KR100672401B1 - Method for generating optimal cell identification code, and for transmitting the code - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the next generation mobile communication, and more particularly, to the generation of a cell identification code for identifying a cell (= base station) in a mobile communication system of a wideband code division multiple access (hereinafter referred to as W-CDMA) scheme. It relates to a method of transmitting a code.

On the other hand, the present invention uses a Hadamard code and a Bi-orthogonal code to minimize cell identification of optimal performance and to exhibit an optimal diversity effect in soft handover mode. It provides a method for creating an optimal Site Selection Diversity Transmit (SSDT) cell with a maximum Hamming Distance (Maximum Hamming Distance) and transmitting it more efficiently through an uplink channel.

Feedback identifier (FBI), Hadamard code, Bi-orthogonal code

Description

Method for generating optimal cell identification code, and for transmitting the code

1 is a diagram illustrating an uplink dedicated physical channel (DPCH) structure according to 3GPP standard;

2 is a diagram illustrating a detailed structure of a feedback identifier (FBI) field in an uplink dedicated physical channel (DPCH) according to the 3GPP standard;

3 is a view for explaining various examples of cell identification code transmission when 1 bit is inserted into a feedback identifier (FBI) field for each slot in the present invention.

FIG. 4 is a view for explaining various examples of cell identification code transmission when 2 bits are inserted into a feedback identifier (FBI) field for each slot in the present invention. FIG.

5A to 5D are diagrams illustrating performance evaluation results for an AWGN channel when 1 bit is inserted into a feedback identifier (FBI) field for each slot in the present invention.

6A to 6D are diagrams illustrating performance evaluation results for an AWGN channel when two bits are inserted into a feedback identifier (FBI) field for each slot in the present invention.

7A to 7D are diagrams illustrating performance evaluation results for a fading channel when 1 bit is inserted into a feedback identifier (FBI) field for each slot in the present invention.

8A to 8D illustrate performance evaluation results for a fading channel when 2 bits are inserted into a feedback identifier (FBI) field for each slot in the present invention.

The present invention relates to the next generation mobile communication, and more particularly, to a cell identification code for identifying a cell (= base station) in a W-CDMA mobile communication system and a method of transmitting the generated code.

In general, the Radio Access Network (RAN) specification of the Third Generation Partnership Project (3GPP) describes the Site Selection Diversity Transmit (hereinafter abbreviated as SSDT). . Site, base station and cell have the same meaning as each other.

SSDT is a selective macro diversity scheme in soft handover mode. The SSDT operation determines whether the service is determined by the system side (UTRAN: UMTS Terrestrial Radio Access Network). (UE: User Equipment) selects one cell called "Primary cell" among the cells in the active set. All other cells not selected at this time become "Non-primary cell".

The first purpose of the SSDT is to reduce the interference caused by multiple transmissions in the soft handover mode by performing information transmission in downlink in a first rank cell (hereinafter referred to as a primary cell).

The second purpose of SSDT is to maintain the benefits of soft handover by implementing a quick selection of sites without system side (UTRAN) intervention.

However, in order to select a primary cell, temporary identifications are assigned to respective valid cells having a transmission level greater than or equal to a predetermined level, and the UE (UE) informs the connected cells of an identifier code corresponding to the primary cell.

At this time, the UE selects the primary cell by periodically measuring and comparing the reception level of the common pilot transmitted by the active cells, and the cell having the largest pilot power is selected as the primary cell. Thereafter, the transmission power of the cells selected as a subordinate (hereinafter, referred to as non-primary) by the user side (UE) is disconnected.

The identifier code of the primary cell is a feed-back indicator among several fields of a control channel such as an uplink dedicated physical control channel (DPCCH) in the uplink dedicated physical channel (DPCH) shown in FIG. 1. (Hereinafter abbreviated as FBI) field is periodically transmitted to the cells belonging to the active group. As shown in Table 2, FBI transmits 1 bit or 2 bits in one slot. If 1 bit is used for FBI, 15 bits are transmitted in one radio frame, and 1 bit is used for 2 bits in FBI. 30 bits are transmitted. This is because one radio frame consists of 15 timeslots. When the UE transmits the identifier code to the selected primary cell, the UE determines whether to transmit by inserting 1 bit or inserting 2 bits into the FBI field for each slot.

For reference, in FIG. 1, k is related to a spreading factor (SF) in an uplink dedicated physical channel (DPCH), and a spreading factor (SF) having a value from 256 to 4 is given as 256/2 ^k . In addition, the number of bits of the fields per slot in the dedicated physical data channel (DPDCH) and the dedicated physical control channel (DPCCH) of the uplink dedicated physical channel (DPCH) is determined as shown in Tables 1 and 2 below.

