KR101467800B1 - Ranging structure and multiplexing method for legacy support mode - Google Patents

Abstract

The present invention relates to a method of performing communication in a wireless communication system. According to another aspect of the present invention, there is provided a method of performing ranging in a wireless communication system, the method comprising: selecting a specific ranging structure from among two or more ranging structures having different accessibility according to terminal capabilities; And transmitting the ranging signal upward, wherein at least two of the time resources, the frequency resources, and the ranging codes are set to be different from each other.

Description

[0001] RANGING STRUCTURE AND MULTIPLEXING METHOD FOR LEGACY SUPPORT MODE FOR SUPPORTING LEGACY SUPPORT MODE [0002]

The present invention relates to a method of performing communication in a wireless communication system. More specifically, the present invention relates to a ranging structure and a multiplexing technique for supporting a legacy support mode in a wireless communication system. More particularly, the present invention relates to a ranging structure and a multiplexing technique when IEEE 802.16e ranging structure and IEEE 802.16m ranging structure are used together.

An IEEE 802.16m system (hereinafter referred to as a 16m system) must operate in two modes. Specifically, in the legacy support mode, the 16m system must be capable of simultaneously supporting the existing IEEE 802.16e terminal (hereinafter referred to as 16e terminal) and the new IEEE 802.16m terminal (hereinafter referred to as 16m terminal). In the IEEE 802.16m only mode, the 16m system only needs to support the 16m terminal without considering the IEEE 802.16e system (hereinafter referred to as the 16e system). In the legacy support mode, the 16m system must simultaneously support the existing 16e terminal and the 16m terminal, so that the operation of the legacy support mode can restrict the design of the 16m system. In addition, since the 16m terminal can support the 16e system, there is a problem whether all the resources of the two structures are allocated in the legacy support mode when the 16e and 16m systems support resources having different structures. Also, how to use the 16m ranging structure and the 16e ranging structure in a 16m system is problematic.

FIG. 1 is a diagram illustrating an example of multiplexing resources of 16e and 16m systems in Time Division Duplex (TDD) in terms of TDM (Time Division Multiplexing) and FDM (Frequency Divisor Multiplexing). In the figure, the horizontal axis represents the time domain and the vertical axis represents the frequency domain. The frequency domain may be composed of logical frequencies (logical subchannels, resource blocks, resource units, etc.). In other words, when a 16e system operates in a Partial Usage of SubChannelization (PUSC) mode using distributed resource allocation, a set of bands (subchannels, resource blocks, resource units, etc.) And the other non-adjacent bands constitute the frequency domain of the 16m system. Different permutation rules may be applied in the frequency domain of the 16e and 16m systems. In FIG. 1, the positions and configurations of the preamble, the Frame Control Header (FCH), the MAP and the UL control are examples and may be different from actual ones. The important point is that a legacy zone (or segment, area) and a 16m zone (or segment, area) can be supported simultaneously in a subframe using TDM and FDM.

In the 16e system, ranging is used for four purposes: Initial ranging, Handover (HO) ranging, Periodic ranging and Bandwidth Request (BR) ranging. The initial ranging is used to adjust the uplink time synchronization (i.e., time and frequency synchronization) when the UE initially accesses the wireless communication system. The handover ranging is used for initial synchronization with the target base station in case of changing the connection from the source base station to the target base station. The periodic ranging is used by the UE to periodically update the uplink synchronization. The bandwidth request ranging is used by the terminal to request the uplink resource from the base station.

FIG. 2 and FIG. 3 show OFDMA (Orthogonal Frequency Division Multiple Access) symbol structures used for ranging, respectively. Referring to FIG. 1, the ranging structure is composed of one to four OFDMA symbols according to applications. Also, the ranging structure uses different ranging codes according to the use. In this specification, the ranging structure can be used in combination with the ranging channel, ranging channel structure, and the like.

4 shows a PRBS (pseudo random binary sequence) generator for generating ranging codes. The ranging code is generated by a PN (pseudo random noise) code generation formula 1 + X ¹ + X ⁴ + X ⁷ + X ¹⁵ . B0 = 0, 0, 1, 0, 1, 1, 1, s0, s1, s2, s3, s4, s5, s6, and s6 Represents the LSB (Least Significant Bit) of the PRSB initial value, and s6: s0 = UL_PermBase. In this case, s6 indicates the MSB (Most Significant Bit) of UL_PermBase. A total of 256 codes can be generated using the PN generation formula, and these codes are classified according to each application. The first N codes are used for the initial ranging purpose, the following M codes are used for the periodic raging, the following L codes are used for the BR ranging purpose, and the following O codes are used for the HO ranging code Is used.

