatures
 The downlink power is measured and the initial RACH power level is
set with a proper margin due to open loop inaccuracy
 UE transmits 1 ms long preamble with the selected signature
 Node B replies by repeating the preamble using Acquisition Indication
Channel (AICH)
 UE decodes AICH message to see whether the NodeB has detected
the preamble
 If AICH is not detected, the preamble is resend with 1 dB higher transmit
power
 If AICH is detected, a 10 or 20 ms long message part is transmitted with
the same power as the last preamble

42. RACH procedure

43. Exercise
 pls write down the 3 types of channel and describe
their mapping relations.
 One radio frame has a period of ( )ms, and
comprises( ) timeslots with the same length.
 Corresponding to ( ) chips, it is a basic unit of
the physical layer.
 pls describe the main function of each physical
channel.
 pls describe the cell search procedure.
 pls describe RACH procedure.