Slot Format Number (Slot Format #I) Channel Bit Rate (kbps) Channel Symbol Rate (ksps) Diffusion factor (SF) Bits per Frame (Bits / Frame) Bits per Slot (Bits / Slot) N _data bits 0 15 15 256 150 10 10 One 30 30 128 300 20 20 2 60 60 64 600 40 40 3 120 120 32 1200 80 80 4 240 240 16 2400 160 160 5 480 480 8 4800 320 320 6 960 960 4 9600 640 640

Slot Format Number (Slot Format #I) Channel Bit Rate (kbps) Channel Symbol Rate (ksps) Diffusion factor (SF) Bits per Frame (Bits / Frame) Bits per Slot (Bits / Slot) N _pilot bit number N _{TFCI Bits} N _{FBI Bits} N _{TPC Bits} 0 15 15 256 150 10 6 2 0 2 One 15 15 256 150 10 8 0 0 2 2 15 15 256 150 10 5 2 One 2 3 15 15 256 150 10 7 0 One 2 4 15 15 256 150 10 6 0 2 2 5 15 15 256 150 10 5 2 2 One

In Table 2, N _FBI, which represents the number of bits per slot inserted into the FBI field, is a closed loop mode transmission diversity requiring feedback between an access point of a user side (UE) and a system side (UTRAN). loop mode transmit diversity) or SSDT. In addition, the N _FBI is divided into an S field and a D field, as shown in FIG. 2. The S field is used for SSDT signal processing and the D field is used for transmit diversity signal processing in the feedback mode.

In FIG. 2, the lengths of the S field and the D field may be 0, 1, and 2, respectively. If the power control by SSDT and the transmission diversity in the feedback mode are used at the same time, one bit is used for each of the S field and the D field.

Hereinafter, the SSDT operation to reduce the interference caused by the multiplex transmission in the soft handover mode will be described in more detail.

The SSDT is initially operated by the system side (UTRAN) based on the cells of the active group in the soft handover mode, and then the system side (UTRAN) of the SSDT option activated during the current soft handover period is Notify the cell and UE.

At this time, the temporary identifier is allocated based on the order of the active groups, and is transmitted to various effective cells and UEs which are activated.

A particular cell that has received an active list can know its entry position in the list from which it can determine its identifier code, while at the same time the UE (UE) receiving a valid list is a cell in that list. Each identifier code of valid cells according to the registration order can be determined. Therefore, the system side (UTRAN) and the user side (UE) have the same combination between the identifier code and the cells. At this time, the valid list is updated every time, and the updated valid list is transmitted to all valid cells and the UE.

After activation of SSDT and UE-side authentication, UE starts sending the identifier code of primary cell. Upon successful activation of SSDT and acceptance of UE-side authentication, valid cells detect Primary cell identifier information. To start.

The following describes the setting of the temporary cell identifier.

A temporary identifier is assigned to each cell during SSDT, and this identifier is used as a site selection signal.

If it is determined that the upper layer is to transmit between the UE and the cell in the SSDT mode, the UE determines the most appropriate one cell among the valid cells as the primary cell and informs the system side (UTRAN) through the FBI field.

In addition, since the signal is transmitted only in one cell when operating in the SSDT mode, inter-cell interference may be reduced for the remaining valid cells, thereby increasing cell performance.

The temporary cell identifier is given as a binary bit sequence having a specific bit length, which is shown in Tables 3 and 4 below. Table 3 shows a temporary identifier code when the FBI is 1 bit per slot, and Table 4 shows a temporary identifier code when the FBI is 2 bits per slot.

As shown in the following Tables 3 and 4, the temporary identifier code has three forms of "long", "medium", and "short", and there are eight codes for each of these forms. These temporary identifier codes must be transmitted within one frame. If the temporary identifier codes are not transmitted by being inserted into each FBI field of one frame and inserted into two frames, the last bit of the temporary identifier code is punctured. Puncturing).

Identifier label Identifier code long medium short a 000000000000000 0000000 (0) 00000 b 111111111111111 1111111 (1) 11111 c 000000001111111 0000111 (1) 00011 d 111111110000000 1111000 (0) 11100 e 000011111111000 0011110 (0) 00110 f 111100000000111 1100001 (1) 11001 g 001111000011110 0110011 (0) 01010 h 110000111100001 1001100 (1) 10101

In Table 3, the long identifier code having a code length of 15 has a minimum hamming distance (d _min ) of 7, and the medium identifier code having a code length of 8 has a minimum hamming distance (d _min ) of 4, For each medium identifier code with a code length of 8, the code length 7 identifier codes punctured the last bit has a minimum hamming distance (d _min ) of up to 3, and a short identifier code with a code length of 5 has a minimum Hamming. The distance d _min is at most 2.

Identifier label Identifier code long medium short a 0000000 (0) 0000000 (0) 000 (0) 000 (0) 000 000 b 1111111 (1) 1111111 (1) 111 (1) 111 (1) 111 111 c 0000000 (0) 1111111 (1) 000 (0) 111 (1) 000 111 d 1111111 (1) 0000000 (0) 111 (1) 000 (0) 111 000 e 0000111 (1) 1111000 (0) 001 (1) 110 (0) 001 100 f 1111000 (0) 0000111 (1) 110 (0) 001 (1) 110 011 g 0011110 (0) 0011110 (0) 011 (0) 011 (0) 010 010 h 1100001 (1) 1100001 (1) 100 (1) 100 (1) 101 101

In Table 4, a long identifier code having a code length of 16 has a minimum hamming distance (d _min ) of 8, and an identifier having a code length of 14 that punctures the last bit pair in each long identifier code having a code length of 16. Codes have a minimum Hamming distance (d _min ) of up to 6, code length of 8 medium identifier codes have a minimum Hamming distance (d _min ) of up to 4, and code length 8 of each medium identifier code The code length 6 punctured identifier codes have a minimum hamming distance (d _min ) of up to two, and the short identifier code of six code lengths has a minimum hamming distance (d _min ) of up to two.

