ETSI TS V4.4.0 ( )

Transcription

1 TS V4.4.0 ( ) Technical Specification Universal Mobile Telecommunications System (UMTS); Spreading and modulation (TDD) (3GPP TS version Release 4)

2 TS V4.4.0 ( ) Reference RTS/TSGR Uv4R4 Keywords UMTS 650 Route des Lucioles F-0692 Sophia Antipolis Cedex - FRANCE Tel.: Fax: Siret N NAF 742 C Association à but non lucratif enregistrée à la Sous-Préfecture de Grasse (06) N 7803/88 Important notice Individual copies of the present document can be downloaded from: The present document may be made available in more than one electronic version or in print. In any case of existing or perceived difference in contents between such versions, the reference version is the Portable Document Format (PDF). In case of dispute, the reference shall be the printing on printers of the PDF version kept on a specific network drive within Secretariat. Users of the present document should be aware that the document may be subject to revision or change of status. Information on the current status of this and other documents is available at If you find errors in the present document, send your comment to: editor@etsi.fr Copyright Notification No part may be reproduced except as authorized by written permission. The copyright and the foregoing restriction extend to reproduction in all media. European Telecommunications Standards Institute All rights reserved. DECT TM, PLUGTESTS TM and UMTS TM are Trade Marks of registered for the benefit of its Members. TIPHON TM and the TIPHON logo are Trade Marks currently being registered by for the benefit of its Members. 3GPP TM is a Trade Mark of registered for the benefit of its Members and of the 3GPP Organizational Partners.

3 2 TS V4.4.0 ( ) Intellectual Property Rights IPRs essential or potentially essential to the present document may have been declared to. The information pertaining to these essential IPRs, if any, is publicly available for members and non-members, and can be found in SR : "Intellectual Property Rights (IPRs); Essential, or potentially Essential, IPRs notified to in respect of standards", which is available from the Secretariat. Latest updates are available on the Web server ( Pursuant to the IPR Policy, no investigation, including IPR searches, has been carried out by. No guarantee can be given as to the existence of other IPRs not referenced in SR (or the updates on the Web server) which are, or may be, or may become, essential to the present document. Foreword This Technical Specification (TS) has been produced by 3rd Generation Partnership Project (3GPP). The present document may refer to technical specifications or reports using their 3GPP identities, UMTS identities or GSM identities. These should be interpreted as being references to the corresponding deliverables. The cross reference between GSM, UMTS, 3GPP and identities can be found under

4 3 TS V4.4.0 ( ) Contents Intellectual Property Rights...2 Foreword...2 Foreword...5 Scope References Symbols and abbreviations Symbols Abbreviations General Data modulation for the 3.84 Mcps option Symbol rate Mapping of bits onto signal point constellation Mapping for burst type and Mapping for burst type Data modulation for the.28 Mcps option Symbol rate Mapping of bits onto signal point constellation QPSK modulation PSK modulation Spreading modulation Basic spreading parameters Channelisation codes Channelisation Code Specific Multiplier Scrambling codes Spread signal of data symbols and data blocks Modulation for the 3.84 Mcps option Combination of physical channels in uplink Combination of physical channels in downlink Modulation for the.28 Mcps option Combination of physical channels in uplink Combination of physical channels in downlink Synchronisation codes for the 3.84 Mcps option Code Generation Code Allocation Code allocation for Case Code allocation for Case Evaluation of synchronisation codes Synchronisation codes for the.28 Mcps option The downlink pilot timeslot (DwPTS) Modulation of the SYNC-DL The uplink pilot timeslot (UpPTS) Code Allocation Cell synchronisation codes...2 Annex A (normative): Scrambling Codes...23 Annex B (normative): Synchronisation sequence...26 B. Basic SYNC-DL sequence...26 B.2 Basic SYNC-UL Codes...27

5 4 TS V4.4.0 ( ) Annex C (informative): Generalised Hierarchical Golay Sequences...33 C. Alternative generation...33 Annex D (informative): Change history...34 History...35

6 5 TS V4.4.0 ( ) Foreword This Technical Specification (TS) has been produced by the 3 rd Generation Partnership Project (3GPP). The contents of the present document are subject to continuing work within the TSG and may change following formal TSG approval. Should the TSG modify the contents of the present document, it will be re-released by the TSG with an identifying change of release date and an increase in version number as follows: Version x.y.z where: x the first digit: presented to TSG for information; 2 presented to TSG for approval; 3 or greater indicates TSG approved document under change control. y z the second digit is incremented for all changes of substance, i.e. technical enhancements, corrections, updates, etc. the third digit is incremented when editorial only changes have been incorporated in the document.

7 6 TS V4.4.0 ( ) Scope The present document describes spreading and modulation for UTRA Physical Layer TDD mode. 2 References The following documents contain provisions which, through reference in this text, constitute provisions of the present document. References are either specific (identified by date of publication, edition number, version number, etc.) or non-specific. For a specific reference, subsequent revisions do not apply. For a non-specific reference, the latest version applies. In the case of a reference to a 3GPP document (including a GSM document), a non-specific reference implicitly refers to the latest version of that document in the same Release as the present document. [] 3GPP TS 25.20: "Physical layer - general description". [2] 3GPP TS 25.2: "Physical channels and mapping of transport channels onto physical channels (FDD)". [3] 3GPP TS 25.22: "Multiplexing and channel coding (FDD)". [4] 3GPP TS 25.23: "Spreading and modulation (FDD)". [5] 3GPP TS 25.24: "Physical layer procedures (FDD)". [6] 3GPP TS 25.25: "Physical layer Measurements (FDD)". [7] 3GPP TS 25.22: "Physical channels and mapping of transport channels onto physical channels (TDD)". [8] 3GPP TS : "Multiplexing and channel coding (TDD)". [9] 3GPP TS 25.02: "UTRA (UE) TDD; Radio Transmission and Reception". [0] 3GPP TS 25.05: "UTRA (BS) TDD; Radio Transmission and Reception". 3 Symbols and abbreviations 3. Symbols For the purposes of the present document, the following symbols apply: C p : C i : C (k) CSC, m : PSC i:th secondary SCH code CSCderived ask:th offset version from m:th applicable constituent Golay complementary pair 3.2 Abbreviations For the purposes of the present document, the following abbreviations apply: CCTrCH DPCH CDMA Coded Composite Transport Channel Dedicated Physical Channel Code Division Multiple Access