In the ranging process, a ranging signal of a non-synchronized terminal may cause inter-subcarrier interference in an adjacent data / control channel in the physical frequency domain. Subcarrier-interfering may be greater if the resources that make up the ranging channel are not adjacent on the physical frequency. Thus, the 16m ranging channel being discussed can be designed to use only ubiquitous (or adjacent) frequency bands. However, if the legacy support mode is supported by FDM as illustrated in FIG. 1, it may become impossible to allocate ubiquitous (or adjacent) frequency bands for the 16m ranging channel. Therefore, different considerations are needed in the legacy support mode. That is, the 16m ranging channel can be designed differently from the 16e ranging channel. For example, the resource usage method (permutation, resource allocation, etc.) of the 16m ranging channel and the 16e ranging channel may be different from each other.

Also, the 16e ranging channel has limited coverage. Figure 5 shows the limitation of coverage due to the structure of the 16e ranging channel. Referring to FIG. 5, a correlation peak is observed at the same position when the time delay is k (<T ₀ ) and the time delay is k + T ₀ , based on the effective OFDMA symbol length (T ₀ ). That is, 16e ranging channel can not support the case where the time delay is greater than T _0. Thus, the coverage of the 16e system is limited by T ₀ , and the cell radius is around 12 km when considering the maximum round trip delay.

16m According to the system requirements, the 16m system shall support up to 100km of cell radius. Therefore, in 16m only mode, the 16m ranging channel must have a different structure from the 16e ranging channel. However, in the legacy support mode, the actual cell radius is limited by the 16e ranging channel even if the cell radius that the 16m ranging channel can support is large. As described above, since the coverage request is relaxed in the legacy support mode, the 16m terminal can reuse the structure of the 16e ranging channel without considering a separate channel structure.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method for efficiently supporting a legacy system in a wireless communication system.

It is another object of the present invention to provide a ranging method for a terminal operating in a legacy support mode.

It is still another object of the present invention to provide a ranging structure that operates efficiently in the legacy support mode.

It is still another object of the present invention to provide a ranging performing method in a case where a 16e ranging structure and a 16m ranging structure exist simultaneously.

It is still another object of the present invention to provide a method of adjusting a load when a 16e ranging channel and a 16m ranging channel exist simultaneously.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

According to an aspect of the present invention, there is provided a method of performing ranging of a terminal in a wireless communication system, the method comprising: selecting a specific ranging structure from among two or more ranging structures having different accessibility according to a terminal capability; Wherein the at least one of the time resources, the frequency resources, and the ranging codes are set to be different from each other, wherein the at least one of the time resources, the frequency resources, and the ranging codes are set to be different from each other .

Preferably, the particular ranging structure may be selected at random.

Preferably, the specific ranging structure may be selected based on a predetermined criterion. Here, the predetermined criteria may relate to a probability value, a capability of the terminal, a state of the terminal, or any combination thereof. In addition, the probability value may be dynamically changed depending on whether the ranging is successful or unsuccessful. In addition, the method may further include receiving information on the predetermined criterion from a base station.

Preferably, each of the ranging codes used in the two or more ranging structures may be a code generated using different seed values.

Preferably, each ranging code used in the two or more ranging structures may be a code generated so as to be distinguished from each other by using the same seed value. Here, the cyclic shift values of the ranging codes may be different from each other. Preferably, the phase difference between each ranging code may be 90 [deg.]. Also, each of the ranging codes may be generated using different code generation formulas. Preferably, the different code generation equations may be inversely related to each other. Further, the different code generation equation ^{1 + X 1 + X 4 +} X 7 + X 15 PN (Pseudo random Noise) code generating formula, and ^{1 + X 8 + X 11 +} X 14 + X 15 PN code comprises a generation equation can do.

Preferably, each of the ranging codes may have different code lengths depending on the available system bandwidth.

Preferably, each ranging code used in the two or more ranging structures is selected from a PN (Pseudo-random Noise) code, a CAZAC (Constant Amplitude Zero Auto-Correlation) sequence, and a GCL (Generalized Chirp- can be different.

According to the embodiments of the present invention, the following effects are obtained.

First, when the 16e ranging structure and the 16m ranging structure coexist, the 16m terminal increases the communication efficiency by selectively using the ranging structure.