Table 5 below shows the number of site selections for selecting a primary cell per frame for each identifier code type according to the characteristics of the temporary identifier codes shown in Tables 3 and 4.

Cord length SSDT  Assigned to Per slot FBI Number of bits One 2 "long" Per frame  Select site once Per frame  Select site twice "medium" Per frame  Select site twice Per frame  4 site selections "short" Per frame  3 times site selection Per frame  5 site selections

Referring to Table 5 above, first, when the FBI per slot is 1 bit, the long identifier code is transmitted 15 bits per frame, one bit in each slot, so that site selection is performed once per frame. If the FBI is 2 bits, the long identifier code is transmitted 30 bits per frame, 2 bits in each slot, thus making two site selections per frame.

Also, if the FBI per slot is 1 bit, the medium identifier code is transmitted 15 bits per frame, so two site selections per frame are made. If the FBI is 2 bits per slot, the medium identifier code is 30 per frame. Because the bits are transmitted, four site selections are made per frame.

Finally, if the FBI per slot is 1 bit, the short identifier code is transmitted 15 bits per frame, so three site selections per frame are made. Since 30 bits are transmitted, five site selections are made per frame.

As mentioned above, when the user side (UE) determines one of the temporary identifier codes as the primary cell identifier codes after the activation of the SSDT and the UE side (UE) acknowledgment, periodically through the FBI field of the uplink control channel. To pass.

If a cell receives a Primary cell identifier code that does not match its identifier code and the quality of the uplink signal received in this cell does not meet the threshold defined by the system side (UTRAN), this cell Becomes a non-primary cell.

 The end of the next SSDT is determined by the system side (UTRAN). The system side (UTRAN) terminates SSDT in the same manner as the soft handover termination procedure and informs all cells and the user side (UE) of this fact.

The performance of the cell identification code used to identify each cell in the conventional SSDT is determined by the maximum cross correlation function value or the minimum hamming distance d _min . Accordingly, an optimal cell identification code having a small maximum cross correlation function value or a maximum minimum hamming distance (d _min ) is currently required, and a cell identification method for achieving better performance using the same is required.

An object of the present invention has been devised in view of the above, and it is possible to satisfy a cell identification of optimal performance and to exhibit an optimal diversity effect in a soft handover mode. By using the (Bi-orthogonal code) to create an optimal SSDT cell identification code to maximize the minimum Hamming Distance (Minimum Hamming Distance), and provides a method for transmitting this more effectively through the uplink channel.

In order to achieve the above object, a feature of an optimal cell identification code generation and transmission method thereof according to the present invention is that a plurality of identifier codes to be assigned to valid cells by a user side (UE) during SSDT are Hadamard code and orthogonal code. And a number of bits to be inserted into the FBI field of each slot when the identifier code of the corresponding cell selected by the user side (UE) is to be transmitted through an uplink specific control channel. And the identifier code of the corresponding cell selected by the user side (UE) among the generated identifier codes is repeatedly transmitted one or more times according to the form of the code to the valid cells. .

Preferably, the code generating step generates the identifier code by puncturing a first bit of a Hadamard code having a code length of 8 and 16, and the first bit and the other one or the other according to the type of the identifier code. The other bits are punctured to generate the identifier code.

Here, an identifier code having a code length of 14 is generated by puncturing the first bit and the second bit of the Hadamard code having a code length of 16, and in some cases, the first bit and the ninth bit of the Hadamard code having the code length of 16 are generated. By puncturing, an identifier code having a code length of 14 is generated.

In the code transmission step, the identifier code generated by puncturing the identifier code generated using the code length 8 and 16 orthogonal codes, and the Hadamard code having the code length 8 and 16 according to the predetermined bit length for each frame, is generated. Are transmitted together in each frame.

Hereinafter, an exemplary embodiment of an optimal cell identification code generation and transmission method thereof according to the present invention will be described with reference to the accompanying drawings.

The temporary cell identifier is given as a binary bit sequence having a specific bit length, and the SSDT temporary identifier codes proposed by the present invention are shown in Tables 6 and 7 below.

Table 6 shows SSDT temporary identifier codes when the FBI is 1 bit per slot, and Table 7 shows SSDT temporary identifier codes when the FBI is 2 bits per slot.

As shown in Table 6 and Table 7, the temporary identifier code of the present invention has three types of "Long", "Medium", and "Short", and there are eight codes for each of these types. These temporary identifier codes must be transmitted within one frame. If the temporary identifier codes cannot be inserted and transmitted in each FBI field of one frame, and inserted in two frames, punctured identifier codes are used. do.

Identifier label Identifier code long medium (8) medium (7) short A 000000000000000 00000000 0000000 00000 B 101010101010101 11111111 1010101 10010 C 011001100110011 01010101 0110011 01001 D 110011001100110 10101010 1100110 11011 E 000111100001111 00110011 0001111 00111 F 101101001011010 11001100 1011010 10101 G 011110000111100 01100110 0111100 01110 H 110100101101001 10011001 1101001 11100

In Table 6, the long identifier code having a code length of 15 based on the Hadamard code has a minimum hamming distance (d _min ) of 8, and the medium identifier code having a code length of 8 based on the orthogonal code has a minimum value. the Hamming distance (d _min) and a maximum of 4, and a length of the eight Hadamard this is the first bit of a code length 7 punctured code identifier in the code may have up to four minimum Hamming distance (d _min), it is Short identifier codes with a code length of 5 have a minimum hamming distance (d _min ) of up to 2 based on the mad code.