8 7 TS V4.4.0 ( ) CSC FDD MIB OVSF P-CCPCH PN PRACH PSC QPSK RACH SCH SF SFN TDD TFC UE UL Cell Synchronisation Code Frequency Division Duplex Master Information Block Orthogonal Variable Spreading Factor Primary Common Control Physical Channel Pseudo Noise Physical Random Access Channel Primary Synchronisation Code Quadrature Phase Shift Keying Random Access Channel Synchronisation Channel Spreading Factor System Frame Number Time Division Duplex Transport Format Combination User Equipment Uplink 4 General In the following, a separation between the data modulation and the spreading modulation has been made. The data modulation for 3.84Mcps TDD is defined in clause 5 'Data modulation for the 3.84 Mcps option', the data modulation for.28mcps TDD is defined in clause 6 'Data modulation for the.28 Mcps option' and the spreading modulation in clause 7 'Spreading modulation'. Table : Basic modulation parameters Chip rate same as FDD basic chiprate: 3.84 Mchip/s Low chiprate:.28 Mchip/s Data modulation QPSK QPSK, 8PSK Spreading characteristics Orthogonal Q chips/symbol, where Q = 2 p,0<=p<=4 Orthogonal Q chips/symbol, where Q = 2 p,0<=p<=4 5 Data modulation for the 3.84 Mcps option 5. Symbol rate The symbol duration T S depends on the spreading factor Q and the chip duration T C :T s =Q T c,wheret c = chiprate. 5.2 Mapping of bits onto signal point constellation 5.2. Mapping for burst type and 2 The data modulation is performed to the bits from the output of the physical channel mapping procedure in [8] and combines always 2 consecutive binary bits to a complex valued data symbol. Each user burst has two data carrying parts, termed data blocks: d ( k, = ( k, T ( d, d 2,..., d N ), i =,2; k =,..., K k Code () K Code is the number of used codes in a time slot, max K Code =6. N k is the number of symbols per data field for the code k. This number is linked to the spreading factor Q k as described in table of [7].

9 8 TS V4.4.0 ( ) (k,) (k,2) Data block d is transmitted before the midamble and data block d after the midamble. Each of the N k data ( k) symbols d n ; i=, 2; k=,...,k Code ; n=,...,n k ; of equation has the symbol duration T s = Qk. Tc as already given. The data modulation is QPSK, thus the data symbols d output of the physical channel mapping procedure in [8]: n are generated from two consecutive data bits from the b { 0, }, l =,2; k =,..., K ; n =,..., N ; i, 2 l, n Code k = (2) using the following mapping to complex symbols: consecutive binary bit pattern complex symbol n, 2n, d n 00 +j j (, ) The mapping corresponds to a QPSK modulation of the interleaved and encoded data bits b k i l, n of equation Mapping for burst type 3 In case of burst type 3, the definitions in subclause 5.2. apply with a modified number of symbols in the second data 96 (k,2) block. For the burst type 3, the number of symbols in the second data block d is decreased by symbols. Q K 6 Data modulation for the.28 Mcps option 6. Symbol rate The symbol duration T S depends on the spreading factor Q and the chip duration T C :T s =Q T c,wheret c = 6.2 Mapping of bits onto signal point constellation 6.2. QPSK modulation chiprate. The mapping of bits onto the signal point constellation for QPSK modulation is the same as in the 3.84Mcps TDD cf. [5.2. Mapping for burst type and 2] PSK modulation The data modulation is performed to the bits from the output of the physical channel mapping procedure. In case of 8PSK modulation 3 consecutive binary bits are represented by one complex valued data symbol. Each user burst has two data carrying parts, termed data blocks: d = T ( d, d,..., d ), i =,2; k =,..., K Code 2 Nk (a) N k is the number of symbols per data field for the code k. This number is linked to the spreading factor Q k.

10 9 TS V4.4.0 ( ) Data block symbols (k,) d d n is transmitted before the midamble and data block (k,2) d after the midamble. Each of the N k data T ; i=, 2; k=,...,k Code ; n=,...,n k ; of equation has the symbol duration s = Qk. Tc as already given. ( k) Thedatamodulationis8PSK,thusthedatasymbols of the physical channel mapping procedure in [8]: d n are generated from 3 consecutive data bits from the output b { 0,} l =,2,3; k =,..., K ; n =,..., N ; i, 2 l, n Code k = (2a) using the following mapping to complex symbols: Consecutive binary bit pattern complex symbol n, 2n, b 3, n d n 000 cos(pi/8)+ jsin(pi/8) 00 cos(9pi/8)+ jsin(9pi/8) 00 cos(5pi/8)+ jsin(5pi/8) 0 cos(7pi/8)+ jsin(7pi/8) 00 cos(3pi/8)+ jsin(3pi/8) 0 cos(5pi/8)+ jsin(5pi/8) 0 cos(3pi/8)+ jsin(3pi/8) cos(pi/8)+ jsin(pi/8) The mapping corresponds to a 8PSK modulation of the interleaved and encoded data bits d n of equation a. b l, n of the table above and 7 Spreading modulation 7. Basic spreading parameters Spreading of data consists of two operations: Channelisation and Scrambling. Firstly, each complex valued data symbol (k) d of equation is spread with a real valued channelisation code Q,2,4,8,6. The resulting n sequence is then scrambled by a complex sequence ν of length 6. c of length { } k 7.2 Channelisation codes The elements shall be taken from the set The c (k) Q k (k) c q ; k=,...,k Code ; q=,...,q k ; of the real valued channelisation codes ( k) ( k) ( k) ( k) c = ( c, c 2,..., cq ) k ; k=,...,k Code ; V c = {, -}. (3) are Orthogonal Variable Spreading Factor (OVSF) codes, allowing to mix in the same timeslot channels with different spreading factors while preserving the orthogonality. The OVSF codes can be defined using the code tree of figure.

11 0 TS V4.4.0 ( ) c ( k= ) Q= = () c c ( k= ) = Q= 2 ( k= 2) Q= 2 (,) = (, ) c c c c ( k= ) = Q= 4 ( k= 2) Q= 4 ( k= 3) Q= 4 ( k= 4) Q= 4 (,,,) = (,,, ) = (,,, ) = (,,,) Q= Q=2 Q=4 Figure : Code-tree for generation of Orthogonal Variable Spreading Factor (OVSF) codes for Channelisation Operation Each level in the code tree defines a spreading factor indicated by the value of Q in the figure. All codes within the code tree cannot be used simultaneously in a given timeslot. A code can be used in a timeslot if and only if no other code on the path from the specific code to the root of the tree or in the sub-tree below the specific code is used in this timeslot. This means that the number of available codes in a slot is not fixed but depends on the rate and spreading factor of each physical channel. The spreading factor goes up to Q MAX = Channelisation Code Specific Multiplier Associated with each channelisation code is a multiplier jπ / 2 p w taking values from the set { e } k (k) Q k,where pk is a permutation of the integer set {0,..., Q k -} and Q k denotes the spreading factor. The multiplier is applied to the data sequence modulating each channelisation code. The values of the multiplier for each channelisation code are given in the table below: k ( k ) ( k ) ( k ) ( k ) ( k ) w Q = w Q = 2 w Q = 4 w Q = 8 w Q = 6 -j - 2 +j +j -j 3 +j +j j +j j j 0 +j 2 +j 3 -j 4 -j 5 +j 6 - If the UE autonomously changes the SF, as described in [7], it shall always use the multiplier associated with the channelisation code allocated by higher layers.