Second, when the 16e ranging structure and the 16m ranging structure coexist, the load control of the terminal attempting ranging can be made flexible.

Thirdly, the UE can transmit information on its capability / status (e.g., H-FDD or F-FDD support, emergency status, LBS service, etc.) through ranging.

Fourth, the 16e and 16m terminals can use the same ranging structure, and terminals requiring urgent and / or LBS services can use a further assigned ranging structure.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

Hereinafter, the structure, operation and other features of the present invention will be readily understood by the embodiments of the present invention described with reference to the accompanying drawings. The embodiments described below are examples in which the technical features of the present invention are applied.

Legacy Support  for Raging  Structure and code

Example 1-1. How to use time / frequency resources and codes

6A to 6C show examples of dividing the 16e ranging structure and the 16m ranging structure into time / frequency resources and / or codes in the legacy support mode. In the figure, each box represents a ranging slot.

Referring to FIG. 6 (a), the 16e ranging structure and the 16m ranging structure use the same time / frequency resource, and each ranging structure is divided into codes. In this case, additional time / frequency resource allocation for the 16m ranging structure is not required. That is, the 16e terminal and the 16e terminal attempt ranging using the same time / frequency resource. Instead, the 16e terminal uses the 16e code and the 16m terminal uses the 16m code to attempt ranging. All or part of the 16e ranging slot can be used for 16m ranging.

Referring to FIG. 6 (b), the 16e ranging structure and the 16m ranging structure use different time / frequency resources. Since the 16e ranging structure and the 16m ranging structure are divided into time / frequency resources, the codes used for each channel can be the same. However, if the specific 16m terminal can use both the 16e ranging structure and the time / frequency resources allocated to the 16m ranging structure, the base station can not determine whether the ranging terminal is the 16e terminal or the 16m terminal. In addition, when the 16e ranging structure and the 16m ranging structure are assigned to the same time / frequency resource between neighboring cells without code discrimination, interference between each other increases, and erroneous detection may occur as an adjacent cell signal. Therefore, it is preferable that different codes are used even when different time / frequency resources are used for the 16e ranging structure and the 16m ranging structure. In addition, the time / frequency resources of the 16m ranging structure described above may be allocated not only to the 16m area but also to the 16e area. When the time / frequency resource of the 16m ranging structure is allocated to the 16e area, the time / frequency resource of the 16m ranging structure may be allocated to overlap the time / frequency resource of the 16e ranging structure, Lt; / RTI &gt; That is, the above method can be used in combination with the method illustrated in FIG. 6 (a).

The 16e ranging structure uses a 16e ranging code and 144 subcarriers x 2 OFDMA symbols. In the legacy support mode, the 16m ranging structure uses a 16m ranging code and 144 subcarriers x 2 OFDMA symbols. If the 16m ranging structure is allocated to the 16e area, the time / frequency resource of the 16m ranging structure may be the same as or different from the time / frequency resource of the 16e ranging structure. The resource allocation relationship of the 16e and 16m ranging structures can be determined by the base station. When the 16m ranging structure is allocated to the 16e area, the 16m terminal can know the physical resource to which the 16m ranging structure is allocated according to the 16e system resource allocation method (e.g., permutation, PUSC, AMC, etc.). Also, the 16m ranging structure can be allocated to the 16m area. In this case, the 16m terminal knows the physical resource to which the 16m ranging structure is allocated according to the resource allocation method (permutation, etc.) of the 16m system. That is, the allocation position of the 16m ranging structure in the legacy support mode is 16e And may be allocated to the 16e or 16m area without limitation.

Referring to FIG. 6 (c), a 16m code can be allocated to the time / frequency resource for the 16e ranging structure. In this case, even if the specific 16m terminal can use both the 16e ranging structure and the 16m ranging structure time / frequency resources, the base station attempts to perform ranging using a code allocated to each time / frequency resource, It is possible to know whether the terminal is a 16m terminal or not. The 16m codes allocated to the 16e ranging structure and the 16m ranging structure may be the same or may be different from each other. Since the 16e ranging structure and the 16m ranging structure use different resources, it is not necessary to use the same code. In this case, the 16m code only may include a Zadoff-Chu sequence of a CAZAC (Constant Amplitude Zero Auto-Correlation) sequence, a GCL (Generalized Chirp-Like) sequence, and the like. These codes exhibit lower cross-correlation characteristics than existing 16e ranging codes when multiple users access simultaneously.