Identifier label Identifier code (columns and rows represent slot positions and FBI bit positions) long (16) long (14) medium (8) medium (6) short A 00000000 00000000 0000000 0000000 0000 0000 000 000 000 000 B 11111111 11111111 0000000 1111111 1111 1111 000 111 000 111 C 00000000 11111111 1010101 1010101 0000 1111 101 101 101 101 D 11111111 00000000 1010101 0101010 1111 0000 101 010 101 010 E 01010101 01010101 0110011 0110011 0101 0101 011 011 011 011 F 10101010 10101010 0110011 1001100 1010 1010 011 100 011 100 G 01010101 10101010 1100110 1100110 0101 1010 110 110 110 110 H 10101010 01010101 1100110 0011001 1010 0101 110 001 110 001

In Table 7, the long identifier code having a code length of 16 has a minimum Hamming distance (d _min ) of up to 8 based on the 16 orthogonal code of the orthogonal code. The long identifier code with code length 14 puncturing the second bit has a minimum hamming distance (d _min ) of up to 7, and the medium identifier code with a code length of 8 based on the orthogonal code has a minimum hamming distance (d). _min ) is up to 4, and in an Hadamard code of length 8, code length 6 identifier codes puncturing the first and fifth bits have a minimum Hamming distance (d _min ) of up to 3, and Hadamard Based on the code, a short identifier code with a code length of 6 has a minimum hamming distance (d _min ) of up to three.

The temporary identifier codes of the present invention shown in Tables 6 and 7 above are generated based on the Hadamard codes of lengths 8 and 16, respectively, shown in Table 8, and the lengths shown in Table 9 are 8, respectively. Generated based on 16 orthogonal codes.

Hadamard code of length 8 Hadamard code of length 16 H _3,0 = 0000 0000 H _3,1 = 0101 0101 H _3,2 = 0011 0011 H _3,3 = 0110 0110 H _3,4 = 0000 1111 H _3,5 = 0101 1010 H _3,6 = 0011 1100 H _3,7 = 0110 1001 H _4,0 = 0000 0000 0000 0000 H _4,1 = 0101 0101 0101 0101 H _4,2 = 0011 0011 0011 0011 H _4,3 = 0110 0110 0110 0110 H _4,4 = 0000 1111 0000 1111 H _4,5 = 0101 1010 0101 1010 H _4,6 = 0011 1100 0011 1100 H _4,7 = 0110 1001 0110 1001 H _4,8 = 0000 0000 1111 1111 H _4,9 = 0101 0101 1010 1010 H _4,10 = 0011 0011 1100 1100 H _{4,11 = 0110 0110 1001 1001 H 4,12} = 0000 1111 1111 0000 H 4,13 = 0101 1010 1010 0101 H 4,14 = 0011 1100 1100 0011 H 4,15 = 0110 1001 1001 0110

In Table 8, the Hadamard code of length 8 and the Hadamard code of length 16 have a bit value of 0 because the first bit has a bit value of 0, so puncturing the first bit does not affect the minimum hamming distance. Does not have the property.

In particular, in the present invention, since eight SSDT identifier codes are used for each identifier code type, eight Hadamard codes of length 8 are used, and the top 8 of 16 are used for 16 Hadamard codes of length.

However, the peculiar thing is that all of the top eight Hadamard codes of length 16 used in the present invention have zero as the bit value in the ninth bit. As a result, puncturing these ninth bits does not affect the minimum hamming distance as it does when puncturing the first bit. Therefore, in the present invention, as shown in Table 10, a long identifier code having a code length of 14 puncturing the first bit and the ninth bit of length 16 is complementarily used.

8 orthogonal cord 16 orthogonal cords B _3,0 = 0000 0000 B _3,1 = 1111 1111 B _3,2 = 0101 0101 B _3,3 = 1010 1010 B _3,4 = 0011 0011 B _3,5 = 1100 1100 B _3,6 = 0110 0110 B _3,7 = 1001 1001 B _3,8 = 0000 1111 B _3,9 = 1111 0000 B _3,10 = 0101 1010 B _3,11 = 1010 0101 B _3,12 = 0011 1100 B _3,13 = 1100 0011 B _{3 , 14} = 0110 1001 B _3,15 = 1001 0110 B _4,0 = 0000 0000 0000 0000 B _4,1 = 1111 1111 1111 1111 B _4,2 = 0101 0101 0101 0101 B _4,3 = 1010 1010 1010 1010 B _4,4 = 0011 0011 0011 0011 B _4,5 = 1100 1100 1100 1100 B _4,6 = 0110 0110 0110 0110 B _4,7 = 1001 1001 1001 1001 B _4,8 = 0000 1111 0000 1111 B _4,9 = 1111 0000 1111 0000 B _4,10 = 0101 1010 0101 1010 B _{4,11 = 1010 0101 1010 0101 B 4,12} = 0011 1100 0011 1100 B 4,13 = 1100 0011 1100 0011 B 4,14 = 0110 1001 0110 1001 B 4,15 = 1001 0110 1001 0110 B 4,16 = 0000 _{0000 1111 1111 B 4,17 = 1111 1111} 0000 0000 B 4,18 = 0101 0101 1010 1010 B 4,19 = 1010 1010 0101 0101 B 4,20 = 0011 0011 1100 1100 B 4,21 = 1100 1100 0011 0011 B 4 _{, 22} = 0110 0110 1001 1001 B _4,23 = 1001 1001 0110 0110 B _4,24 = 0000 1111 1111 0000 B _4,25 = 1111 0000 0000 1111 B _4,26 = 0101 1010 1010 0101 B _4,27 = 1010 0101 0101 1010 B _4,28 = 0011 1100 1100 0011 B _4,29 = 1100 0011 0011 1100 B _4,30 = 0110 1001 1001 0110 B _4,31 = 1001 0110 0110 1001