12 TS V4.4.0 ( ) 7.4 Scrambling codes (k ) The spreading of data by a real valued channelisation code c of length Q k is followed by a cell specific complex ν = ν,ν. The elements ; =,..., 6 of the complex valued scrambling codes shall scrambling sequence (,..., ) 2 ν6 be taken from the complex set V ν = {, j, -, - j}. (4) ν i i In equation 4 the letter j denotes the imaginary unit. A complex scrambling code ν is generated from the binary scrambling codes ν = ( ν ν,... ν ) given by:, 2, 6 of length 6 shown in Annex A. The relation between the elements ν and ν is νi = i ( j) ν i νi {, }; i =,..., 6 (5) Hence, the elements ν i of the complex scrambling code ν are alternating real and imaginary. The length matching is obtained by concatenating Q MAX /Q k spreadwordsbeforethescrambling.theschemeis illustrated in figure 2 and is described in more detail in subclause 6.4. d d 2 d QMAX Qk data symbols Weighting of each data symbol by multiplier w Q (k) Spreading of each weighted data symbol by channelisation code c (k) (k) (, (, (, (, d k.( c k, c k,..., c k (k) (, (, (, (, ) d k.( c k, c k,..., c k (k) w Q. w Q. ) w Q. d.( c, c,..., c ) 2 Qk 2 2 Qk QMAX Qk 2 Qk Chip by chip multiplication by scrambling code ν ν ν ν ν ν ν,, 2,...., Q, k Qk +,, 2Q,..., k QMAX Qk + ν QMAX Spread and scrambled data Figure 2: Spreading of data symbols 7.5 Spread signal of data symbols and data blocks The combination of the user specific channelisation and cell specific scrambling codes can be seen as a user and cell ( k ) ( k ) specific spreading code s = ( s ) p with ( k ) p = c ( k ) [ ] + ( p ) modqk. ν + [( p ) modqmax ], k=,,k Code, p=,,n k Q k.

13 2 TS V4.4.0 ( ) With the root raised cosine chip impulse filter Cr 0 (t) the transmitted signal belonging to the data block equation transmitted before the midamble is (k,) d of and for the data block d 2) d ) (k,2) d N k n= N k n= ) n Qk ( k) Qk q= ( k) ( n ) Qk + q ( t) = d w s. Cr ( t ( q ) T ( n ) Q T ) (6) of equation transmitted after the midamble 2) n Qk ( k) Qk q= ( k) ( n ) Qk + q 0 ( t) = d w s. Cr ( t ( q ) T ( n ) Q T N Q T L T ) (7) where L m is the number of midamble chips. 7.6 Modulation for the 3.84 Mcps option The complex-valued chip sequence is QPSK modulated as shown in figure 3. 0 c c k c k k k c c m c cos(ωt) Complex-valued chip sequence S Split real & imag. parts Re{S} Im{S} Pulseshaping Pulseshaping -sin(ωt) Figure 3: Modulation of complex valued chip sequences The pulse-shaping characteristics are described in [9] and [0] Combination of physical channels in uplink Figure 4 illustrates the principle of combination of two different physical uplink channels within one timeslot. The DPCHs to be combined belong to same CCTrCH, did undergo spreading as described in sections before and are thus represented by complex-valued sequences. First, the amplitude of all DPCHs is adjusted according to UL open loop power control as described in [0]. Each DPCH is then separately weighted by a weight factor γ i and combined using complex addition. After combination of Physical Channels the gain factor β j is applied, depending on the actual TFC as described in [0]. In case of different CCTrCH, principle shown in Figure 4 applies to each CCTrCH separately.

14 3 TS V4.4.0 ( ) Different UL DPCH Power Setting γ Σ (point S in Figure 3) γ 2 β j Figure 4: Combination of different physical channels in uplink The values of weight factors γ i are depending on the spreading factor SF of the corresponding DPCH: SF of DPCH i γ i In the case that β j (corresponding to the j th TFC) has been explicitly signalled to the UE, the possible values that β j can assume are listed in the table below. In the case that β j has been calculated by the UE from a reference TFC, β j shall not be restricted to the quantised values. Signalling value for β j Quantized value β j 5 6/8 4 5/8 3 4/8 2 3/8 2/8 0 /8 9 0/8 8 9/8 7 8/8 6 7/8 5 6/8 4 5/8 3 4/8 2 3/8 2/8 0 / Combination of physical channels in downlink Figure 5 illustrates how different physical downlink channels are combined within one timeslot. Each complex-valued spread channel is separately weighted by a weight factor G i. If a timeslot contains the SCH, the complex-valued SCH, as described in [7] is separately weighted by a weight factor G SCH. All downlink physical channels are then combined using complex addition.

15 4 TS V4.4.0 ( ) Different downlink Physical channels G G 2 Σ SCH Σ (point S in Figure 3) G SCH Figure 5: Combination of different physical channels in downlink in case of SCH timeslot 7.7 Modulation for the.28 Mcps option The complex-valued chip sequence is modulated as shown in figure 6. cos(ωt) Complex-valued chip sequence S Split real & imag. parts Re{S} Im{S} Pulseshaping Pulseshaping -sin(ωt) Figure 6: Modulation of complex valued chip sequences The pulse-shaping characteristics are described in [9] and [0] Combination of physical channels in uplink The combination of physical channels in uplink is the same as in the 3.84 Mcps TDD cf. [7.5. Combination of physical channels in uplink] Combination of physical channels in downlink Figure 7 illustrates how different physical downlink channels are combined within one timeslot. Each spread channel is separately weighted by a weight factor G i.. All downlink physical channels are then combined using complex addition.