6 (a) to 6 (c) illustrate the present invention based on one ranging slot. However, the present invention is also applicable to a case where a plurality of ranging slots exist. However, when the present invention is applied to a plurality of ranging slots, it is also possible to apply the above method to all ranging slots, or to apply the above method to only some of the ranging slots. Also, although the above method is described separately, it can be used in combination when a plurality of ranging slots are applied.

In the above description, time / frequency resources represent physical locations in the frequency and time domain. In addition, even if the time / frequency resources are different, the ranging structure can be practically the same. The 16e ranging structure and the 16m ranging structure may be designed to be the same or different from each other. Also, in case of the TDD or FDD multiplexing of the legacy 16e system and the 16m system, the 16m ranging structure can be located in the 16e legacy area, and conversely, the 16e ranging structure can be located in the 16m area. Each ranging structure and physical location does not impose any restriction on the present invention.

Examples 1-2. Additional 16m Raging  Code allocation techniques

Assuming the situation illustrated in FIG. 6, a 16m code set can be set for the 16e ranging structure to know the state of the terminal attempting ranging (e.g., 16e terminal or 16m terminal). The 16m code may reserve a portion of the existing 16e code for 16m ranging. In this case, the code resources used in the 16e ranging structure are reduced. Also, the 16m code may be new code independent of the existing 16e code. In this case, considering the case where the resources of the 16e and 16m ranging structures are overlapped with each other, the new code for the 16m ranging needs to have good mutual-correlation characteristics with the code for the 16e ranging, thereby giving less influence on the legacy ranging performance have. Also, considering the case where the resources of the 16e and 16m ranging structures do not overlap each other, when considering the code reuse factor and the inter-cell interference, the mutual-correlation characteristics of the 16m code and the 16e code are important factors Lt; / RTI &gt; An increase in cross-correlation causes an increase in false alarm rate and a decrease in detection probability at the time of detecting the ranging signal. Therefore, the cross-correlation property between the new 16m code and the 16e code should be able to guarantee a performance similar to the cross-correlation property between at least 16e codes.

Hereinafter, a method of generating the 16m ranging code will be described in detail.

FIG. 7 shows an example in which a code not used in the 16e code is used as a 16m ranging code. The 16e system generates long PN codes and then cuts them in 144 units to generate several short codes. A total of 256 short 16e codes can be generated from long PN codes generated with one seed value. The 256 short 16e codes are divided into S number, N number, M number, L number and O number in order. S is used by each base station to use the subgroup for the 16e code. N [144 * ((S + N) mod 256) - 144 * ((S + N) mod 256) -1] for the initial ranging, (S + N + M) mod 256) to 144 * ((S + N + M + L) mod 256) for periodic lagging. (S + N + M + L + O) mod 256) -1] for the bandwidth request, O [144 * It is used for overrunning. FIG. 7A illustrates that the sequence remaining after allocating a code for ranging in each cell can be used as a 16m code. Fig. 7 (b) shows that S, which is a front part of a sequence not used in the cell, can be used for 16 m. Fig. 7 (c) shows the combined use of the methods illustrated in Figs. 7 (a) and 7 (b).

Figure 8 illustrates another method of reusing a 16e code into a 16m code. In a 16e system, each 16e ranging channel corresponds one-to-one with the corresponding code set. As an example, the 16e initial ranging channel uses code set N. [ Thus, if the 16m initial ranging channel uses codes other than code set N (e.g., code set S, M, L, or O), then the 16e initial ranging channel and the 16m initial ranging channel can be distinguished. That is, by changing the one-to-one correspondence relationship between each 16e ranging channel and the corresponding code set, the existing 16e code can be reused as the 16m code. In this case, since the existing 16e code is reused, mutual-correlation property is ensured and it is not necessary to secure additional code resources.

As described above, when the 16m code reuses the 16e code (that is, the seed value for code generation is the same), the mutual-correlation property of the 16e code and the 16m code and thus the ranging detection performance, etc., As shown in FIG.

Figures 9 (a) - (c) show the self-correlation and cross-correlation properties of codes with seed values of [0 0 1 0 1 0 1 1 0 0 0 0 0 0]. Figure 9 (a) is a self-correlation graph with a peak of 1. FIG. 9 (b) shows normalized cross-correlation characteristics among 200 codes generated by the seed value. The maximum peak is 0.30108 and the average is 0.073886. FIG. 9 (c) shows the normalized cross-correlation property between the third code and the 100th code. The maximum peak is 0.25205 and the average is 0.072772.