In Table 9, the 8 orthogonal length code and the 16 orthogonal length code are more advantageous in terms of minimum Hamming distribution than the Hadamard codes of the same length. In other words, for 8 length orthogonal cords, the Hamming distance is 8 times the same as the code length, and for 16 length orthogonal codes, the Hamming distance is 16 equal to the code length. 4 times.

Therefore, in the present invention, eight medium identifier codes having a code length of 8 when the FBI is 1 bit per slot and 8 medium identifier codes having a code length of 8 when the FBI is 2 bits per slot, Use a 9 orthogonal code of length 9. In addition, when the FBI is 2 bits per slot, 8 long identifier codes having a code length of 16 are used.

However, all of the other SSDT identifier codes except for the above cases use the Hadamard codes shown in Table 8.

The following describes the generation procedure of SSDT identifier code generated based on Hadamard code and orthogonal code to maximize the minimum Hamming distance.

One of the principles for generating SSDT identifier codes based on the Hadamard code in this generation procedure is that, as mentioned earlier, the first bit of both the Hadamard code of length 8 and the Hadamard code of length 16 has a bit value of 0. Uses the points. As a result, even if the SSDT identifier code generated by puncturing the first bit of Hadamard code is transmitted, the minimum Hamming distance does not decrease and remains the same.

In addition, one of the generation principles of SSDT identifier code based on the orthogonal code in this generation procedure is that the minimum Hamming distribution is 8 or 16 length orthogonal codes compared to each Hadamard code of the same length. Take advantage of the benefits from the side.

First, the FBI is 1 bit in each slot.

Eight long identifier codes with a code length of 15 are created by puncturing the first bit of eight Hadamard codes with a code length of 16. Accordingly, the minimum hamming distance d _min is up to eight.

The following eight medium identifier codes of code length 8 use the eight orthogonal codes of code length 8. Accordingly, the minimum hamming distance d _min is at most 4.

The following eight medium identifier codes with a code length of seven are made by puncturing the first bit of eight Hadamard codes with a code length of eight. Accordingly, the minimum hamming distance d _min is at most 4.

The next 8 short identifier codes of code length 5 are made by puncturing the first bit of the 8 Hadamard codes of code length 8 first and then puncturing the two bits of the remaining arbitrary positions. The puncturing bit pattern for this is shown in Tables 10, 11, and 12, and the minimum hamming distance d _min is 2 in all cases.

The short identifier codes shown in Table 10, Table 11, and Table 12 above are commonly generated by puncturing the first bit of the Hadamard code having a code length of 8, and then the two bits are punctured into 21 patterns to form a final code. This is a short identifier code of length 5.

In other words, the short identifier codes of code length 5 shown in Table 10 are (1,2,3), (1,2,4), (1,2,5) in the order of eight Hadamard codes of code length 8, respectively. ), (1,2,6), (1,2,7), (1,2,8), (1,3,4) are generated by puncturing each three bits of the position pattern.

The short identifier codes of code length 5 shown in Table 11 are (1,3,5), (1,3,6), (1,3,7), in the order of eight Hadamard codes of code length 8, respectively. It is generated by puncturing each three bits of the (1,3,8), (1,4,5), (1,4,6), and (1,4,7) position patterns.

The short identifier codes of code length 5 shown in the last table 12 are (1,4,8), (1,5,6), (1,5,7), It is generated by puncturing each three bits of the (1,5,8), (1,6,7), (1,6,8), and (1,7,8) position patterns.

However, among the 21 puncturing position patterns described above, an optimal performance is achieved when using eight short identifier codes generated by puncturing the first, second, and sixth bits in eight Hadamard codes having a code length of eight. do.

In addition, the present invention is generated by puncturing the first bit and the second bit of the Hadamard code having a code length of 8 bits in common, as in some of the short identifier codes of Table 10 above, and the remaining 1 bit is 6 It is punctured with a pattern of branches, and in order (1,2,3), (1,2,4), (1,2,5), (1,2,6), (1,2,7), The short identifier code of 5 bits of the final code length generated by puncturing 3 bits of the (1, 2, 8) position pattern is used.