16 5 TS V4.4.0 ( ) Different downlink Physical channels G G 2 Σ (point S in Figure 6) Figure 7: Combination of different physical channels in downlink 8 Synchronisation codes for the 3.84 Mcps option 8. Code Generation The primary synchronisation code (PSC), C p, is constructed as a so-called generalised hierarchical Golay sequence. The PSC is furthermore chosen to have good aperiodic auto correlation properties. Definea=<x,x 2,x 3,,x 6 >=<,,,,,,-,-,,-,,-,,-,-,> The PSC is generated by repeating the sequence 'a' modulated by a Golay complementary sequence and creating a complex-valued sequence with identical real and imaginary components. The PSC, C p, is defined as C p = < y(0),y(),y(2),...,y(255) > where y = (+ j) < a, a, a, a, a, a, a, a, a, a, a, a, a, a, a, a > and the left most index corresponds to the chip transmitted first in time. The 2 secondary synchronization codes, {C 0,C, C 3, C 4, C 5, C 6, C 8, C 0, C 2, C 3, C 4,C 5 } are complex valued with identical real and imaginary components, and are constructed from the position wise multiplication of a Hadamard sequence and a sequence z, defined as z= < b, b, b, b, b, b, b, b, b, b, b, b, b, b, b, b >,where b= x, x, x, x, x, x, x, x, x, x, x, x, x, x, x x > < , 6 and x,x 2,x 3,,x 6 are the same as in the definition of the sequence 'a' above. The Hadamard sequences are obtained as the rows in a matrix H 8 constructed recursively by: H k H = H H k k 0 = () H H k k, k The rows are numbered from the top starting with row 0 (the all ones sequence). Denote the n:th Hadamard sequence h n as a row of H 8 numbered from the top, n = 0,, 2,, 255, in the sequel. Furthermore, let h m (l) and z(l) denote the lth symbol of the sequence h m and z, respectively where l =0,,2,,255and l = 0 corresponds to the leftmost symbol.

17 6 TS V4.4.0 ( ) The i:th secondary SCH code word, C i,i=0,,3,4,5,6,8,0,2,3,4,5isthendefinedas C i =(+j) <h m (0) z(0), h m () z(), h m (2) z(2),, h m (255) z(255)>, where m =(6 and the leftmost chip in the sequence corresponds to the chip transmitted first in time. 8.2 Code Allocation Three secondary SCH codes are QPSK modulated and transmitted in parallel with the primary synchronization code. The QPSK modulation carries the following information: - the code group that the base station belongs to (32 code groups:5 bits; Cases, 2); - the position of the frame within an interleaving period of 20 msec (2 frames: bit, Cases, 2); - the position of the SCH slot(s) within the frame (2 SCH slots: bit, Case 2). The modulated secondary SCH codes are also constructed such that their cyclic-shifts are unique, i.e. a non-zero cyclic shift less than 2 (Case ) and 4 (Case 2) of any of the sequences is not equivalent to some cyclic shift of any other of the sequences. Also, a non-zero cyclic shift less than 2 (Case ) and 4 (Case 2) of any of the sequences is not equivalent to itself with any other cyclic shift less than 8. The secondary synchronization codes are partitioned into two code sets for Case and four code sets for Case 2. The set is used to provide the following information: Case : Table 2: Code Set Allocation for Case Code Set Code Group The code group and frame position information is provided by modulating the secondary codes in the code set. Case 2: Table 3: Code Set Allocation for Case 2 Code Set Code Group The slot timing and frame position information is provided by the comma free property of the code word and the Code group is provided by modulating some of the secondary codes in the code set. The following SCH codes are allocated for each code set: Case Case 2 Code set : C,C 3,C 5. Code set 2: C 0,C 3,C 4. Code set : C,C 3,C 5. Code set 2: C 0,C 3,C 4. Code set 3: C 0,C 6,C 2. Code set 4: C 4,C 8,C 5.

18 7 TS V4.4.0 ( ) The following subclauses 7.2. to refer to the two cases of SCH/P-CCPCH usage as described in [7]. Note that in the tables 4 and 5 corresponding to Cases and 2, respectively, Frame implies the frame with an odd SFN and Frame 2 implies the frame with an even SFN Code allocation for Case Table 4: Code Allocation for Case Code Group Code Set Frame Frame 2 Associated t offset 0 C C 3 C 5 C C 3 -C 5 t 0 C -C 3 C 5 C -C 3 -C 5 t 2 -C C 3 C 5 -C C 3 -C 5 t 2 3 -C -C 3 C 5 -C -C 3 -C 5 t 3 4 jc jc 3 C 5 jc jc 3 -C 5 t 4 5 jc -jc 3 C 5 jc -jc 3 -C 5 t 5 6 -jc jc 3 C 5 -jc jc 3 -C 5 t 6 7 -jc -jc 3 C 5 -jc -jc 3 -C 5 t 7 8 jc jc 5 C 3 jc jc 5 -C 3 t 8 9 jc -jc 5 C 3 jc -jc 5 -C 3 t 9 0 -jc jc 5 C 3 -jc jc 5 -C 3 t 0 -jc -jc 5 C 3 -jc -jc 5 -C 3 t 2 jc 3 jc 5 C jc 3 jc 5 -C t 2 3 jc 3 -jc 5 C jc 3 -jc 5 -C t 3 4 -jc 3 jc 5 C -jc 3 jc 5 -C t 4 5 -jc 3 -jc 5 C -jc 3 -jc 5 -C t C 0 C 3 C 4 C 0 C 3 -C 4 t C 0 -C 3 C 4 C 0 -C 3 -C 4 t jc 0 jc 3 C 4 jc 0 jc 3 -C 4 t jc 0 jc 4 C 3 jc 0 jc 4 -C 3 t jc 3 -jc 4 C 0 -jc 3 -jc 4 -C 0 t 3 NOTE: The code construction for code groups 0 to 5 using only the SCH codes from code set is shown. The construction for code groups 6 to 3 using the SCH codes from code set 2 is done in the same way.