10 shows an example of generating 16e code and 16m code using different seed values. Referring to Fig. 10, the 16e code uses the seed value x, and the 16m code uses the seed value y (? X). Cross-correlation properties between codes generated using different seed values are shown in FIGS. 11-13.

11 (a) and 11 (b) use [0 0 1 0 1 0 1 1 0 0 0 0 0 0] & [0 0 1 0 1 0 1 1 0 0 0 0 0 1] as seed values Correlation property between the 16e code and the 16m code generated by the above method. 11 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30108 and the average is 0.073861. 11 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.21349 and the average is 0.07457.

12 (a) and 12 (b) use [0 0 1 0 1 0 1 1 0 0 0 0 0 0] & [0 0 1 0 1 0 1 1 0 1 0 0 0 0] as seed values Correlation property between the 16e code and the 16m code generated by the above method. 12 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30108 and the average is 0.073869. 12 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.23285 and the average is 0.073784.

13 (a) and 13 (b) use [0 0 1 0 1 0 1 1 0 0 0 0 0 0] and [1 0 1 0 1 0 1 1 0 0 0 0 0 0] as seed values Correlation property between the 16e code and the 16m code generated by the above method. 13 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30876 and the average is 0.073897. 13 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.23079 and the average is 0.073311.

The results for the cross-correlation characteristics of FIG. 11-13 are summarized in Table 1.

x & x (FIG. 9B)
x & y1 (Fig. 11A)
x & y2 (Fig. 12A)
x & y3 (FIG. 13A)
Maximum peak
0.30108
0.30108
0.030108
0.30876
The difference with the self-correlation peak
0.69892
0.69892
0.69892
0.69124
Average
0.073886
0.073861
0.073869
0.073897

In the above table, x is a seed value for 16e code generation, and y1-y3 (x) is a seed value for new 16m code generation. In Fig. 9B, the 16e code and the 16m code are generated using the same seed value.

From the above results, it can be seen that the 16e code and the 16m code generated using different seed values can maintain almost the same cross-correlation property as the code generated using the same seed value.

14 shows an example of generating a 16m code by phase shifting (or rotating) a 16e code. Referring to Fig. 14, the 16e code is generated using the seed value x, and the 16m code is generated by multiplying the 16e code by e ^{j & amp} ; ^thetas; in the frequency domain. In this case, the 16m code is a sample cyclic shift of the 16e code in the time domain. Here,? Is the magnitude of the phase shift of 0 to 2?. If θ = -2 π kl / N , then e ^{j θ} is in the form e ^{-2 π kl / N.} Where k represents the element index or subcarrier index for the entire code or the scrambling code, and N represents the total code length or the length of the scrambling code. That is, for a 16e code, N may be the total code length or the truncation code length (e.g., 144). l represents the number of samples that are cyclically shifted in the time domain. The size of the phase that is cyclically shifted in the frequency domain or the size of the sample that is cyclically shifted in the time domain is not limited. However, considering that the 16e code is always transmitted as a binary code in real form, it may be desirable that the 16m code is an imaginary form of the 16e code (i.e., a 90 ° phase shift). The cross-correlation characteristics between the 16e code and the 16m code generated by phase shifting the 16e code are shown in FIGS. 15-23.

15-17 generates 16e code by using [1 0 1 0 1 0 1 1 0 0 0 0 0 0] as the seed value, multiplies the 16e code by e ^{-2 π kl / N} , . Here, N is 32767 and k is 0 to (N-1). l is 10, 50, and 150, respectively.

15 (a) and 15 (b) show cross-correlation characteristics between 16e code and 16m code when l = 10. 15 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30143 and the average is 0.073886. 15 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.25467 and the average is 0.072774.

16 (a) and 16 (b) show cross-correlation characteristics between 16e code and 16m code when l = 50. 15 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.3101 and the average is 0.073891. 15 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.25375 and the average is 0.07297.

17 (a) and 17 (b) show cross-correlation characteristics between 16e code and 16m code when l = 150. Figure 17 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.31503 and the average is 0.073887. FIG. 17 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.2578 and the average is 0.072847.

The results for the cross-correlation characteristics of FIGS. 15-17 are summarized in Table 2.

x & x (l = 0)
(Figure 9b)
x & x (l = 10)
(Fig. 15A)
x & x (l = 50)
(Fig. 16A)
x & x (l = 150)
(Fig. 17A)
Maximum peak
0.30108
0.30143
0.03101
0.31053
The difference with the self-correlation peak
0.69892
0.69857
0.6899
0.68947
Average
0.073886
0.073886
0.073891
0.073887

In the above table, x is a seed value for 16e code generation, and 1 is a circular transition size in terms of the number of samples.