As such, when the first and second bits of the Hadamard code having 8 bits of code length are punctured to generate identifier codes of code length 5 or identifier codes of code length 6, a feedback identifier (FBI) field for each slot is generated. In the case where one bit is inserted into the slot or two bits are inserted into the feedback identifier (FBI) field for each slot, the identifier code can be generated by a common puncturing pattern. Can be implemented.

The following is an example of 2 bits of FBI for each slot.

The eight long identifier codes of code length 16 use the eight orthogonal codes of code length 16 as they are. Accordingly, the minimum hamming distance d _min is up to eight.

The next eight long identifier codes of length 14 are punctured by the first and second bits of the eight Hadamard codes with length 16. Accordingly, the minimum hamming distance d _min is up to seven.

The following eight medium identifier codes of code length 8 use the eight orthogonal codes of code length 8. Accordingly, the minimum hamming distance d _min is at most 4.

The following eight medium identifier codes with a code length of 6 are made by puncturing the first and second bits of eight Hadamard codes with a code length of 8. Accordingly, the minimum hamming distance d _min is up to three.

The next 8 short identifier codes of code length 6 are made by puncturing the first and second bits of the 8 Hadamard codes of code length 8. The minimum solution _min d _min is therefore up to three.

However, in the present invention, when the FBI in each slot is 2 bits, the SSDT identifier code generated by puncturing the first bit and the second bit of eight Hadamard codes having a code length of 16 as described above is complementary to each other. Use the SSDT identifier code in Table 13 that can be used as

Identifier label Identifier code (columns and rows represent slot positions and FBI bit positions) long (16) long (14) medium (8) medium (6) short A 00000000 00000000 0000000 0000000 0000 0000 000 000 000 000 B 11111111 11111111 1111000 0001111 1111 1111 000 111 000 111 C 00000000 11111111 0101101 1010101 0000 1111 101 101 101 101 D 11111111 00000000 1010101 1011010 1111 0000 101 010 101 010 E 01010101 01010101 0011011 0110011 0101 0101 011 011 011 011 F 10101010 10101010 1100011 0111100 1010 1010 011 100 011 100 G 01010101 10101010 0110110 1100110 0101 1010 110 110 110 110 H 10101010 01010101 1001110 1101001 1010 0101 110 001 110 001

In Table 13, the long identifier code of length 14 puncturing the first bit and the ninth bit in the Hadamard code having a length of 16 has a minimum hamming distance d _{min of} 8, and thus, Table 7 above. In Hadamard code of length 16, the long identifier code of length 14, puncturing the first bit and the second bit, is advantageous compared to the maximum hamming distance d _min .

The UE determines one of the generated SSDT identifier codes as the primary cell identifier code and periodically transmits the corresponding identifier code to the cells belonging to the active group. To pass.

The following describes the transmission procedure of the generated SSDT identifier code.

3 is a diagram for explaining various examples of cell identification code transmission when 1 bit is inserted into an FBI field for each slot in the present invention.

FIG. 3A illustrates a case in which a long identifier code having a code length of 15 is transmitted in one frame. The UE selects one of eight identifier codes having a code length of 15 shown in Table 6 into the FBI field of each slot. To transmit. Therefore, in this case, the number of site selections for selecting a primary cell per frame is once.

Next, FIG. 3B illustrates a case in which a medium identifier code having a code length of 8 and a medium identifier code having a code length of 7 are transmitted together in one frame. The UE selects one selected from eight identifier codes having a code length of 8 shown in Table 6. One bit is inserted into the FBI field of the first eight slots, and one selected from eight identifier codes having a code length of seven shown in Table 6 is inserted into each of the FBI fields by one bit into the remaining seven slots. Therefore, in this case, the number of site selections for selecting a primary cell per frame is twice.

Next, FIG. 3C illustrates a case in which a short identifier code having a code length of 5 is transmitted three times in one frame. A UE selects one of eight identifier codes having a code length of 5 shown in Table 6 and selects one FBI in five slot units. Transmit by repeatedly inserting one bit into the field. Therefore, in this case, the number of site selections for selecting a primary cell per frame is three times.

FIG. 4 is a diagram for explaining various examples of cell identification code transmission when 2 bits are inserted into the FBI field for each slot in the present invention.

FIG. 4A illustrates a case in which a long identifier code having a code length of 16 and a long identifier code having a code length of 15 are transmitted together in a frame, and a UE first selects one of eight identifier codes having a code length of 16 shown in Table 7. Insert 2 bits for each column in the FBI field of 8 slots, and insert one of the 8 identifier codes of code length 14 shown in Table 7 into 2 Fbits for each column in the remaining 7 slots. To transmit. Therefore, in this case, the number of site selections for selecting a primary cell per frame is twice.

Next, FIG. 4B illustrates a case in which a medium identifier code having a code length of 8 and a medium identifier code having a code length of 6 are transmitted together in one frame. The UE selects one of eight identifier codes having a code length of 8 shown in Table 7 below. Repeatedly insert 2 bits per column three times in each FBI field of four slot units among the first 12 slots, and select one of eight identifier codes of code length 6 shown in Table 7 in each of the three slots. Insert bit by bit and send. In this case, therefore, the number of site selections for selecting a primary cell per frame is four times.