19 8 TS V4.4.0 ( ) Code allocation for Case 2 Table 5: Code Allocation for Case 2 Code Group Code Frame Frame 2 Set Slot k Slot k+8 Slot k Slot k+8 Associated t offset 0 C C 3 C 5 C C 3 -C 5 -C -C 3 C 5 -C -C 3 -C 5 t 0 C -C 3 C 5 C -C 3 -C 5 -C C 3 C 5 -C C 3 -C 5 t 2 jc jc 3 C 5 jc jc 3 -C 5 -jc -jc 3 C 5 -jc -jc 3 -C 5 t 2 3 jc -jc 3 C 5 jc -jc 3 -C 5 -jc jc 3 C 5 -jc jc 3 -C 5 t 3 4 jc jc 5 C 3 jc jc 5 -C 3 -jc -jc 5 C 3 -jc -jc 5 -C 3 t 4 5 jc -jc 5 C 3 jc -jc 5 -C 3 -jc jc 5 C 3 -jc jc 5 -C 3 t 5 6 jc 3 jc 5 C jc 3 jc 5 -C -jc 3 -jc 5 C -jc 3 -jc 5 -C t 6 7 jc 3 -jc 5 C jc 3 -jc 5 -C -jc 3 jc 5 C -jc 3 jc 5 -C t C 0 C 3 C 4 C 0 C 3 -C 4 -C 0 -C 3 C 4 -C 0 -C 3 -C 4 t C 0 -C 3 C 4 C 0 -C 3 -C 4 -C 0 C 3 C 4 -C 0 C 3 -C 4 t jc 0 jc 3 C 4 jc 0 jc 3 -C 4 -jc 0 -jc 3 C 4 -jc 0 -jc 3 -C 4 t 0 2 jc 0 -jc 3 C 4 jc 0 -jc 3 -C 4 -jc 0 jc 3 C 4 -jc 0 jc 3 -C 4 t 2 2 jc 0 jc 4 C 3 jc 0 jc 4 -C 3 -jc 0 -jc 4 C 3 -jc 0 -jc 4 -C 3 t jc 0 -jc 4 C 3 jc 0 -jc 4 -C 3 -jc 0 jc 4 C 3 -jc 0 jc 4 -C 3 t jc 3 jc 4 C 0 jc 3 jc 4 -C 0 -jc 3 -jc 4 C 0 -jc 3 -jc 4 -C 0 t jc 3 -jc 4 C 0 jc 3 -jc 4 -C 0 -jc 3 jc 4 C 0 -jc 3 jc 4 -C 0 t C 0 C 6 C 2 C 0 C 6 -C 2 -C 0 -C 6 C 2 -C 0 -C 6 -C 2 t jc 6 -jc 2 C 0 jc 6 -jc 2 -C 0 -jc 6 jc 2 C 0 -jc 6 jc 2 -C 0 t C 4 C 8 C 5 C 4 C 8 -C 5 -C 4 -C 8 C 5 -C 4 -C 8 -C 5 t jc 8 -jc 5 C 4 jc 8 -jc 5 -C 4 -jc 8 jc 5 C 4 -jc 8 jc 5 -C 4 t 3 NOTE: The code construction for code groups 0 to 5 using the SCH codes from code sets and 2 is shown. The construction for code groups 6 to 3 using the SCH codes from code sets 3 and 4 is done in the same way.

20 9 TS V4.4.0 ( ) 8.3 Evaluation of synchronisation codes The evaluation of information transmitted in SCH on code group and frame timing is shown in table 6, where the 32 code groups are listed. Each code group is containing 4 specific scrambling codes (cf. subclause 6.3), each scrambling code associated with a specific short and long basic midamble code. Each code group is additionally linked to a specific t Offset, thus to a specific frame timing. By using this scheme, the UE can derive the position of the frame border due to the position of the SCH sequence and the knowledge of t Offset.The complete mapping of Code Group to Scrambling Code, Midamble Codes and t Offset is depicted in table 6. Table 6: Mapping scheme for Cell Parameters, Code Groups, Scrambling Codes, Midambles and t Offset CELL PARA- METER Code Associated Codes Group Scrambling Long Basic Code Midamble Code 0 Group 0 Code 0 m PL0 m SL0 Code m PL m SL 2 Code 2 m PL2 m SL2 3 Code 3 m PL3 m SL3 4 Group Code 4 m PL4 m SL4 5 Code 5 m PL5 m SL5 6 Code 6 m PL6 m SL6 7 Code 7 m PL7 m SL Group 3 Code 24 m PL24 m SL24 Short Basic Midamble Code 25 Code 25 m PL25 m SL25 26 Code 26 m PL26 m SL26 27 Code 27 m PL27 m SL27 Associat ed t Offset t 0 t t 3 For basic midamble codes m P cf. [7], annex A 'Basic Midamble Codes'. Each cell shall cycle through two sets of cell parameters in a code group with the cell parameters changing each frame. Table 7 shows how the cell parameters are cycled according to the SFN. Table 7: Alignment of cell parameter cycling and SFN Initial Cell Parameter Assignment Code Group Cell Parameter used when SFN mod 2 = 0 Cell Parameter used when SFN mod 2 = 0 Group Group Group

21 20 TS V4.4.0 ( ) 9 Synchronisation codes for the.28 Mcps option 9. The downlink pilot timeslot (DwPTS) The contents of DwPTS is composed of 64 chips of a SYNC-DL sequence, cf.[b. Basic SYNC-DL sequence] and 32 chips of guard period (GP). The SYNC-DL code is not scrambled There should be 32 different basic SYNC-DL codes for the whole system. For the generation of the complex valued SYNC-DL codes of length 64, the basic binary SYNC-DL codes = ( s s,... s ), 2, 64 of length 64 shown in Table 9 are used. The relation between the elements s and s is given by: s i = i ( j) s i si {, }; i =,..., 64 () Hence, the elements si of the complex SYNC-DL code s are alternating real and imaginary. The SYNC-DL is QPSK modulated and the phase of the SYNC-DL is used to signal the presence of the P-CCPCH in the multi-frame of the resource units of code ( k= ) c Q = 6 and 9.. Modulation of the SYNC-DL ( k= 2) c Q = 6 in time slot #0. The SYNC-DL sequences are modulated with respect to the midamble (m () ) intime slot#0. Four consecutive phases (phase quadruple) of the SYNC-DL are used to indicate the presence of the P-CCPCH in the following 4 sub-frames. In case the presence of a P-CCPCH is indicated, the next following sub-frame is the first subframe of the interleaving period. As QPSK is used for the modulation of the SYNC-DL, the phases 45, 35, 225, and 35 are used. The total number of different phase quadruples is 2 (S and S2). A quadruple always starts with an even system frame number ((SFN mod 2) =0). Table 8 is showing the quadruples and their meaning. Table 8: Sequences for the phase modulation for the SYNC-DL Name Phase quadruple Meaning S 35, 45, 225, 35 There is a P-CCPCH in the next 4 sub-frames S2 35, 225, 35, 45 There is no P-CCPCH in the next 4 sub-frames 9.2 The uplink pilot timeslot (UpPTS) The contents in UpPTS is composed of 28chips of a SYNC-UL sequence, cf. [B.2 Basic SYNC-UL sequence] and 32chips of guard period (GP).The SYNC-UL code is not scrambled. There should be 256 different basic SYNC-UL codes (see Table 0) for the whole system. For the generation of the complex valued SYNC-UL codes of length 28, the basic binary SYNC-UL codes by: = ( s s,... s ), 2, 28 of length 28 shown in Table 0 are used. The relation between the elements s and s is given s i = i ( j) s i si {, }; i =,..., 28 (2) Hence, the elements si of the complex SYNC-UL code s are alternating real and imaginary.

22 2 TS V4.4.0 ( ) 9.3 Code Allocation Relationship between the SYNC-DL and SYNC-UL sequences, the scrambling codes and the midamble codes Code Group SYNC-DL SYNC-UL ID ID Group Group Group Associated Codes Scrambling Code ID... Basic Midamble Code ID Cell synchronisation codes The cell synchronisation codes (CSCs) are constructed as so-called CEC sequences, i.e. concatenated and periodically extended complementary sequences. They are complex-valued sequences that are derived as cyclically offset versions from a set of possible constituent Golay complementary pairs. The CSCs are chosen to have good aperiodic auto correlation properties. The aperiodic auto correlations of the applicable constituent Golay complementary pairs and every pair of their derived cyclically offset versions are complementary. Furthermore, orthogonality is preserved for all CSCs which are derived from the same constituent Golay complementary pair due to this complementary property. The delay and weight matrices for the set of M = 8 possible constituent Golay complementary pairs are listed in the table below: Code ID m Delay matrices D m and weight matrices W m of constituent Golay complementary pairs 0 D 0 = <52, 64, 28,, 6, 4, 256, 32, 8, 2>, W 0 = <,,,, -, -,,,, > D = <2, 6, 32, 256,, 8, 28, 4, 52, 64>, W = <, -,, -,, -, -,, -, -> 2 D 2 = <6, 52, 32, 256, 4,, 64, 8, 2, 28>, W 2 =<-,,,-,-,,-,,-,-> 3 D 3 = <52, 6, 8, 4, 2, 256, 28, 64, 32, >, W 3 = <-, -, -, -, -,, -,,, > 4 D 4 = <52, 28, 256, 32, 2, 4, 64,, 6, 8>, W 4 = <, -,, -, -, -, -, -, -, > 5 D 5 = <, 2, 4, 64, 52, 6, 32, 256, 28, 8>, W 5 =<-,,,,,-,-,,-,> 6 D 6 = <8, 6, 28, 2, 32,, 256, 52, 4, 64>, W 6 = <-, -,,,,, -, -, -, > 7 D 7 = <, 2, 28, 6, 256, 32, 8, 52, 64, 4>, W 7 = <,, -, -, -, -,, -, -, -> A constituent Golay complementary pair of length N = 024, defined as: s m =<s m (0), s m (), s m (2),, s m (023)> and g m =<g m (0), g m (), g m (2),, g m (023)> shall be derived from the selected delay and weight matrices: D m =<D m (0), D m (), D m (2),, D m (9)> and W m =<W m (0), W m (), W m (2),, W m (9)>

23 22 TS V4.4.0 ( ) as follows. Define: a (0) =<a (0) (0), a (0) (), a (0) (2),, a (0) (023)> = <, 0, 0,, 0> and b (0) =<b (0) (0), b (0) (), b (0) (2),, b (0) (023)> = <, 0, 0,, 0>. Then, the elements of the set of auxiliary sequences: a (n) =<a (n) (0), a (n) (), a (n) (2),, a (n) (023)> and b (n) =<b (n) (0), b (n) (), b (n) (2),, b (n) (023)> are given by the recursive relations: a (n+) ( = a (n) ( + W m (n) b (n) (i D m (n)) and b (n+) ( = a (n) ( W m (n) b (n) (i D m (n)) with element index i = 0,, 2,, 023 and iteration index n =0,,2,,9.Operationsontheelementindexshallbe performed modulo 024. The elements of the constituent Golay complementary pairs s m and g m are then obtained from the output of the last iteration step using: s m ( =a (0) ( andg m ( =b (0) ( fori = 0,, 2,..., 023 From each applicable constituent Golay complementary pair s m and g m, up to K = 8 different cyclically offset pairs s m (k) and g m (k),withoffsetindexk = 0,, 2,, K-, of length 52 chips can be derived. The complementary property of the respective aperiodic auto correlation is preserved for each particular pair of sequences s m (k) and g m (k). The generation of the K cyclically offset pairs from s m and g m is done in a similar way as the generation of the user midambles from a periodic basic midamble sequence as described in [7]. With N = 024, K = 8, W = 28, the elements of a cyclically offset pair: s m (k) =<s m (k) (0), s m (k) (), s m (k) (2),, s m (k) (5)> and g m (k) =<g m (k) (0), g m (k) (), g m (k) (2),, g m (k) (5)> for a particular offset k, with k = 0,, 2,, K-, shall be derived from the elements of the constituent Golay complementary pairs s m and g m using: s m (k) ( =(j) i s m (i + k W) and g m (k) ( =(j) i g m (i + k W) for i =0,,2,...,N k W, s m (k) ( =(j) i s m (i N +k W) and g m (k) ( =(j) i g m (i N +k W) for i =N k W, N k W +,..., 5. Hence, the elements of s m (k) and g m (k) are alternating real and imaginary. Note that both s m (0) and g m (0) simply correspond to s m and g m respectively, followed by its first W elements as post extension and that both s m (7) and g m (7) simplycorrespondtothelastwelementsofs m and g m in form of a pre extension, followed by s m and g m respectively. Finally, the CSC C CSC, m (k) derived from the m:th applicable constituent Golay complementary pair s m and g m, and for the k:th offset is then defined as a concatenation of s m (k) and g m (k) by: C CSC, m (k) =<s m (k) (0), s m (k) (), s m (k) (2),, s m (k) (5), g m (k) (0), g m (k) (), g m (k) (2),, g m (k) (5)> where the leftmost element s m (k) (0) in the sequence corresponds to the chip to be first transmitted in time. An CSC has therefore length 2304 chips. Note that due to this construction method, the auto correlations for all CSCs derived from one particular constituent Golay complementary pair s m and g m can be obtained simultaneously and in sequential order from the sum of partial correlations with s m and g m, these CSCs remaining orthogonal. CSCs derived according to above have complex values and shall not be subject to the channelisation or scrambling process, i.e. its elements represent complex chips for usage in the pulse shaping process at modulation.

24 23 TS V4.4.0 ( ) Annex A (normative): Scrambling Codes The applicable scrambling codes are listed below. Code numbers are referring to table 6 'Mapping scheme for Cell Parameters, Code Groups, Scrambling Codes, Midambles and t offset ' in subclause 7.3 'Evaluation of synchronisation codes'. Scrambling ν ν 2 ν 3 ν 4 ν 5 ν 6 ν 7 ν 8 ν 9 ν 0 ν ν 2 ν 3 ν 4 ν 5 ν 6 Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code

25 24 TS V4.4.0 ( ) Scrambling ν ν 2 ν 3 ν 4 ν 5 ν 6 ν 7 ν 8 ν 9 ν 0 ν ν 2 ν 3 ν 4 ν 5 ν 6 Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code

26 25 TS V4.4.0 ( ) Scrambling ν ν 2 ν 3 ν 4 ν 5 ν 6 ν 7 ν 8 ν 9 ν 0 ν ν 2 ν 3 ν 4 ν 5 ν 6 Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code Code