4C shows a case in which a short identifier code having a code length of 6 is transmitted five times in one frame, and a UE selects one of eight identifier codes having a code length of 6 shown in Table 7 from each FBI in units of three slots. Transmit by repeatedly inserting two bits in the field. In this case, therefore, the number of site selections for selecting a primary cell per frame is five times.

The following is a performance evaluation result of the present invention described so far.

5A to 5D are diagrams illustrating a performance evaluation result for an AWGN channel when 1 bit is inserted into an FBI field for each slot in the present invention. FIGS. 6A to 6D are 2 for each slot in the present invention. In the case of being inserted bit by bit, it is a diagram showing the results of the performance evaluation for the AWGN channel.

In addition, Table 14 shows the performance gain of the present invention based on the existing performance gain for each identifier code type.

AWGN Channel 1 bit FBI for each slot 2 bits FBI for each slot long (15) medium (8) medium (7) short (5) long (16) long (14) medium (8) medium (6) short (6) existing 0 0 0 0 0 0 0 0 0 The present invention 0.3 0 0.7 0.25 0 0.25 0 0.8 0.8

The performance gain of Table 14 is used by the SSDT identifier code of code length 14, which is made by puncturing the first and second bits of the Hadamard code having a code length of 16 when the FBI is 2 bits per slot. If the long identifier code of length 14 puncturing the first and ninth bits of Hadamard code of length 16 is used, as shown in Table 13, the following table 15 is used. It has a performance gain as

AWGN Channel 1 bit FBI for each slot 2 bits FBI for each slot long (15) medium (8) medium (7) short (5) long (16) long (14) medium (8) medium (6) short (6) existing 0 0 0 0 0 0 0 0 0 The present invention 0.3 0 0.7 0.25 0 0.3 0 0.8 0.8

7A to 7D are diagrams illustrating a performance evaluation result for a fading channel when 1 bit is inserted into an FBI field for each slot in the present invention, and FIGS. 8A to 8D are 2 for each slot in the present invention. In the case of being inserted bit by bit, the result of the performance evaluation of the fading channel.

In addition, Table 16 shows the performance gain of the present invention based on the existing performance gain for each identifier code type.

AWGN Channel 1 bit FBI for each slot 2 bits FBI for each slot long (15) medium (8) medium (7) short (5) long (16) long (14) medium (8) medium (6) short (6) existing 0 0 0 0 0 0 0 0 0 The present invention 1.5 1.0 1.0 1.5 1.2 1.3 0.8 2.0 2.0

The performance gain of Table 16 is also used by the SSDT identifier code of code length 14 produced by puncturing the first and second bits of the Hadamard code having a code length of 16 when the FBI is 2 bits per slot. If the long identifier code of length 14 puncturing the first and ninth bits of the Hadamard code of length 16 is used, as shown in Table 13, the following table 17 It has a performance gain as

AWGN Channel 1 bit FBI for each slot 2 bits FBI for each slot long (15) medium (8) medium (7) short (5) long (16) long (14) medium (8) medium (6) short (6) existing 0 0 0 0 0 0 0 0 0 The present invention 1.5 1.0 1.0 1.5 1.2 2.2 0.8 2.0 2.0

In addition to the SSDT, the identifier code proposed in the present invention can be used when the UE transmits its own cell information to the system side UTRAN, and in this case, it is optimized for cross-correlation and minimum hamming distance. Can be.

As described above, according to the optimal cell identification code generation and transmission method thereof according to the present invention, in identifying each cell in the SSDT, a cycle is generated by using a combination of the cell identification code based on the Hadamard code and the orthogonal code. Maximize the use of fast identifier codes to maximize system performance on fading channels and AWGN channels. In addition, in receiving and decoding the cell identification code according to the present invention, the punctured bits are transmitted from the transmitting side, and thus the gain is maximized when decoding. In addition, the present invention uses a combination of the Hadamard code and the orthogonal code to generate and transmit a cell identification code having a small maximum absolute cross-correlation function and a maximum minimum hamming distance, thereby providing an optimum in soft handover mode. Diversity performance can be exhibited.                     

Claims (36)