27 26 TS V4.4.0 ( ) Annex B (normative): Synchronisation sequence B. Basic SYNC-DL sequence Table 9: Basic SYNC-DL Codes Code ID SYNC-DL Codes of length 64 0 B3A7CC05A98688E4 9D559BD CE7BA2A07C3A D20672F A F BA5CE0F FD429B359450C AA3F8C9 8 C9A3B8E0C043EA56 9 BA04B888E5BC802 0 A C3C8DA445AE5 2 F4FD0458A A0D4E6C3D BDA066B0CAA8C68 5 8E323F F095C632E2906AB 7 B60B4A8A66407CF 8 AA094DCCE9E04A 9 C0C3CDA8A D56964FB8C DE0834F4AACCE 22 8F700323BA5CAD34 23 B50F4DEE0C380C F56F2D 25 EE4005D49B846B A BFAA 27 C48E AD78 28 D4354B2FE0236CC AB6C8A0CE84 30 D47A730F2F ABF0A0D905A939C4

28 27 TS V4.4.0 ( ) B.2 Basic SYNC-UL Codes Table 0: Basic SYNC-UL Codes Code ID SYNC-UL Codes of length 28 0 CC20F0D807DB885975B798EC094A EC8E74543DBCC9AD F5AEE2E53DB2A663BA046003E5 3 7AA8A0A20F2AE4332F2EDD330FC 4 C80EA3B9BA774EB96BD249C4A508 5 B072A2C839489D496B98CE9D032FBC9 6 B2723EAC6EB0667F2B3396C C444AD060F0EC095E227B92CF7C A0D305446FCF85986C63A4 9 F899CA6435D64DC07FDF04C4A0C053A 0 B56F2D6893A805407F4C34D88DC7DC DC0BE EDE643A72C88D74AA 2 22A2FD86E4086C70A4860B3C76E579F 3 A3CBC2322C97D2A02728E7875F D4EC4F694A082CB38E3B558A0FCC89F 5 CC894C4E26D235C5CF5D3F9B002 6 A9934C50B77CB0C0725DE22FD F73A979DE52F82E8800CCB93842A59 8 8F878FA E294D8DEAB20BA2FD 9 AC90B0442D70662B028CF76A6BECDF09 20 D94A284DF64D7B002F0E084C29C88C C7596F24E865FD D 22 B466B2CF433642BD8B08FF452E A3A772CC99FCA7DBBA0C32E34A A889F72A9A2C042D46F08EFEEAC 25 BF220A362BC0D3B0D7CE400954C6CFAE 26 D28D73C52E89CF57905C502244F AD4EC203697D64D8B9D4C035D F08A9BA2B6C6BD02453AA984D2C 29 E BE82988EE3585BF6A6AE BD36E0A9C06782CB38B35B335CA56 3 CDFF3CC2685DC44F4A059AB03F40A ED4E88FBCECE3243F2A27A022A CF58A7AB63C83A2430B5778C0E2 34 A27A99E26A0C75AC026F4CFAECE D846EEEBA2432AC05A0043C62579DCF 36 6B6B4E85CAF22FC4CF88820C89E7 37 AA4889A A74E0C6F2BED CF845BC ED5C72709EE 39 0AEF5D2290A84A D9963C7

29 28 TS V4.4.0 ( ) F758245D564FE6D852942C7 4 CF7C E446E30745BD56E2D BA0DF8CDC47FE7C8707ED0AD 43 EB2E263EC069C8AB74BFE4D2B A7482FACC499793A0D8CED DE2C22B2783AB75A DE43840A 46 E3AA60B727F2CA2A78DAAC06650D 47 CEF6CD AC9E077ACD55092D 48 E52C84D499FFCDC F2 49 B33BF655A BEE0930BCAEC BE6886D0FC43D7235E6C6D F6745EE23CE240C90F0B52A C290D28E84060E69D09788A26B0FF E0C35E83CD38CCC5D F A7879F0D3A8982A0EE6AC DC 55 A37F C70A83D69A237378B F55208EE A7CBEB9B549E 57 57E5E268A328FCC9ED04B9E5420AC EB033AD222F84D8642C4E3FAAD EE45F026AC0E862C DD0 60 6A0528AEA4B7CD D8F882E D626A87C603BCB09EA4C800A378F 62 EEA C23F669D6A A657B3CC2D0E04F07ACC808B92DCE7 64 DDF88B52EA83D293A803CF23C8C CA4D333A DAB49F6C7A 66 A7D2AD A3289F7C3E35580A 67 BC752FA66B4C8904EDE27EA000E2E BE3CCCB36BE2A095F89CC C20334EBBC596B25E580BF F8070DD9C49A2B05A43DCE 7 40A20BCBE29B7438A7AEE44635A9E C3239CBF628033FA0DF EFA36404CBA58CC5F9052FD28D9C D8A042D496E6477B747C4F A6D7D2549CC9742E3FD E63042B89AA20937A6F0FFDBC30A7 77 C AC6DBB2095FD7826D0CD5C 78 E00D9E B28DEDA9D429362E DE447E CAFCCC57F 80 DA0AFBF2AE6C593AD88584DE BB248AEA5FD3FE20CD48FC40EA A89F46BD99F44530C08CB6F BBF04F247C EB6B9CC58

30 29 TS V4.4.0 ( ) 84 08F48BFA7804B5B2CC2E E AA2BE74005A3679C626B209580B8D D40664A2C808F2F293E255398B37E6A C98A8AAD8CAE4A23C83FF9EEA E8948E6BD0927C440C3C04C4CF3 89 0F942C67A37B6EAA058C2A74872C D058E27ED546C BBC84E5BC 9 79D4B840E2048B34F90B564BCBD0 92 0E35ED8D24C05FAC790B69B FFABB0232CD7480BE5CAC2A269F89 94 B2956F5F4E270446F DB 95 F56CCA2342C8EC8F8A4F7DA4A4EA2 96 0B5ECA04F789A748C80C39D57D05F6 97 A0B538E8A8CFC8F8925C485F2A C2C7500D9FC78ACCC5DAAF DAC9CFDEA40429A8B2C7D320D60F FC9A E838E39D FA8B47E4E943B CC C4F68540CB7E858263B B6A8980C6703C779F49F40C5CFC9 04 D0D253E57BC926250CEA668679E7 05 B8889C60EBA82BD7F0B D2 06 A3FB9F3A08528E44B3C2CF0D46AA 07 8D4DCFBE43D6E2024BF AA D59E9E B2A074E64 09 DCFD49C504AD3A2F049A0CB70238EC8A 0 D363DB4C46C757FA8FB AE8AD4DA256E4CA3BC8C220BE3 2 47B69ED30FEB0A847CC3A9A FBBC95453C6786D33262B45B4D 4 F26CACC0732CF8ED0C5BC462B620B4 5 88E0FE440C70E9249A92A7AF A52B7D8C E066D A5C2828BF5D6E63E42698A0A6B B2763BEEC784A2E8C B2B6A3A77A059B30A082457AB84E DB500FB206358D7A7F20AB85AA A5CFC5E03EB439C A720E8857C8708A59F8C94DE084E 23 2D0F0CF DEBB 24 E8E524B4DCF5DA245B049D49C87C EAA0099ACDE384834A5ADF03D E A230C86FDE4E878BC09 27 A499E39E69ED08890ACA82A65BEC

31 30 TS V4.4.0 ( ) 28 EE54C6E83420D3ECB07A456B92AA DB5CA82420B54CE0BCCE704D EE9A9E4C447DAA F 3 AD095CC0E7438AECE38D60980B3F2D C254C5EE BC3D9282F A27DCA457BC5A56563D8A9B A9C0BB08B4705FF5A7244DB4 35 D36D4B9F E0ECB0CA8C8C E7C990624FCCEBD9509FD C8D83FF0B48B4830D205D53F8C AF223C869A36B6948FDDABB7D20 39 B6C284C600AD0A99F86C449F8F4C53A6 40 DC74B320C07682AF92AC4DBDE0C28C2 4 89B8D84FA C0FA6FF0EB2C4F 42 A69445B3A5220DB984BC03D956D7F3 43 0FE0F7224B7AD72E4D4530D0223F590C 44 B8C06F EB92533AD3BD3F9 45 E33D4C3C942726A35300C37E55D0DF 46 9E0948D88A66F562D8B453BC83AB B04B60A3C BDBBA4E88C8 48 8F8F7A08CC6C8DA3D692AD34F50C AB BCCFA072F8FDE FA88B7FF8A620C3B0D486C52AC2F AF0ADD6D7D F030EE A DACFFC388D5820A4A9BA49 53 CD98EA2EDB4628A407C7E20D4BE84 54 D0FD94279FA67EC6A3904C0AD8ACA04 55 EA73A945EC2004D49E9D0F64596C AF064A DEECBF8DD06 57 B DA0A73705B93CF634E40D A6E4FF34B2C07B5684FE 59 C46D927D0FD2B2F C AD85C C87ECE04D F67852FA3930AA7EE74B400B2CC83 62 AE9D395004C6E27540C378625D36E0D6 63 DC4FA55750F0B F2C22FFE4 64 D3602B8D6CBF809C88B ECF 65 A E7723EA8F22C44BF78B2 66 A62D23C6AEEFE0B0026B A 67 9C7BE80A86465A5055F8925D93B D9338B9CC60485C072F50F2F 69 A3902CE0E0B99259FF28C AB29473A9E0F67F B3368B9EC2A284BC44C8F0D7F8D20

32 3 TS V4.4.0 ( ) 72 EE28880ABF06C75828CB58B598D 73 E43923A00ECC32CCC2D62A4A44BD7F4 74 CC9E30B8538AD5703EEB6F7080AB22 75 B908AD2F50DAC568736CD798CD 76 2B46302ACCC2F808797FC648A64326D 77 8A54494FBE27235B AA0FBCFA 78 BC04E6F63642E89277DC B39A63029B974E356AE0A8FC F6FE89B80492A22B85CE5CE5DC4 8 4CCB52C0CE058A78022C22DF5788CBCC 82 B0DF9608DE549A6F6C585699A8E6 83 2CA8563CC36060DE85BB0A7FBB D284655CAC986FC790D224EFC E D B83BD7AB CAB7085BEC CF 87 DF29065AA505E4F6EB98E4D49C 88 BA B0FB288DE7857DAB E6D075AFF0EA45365E40BF ACC5A A3BE39AA40F9B 9 4D74A3B D7E5FA8988DC80 92 FA42C96EDC BC2FC CAE0B0BFE3EDA59826D5 94 CEBB288C28B7472A0D C BD35A6E00C9528DB38289CF823C34F30 96 E2C9368B6B2800D57A5F85746A55 97 B43EF39AA64F0E220AF740F949429B 98 AC53787C262744A5832A8AFBC44A A32249A82DDBF8C38235A37A4 200 AED D8BB6B08FED9E EAE245DC2CD60AE083249A33B56E D942AAA9BC9F CE0B30FB BA6D AC6D059C005C6C FF47C242C65B502DA70647BAE83D 205 C83AA7FEAC5E5A0809E0DB0C233D9 206 E86EDD2EC2DAA304229EDC4347A6A FAFB9C84B78B56EE9B6602C E4563DC509B290C08D2CAF5DBFE 209 D203C B56568FDAD9E2D AA87F3A7DABC90024F936006C4A DEABC7305BF0C5A D8DA5FE40F A082C53A6A5CB C F324DE8ECC03BAE AF097FCDE82B366A844245E0D E5E9F8C93359ACADC22A06F900A70

33 32 TS V4.4.0 ( ) 26 FE40502B44A9E44B2C336250D47538CC E972C84376F278FE4D B7EAA436078E6886A3024F593AD D4CDD7230E7B953AD232DF07E D82ECAC3D845A2E FF ED2FBD44DB859D F CCC3C3D6D5B4B8D82FF4522A4C A84F7CD62E0C72980E6A0C89BF394F 224 0E5675F DBE74E68ECC4C 225 A3DE F026E084CFE302A20A9 226 B2DA062B343A8C3FE94A32EA5D D65335DE825A74B743E275C9020C CAD30BF846B2EE92D33A3D4BB ACBB548C668FC E6 230 B94B4B89C C9E007D906DF5FE 23 75A2C9E7606A E8BFD4A64A F3070B47ECE2504A5065D74A A47444A F7FE07382D4 234 A58270EBFCA899B C3560F FCB63E2CAC63002DE09FD BEC83F689ADF422C865F98D288838A 237 A06A0D82265D3F346B4749ECCB D A32B7EF72894ECE07CB C0CF8F78E8823ECC866A A A7243F593F280E5A306A8438E6A9 24 A4CCED356D56BFB4C28E50430FE AE90E2F76B3055A2E3A966025CC0A 243 8B90D5A62364E857445C5895CEFF F7EAAB0D903255AD9DE DD5D8424AC60360BC4E6585C9B5E 246 C632A67382ECB268DFB852540E A6ACF22B6F8B9C53FF224C2E00C6C A90C267B7093F362FE5CB4E3A0 249 EA262EC36E6589C3BB005426AF2590F F0326C5B0D7B9028E7757C5F FC090C222AA98BF0D24E85066EFC E26CEC67832FC42A87E92FA0522E 253 ACD889634F79506F2582EA03240F2A AA65407EF4A33BF9A62860A3D6A4CC0 255 BB950AC76A608AA32D04B03C7FF24D3