Selecting a primary cell of the cells based on levels of common pilot signals received from the cells; Generating a cell identification code of the selected priority cell using a selected one of a punctured code or a quadrature code for at least one Hadamard code among the Hadamard codes; Repeatedly inserting the cell identification code of the priority cell one or more times into the feedback identifier field of each slot of one radio frame; And And transmitting the cell identification code of the priority cell inserted into the radio frame to the cells via an uplink control channel. . The method of claim 1, The Hadamard codes each have a code length of 8 bits or 16 bits, The puncturing is performed on at least one bit including the first bit of the selected one Hadamard code Characterized by A method for generating and transmitting a cell identification code for a priority cell at a user device. The method of claim 2, Said Hadamard codes each having a code length of 16 bits Characterized by, The puncturing is performed on the first bit and the second bit of the selected one Hadamard code, or is performed on the first bit and the ninth bit, The length of the punctured code is 14 bits And generating and transmitting a cell identification code for the priority cell in the user device. delete Selecting a primary cell of the cells based on levels of common pilot signals received from the cells; Generating at least one bit puncture of a selected one of the Hadamard codes to generate a cell identification code of the selected priority cell; And And transmitting the generated cell identification code of the priority cell to the cells. The method of claim 5, The puncturing is performed on the first bit of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 5, The puncturing is performed on the first and second bits of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 5, The puncturing is performed on a pair of bits of the selected one code, The pair of bits being the first bit of the first half of the selected one code and the first bit of the second half of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 5, The puncturing is performed on the first bit and at least one other bit of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 9, The at least one other bit being the second and sixth bits of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 5, The Hadamard codes each having a code length of 8 bits or 16 bits And generating and transmitting a cell identification code for the priority cell in the user device. Generating at least one bit puncture of each of the Hadamard codes to generate cell identification codes of cells; Periodically measuring levels of common pilot signals received from the cells to periodically select a primary cell of the cells; And And periodically transmitting the generated cell identification code of the priority cell to the cells. The method of claim 12, The puncturing is performed on a pair of bits of each of the Hadamard codes Characterized by, The pair of bits being the first bit of the first half of each of the Hadamard codes and the first bit of the second half of each of the Hadamard codes And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 12, The puncturing is performed on the first bit and at least one other bit of each of the Hadamard codes And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 12, Wherein the Hadamard codes have a code length of 8 bits or 16 bits, respectively, The puncturing is performed for the first bit of each of the Hadamard codes And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 12, Wherein the Hadamard codes have a code length of 8 bits or 16 bits, respectively, The puncturing is performed on the first bit and the second bit of each of the Hadamard codes And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 12, Each cell identification code is inserted into each feedback identifier (FBI) field of each slot in a radio frame by 1 bit or 2 bits. And generating and transmitting a cell identification code for the priority cell in the user device. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Generating a cell identification code of the selected priority cell using a selected one of a plurality of codes having a first bit value of all zeros; And Transmitting the generated cell identification code of the priority cell to the cells And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 18, The cell identification code of the priority cell is generated from a code that punctures a pair of bits of the selected one code. Characterized by, Wherein the pair of bits are the first bit of the first half of the selected one code and the first bit of the second half of each of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 18, The cell identification code of the priority cell is generated from a code puncturing the first bit of the selected one code. And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 18, Wherein the cell identification code of the priority cell is generated from a code in which the first bit and at least one other bit of the selected one code are punctured And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 21, The at least one other bit being the second bit of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 21, Said at least one other bit being a second bit and a sixth bit And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 18, Wherein the selected one code is zero in the first bit value of the second half of the selected one code. And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 24, Wherein the cell identification code of the priority cell is generated from a code in which the first bit of the selected one code is punctured And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 24, The cell identification code of the priority cell is generated from a code punctured by at least one other bit from the first bit of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 26, The at least one other bit being the second bit of the selected one code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 26, The at least one other bit being the second and sixth bits of the selected code And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 18, A plurality of codes in which the first bit value is all zeros, each having a code length of 8 bits or 16 bits And generating and transmitting a cell identification code for the priority cell in the user device. The method of claim 18, The plurality of codes in which the first bit value is all zeros are Hadamard codes And generating and transmitting a cell identification code for the priority cell in the user device. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Multiple identification codes, Identification Label Identification Code (Long: Long) A 000000000000000 B 101010101010101 C 011001100110011 D 110011001100110 E 000111100001111 F 101101001011010 G 011110000111100 H 110100101101001 Selecting one of the identification codes for the selected priority cells; And And transmitting a cell identification code for the priority cell to the cells. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Multiple identification codes, Identification Label Identification Code (Medium) A (0) 0000000 B (0) 1010 101 C (0) 0110011 D (0) 1100 110 E (0) 0001111 F (0) 1011010 G (0) 0111100 H (0) 110 1001 Selecting one of the identification codes for the selected priority cells; And And transmitting a cell identification code for the priority cell to the cells. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Multiple identification codes, Identification Label Identification Code (Short) A 00000 B 01001 C 11011 D 10010 E 00111 F 01110 G 11100 H 10101 Selecting one of the identification codes for the selected priority cells; And And transmitting a cell identification code for the priority cell to the cells. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Multiple identification codes, Identification Label Identification Code (Long: Long) A (0) 0000000                            (0) 0000000 B (0) 0000000                            (1) 1111111 C (0) 1010101                            (0) 1010101 D (0) 1010101                            (1) 0101010 E (0) 0110011                            (0) 0110011 F (0) 0110011                            (1) 1001100 G (0) 1100 110                            (0) 1100110 H (0) 1100 110                            (1) 0011001 Selecting one of the identification codes for the selected priority cells; And And transmitting a cell identification code for the priority cell to the cells. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Multiple identification codes, Identification Label Identification Code (Medium) A (0) 000                           (0) 000 B (0) 000                           (1) 111 C (0) 101                           (0) 101 D (0) 101                           (1) 010 E (0) 011                           (0) 011 F (0) 011                           (1) 100 G (0) 110                           (0) 110 H (0) 110                           (1) 001 Selecting one of the identification codes for the selected priority cells; And And transmitting a cell identification code for the priority cell to the cells. Selecting a priority cell among the cells based on the levels of common pilot signals received from the cells; Multiple identification codes, Identification Label Identification Code (Short) A 000                            000 B 000                            111 C 101                            101 D 101                            010 E 011                            011 F 011                            100 G 110                            110 H 110                            001 Selecting any one of as an identification code for the selected priority cell; And And transmitting a cell identification code for the priority cell to the cells.

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