From the above results, it can be seen that the 16m code generated by multiplying the 16e code and the 16e code by e ^{j ?} Can maintain almost the same cross-correlation property as the code generated using the same seed value.

Figs. 18-20 are diagrams for generating 16e codes using [1 0 1 0 1 0 1 1 0 0 0 0 0 0] as the seed values, multiplying the 16e codes by e ^{-2 π kl / N} , . Here, N is 144 and k is 0 to (32767-1). l is 10, 50, and 150, respectively.

Figs. 18 (a) and 18 (b) show cross-correlation characteristics between 16e code and 16m code when l = 10. 18 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.33102, and the average is 0.073897. 18 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.23078 and the average is 0.07336.

Figs. 19 (a) and 19 (b) show cross-correlation characteristics between 16e code and 16m code when l = 50. Figure 19 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30322, and the average is 0.07389. FIG. 19 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.28107 and the average is 0.073191.

20 (a) and 20 (b) show cross-correlation characteristics between 16e code and 16m code when l = 150. Figure 20 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30108 and the average is 0.073886. 20 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.23376 and the average is 0.073298.

The results for the cross-correlation characteristics of FIGS. 18-20 are summarized in Table 3.

x & x (l = 0)
(Figure 9b)
x & x (l = 10)
(Fig. 18A)
x & x (l = 50)
(Fig. 19A)
x & x (l = 150)
(Fig. 20A)
Maximum peak
0.30108
0.33102
0.30322
0.30108
The difference with the self-correlation peak
0.69892
0.66898
0.6899
0.68947
Average
0.073886
0.073897
0.07389
0.073886

In the above table, x is a seed value for 16e code generation, and 1 is a circular transition size in terms of the number of samples.

From the above results, it can be seen that the 16m code generated by multiplying the 16e code and the 16e code by e ^{j ?} Can maintain almost the same cross-correlation property as the code generated using the same seed value.

FIGS. 21-23 show that the 16e code is generated by using [1 0 1 0 1 0 1 1 0 0 0 0 0 0] as the seed value, and the 16e code is multiplied by e ^{-2 π kl /} . Where N is 144 and k is 0 to (144-1) for each scrambling code. l is 10, 50, and 150, respectively.

Figs. 21 (a) and 21 (b) show cross-correlation characteristics between 16e code and 16m code when l = 10. Figure 21 (a) shows normalized cross-correlation properties between 16e codes (200) and 16m codes (200). The maximum peak is 0.33102, and the average is 0.073897. FIG. 21 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.23078 and the average is 0.07336.

22 (a) and 22 (b) show cross-correlation characteristics between 16e code and 16m code when l = 50. 22 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30322, and the average is 0.07389. 22 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.28107 and the average is 0.073191.

23 (a) and 23 (b) show cross-correlation characteristics between the 16e code and the 16m code when l = 150. 23 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30108 and the average is 0.073886. FIG. 23 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.23376 and the average is 0.073298.

The results for the cross-correlation characteristics of FIGS. 21-23 are summarized in Table 4.

x & x (l = 0)
(Figure 9b)
x & x (l = 10)
(Fig. 21A)
x & x (l = 50)
(Fig. 22A)
x & x (l = 150)
(Fig. 23A)
Maximum peak
0.30108
0.33102
0.30322
0.30108
The difference with the self-correlation peak
0.69892
0.66898
0.6899
0.68947
Average
0.073886
0.073897
0.07389
0.073886

In the above table, x is a seed value for 16e code generation, and 1 is a circular transition size in terms of the number of samples.

From the above results, it can be seen that the 16m code generated by multiplying the 16e code and the 16e code by e ^{j ?} Can maintain almost the same cross-correlation property as the code generated using the same seed value.

As another example, the 16e code and the 16m code can be generated using different PN generation expressions. The PN codes generated from different generation expressions have orthogonality with each other. The PN generation equation of the 16e code is 1 + X ¹ + X ⁴ + X ⁷ + X ¹⁵ . Therefore, the code generated using the 16e code and another generation formula can be used as the 16m code. In particular, a code generated from a specific PN generation expression and a code generated from a PN generation expression corresponding to the reciprocal of the specific PN generation expression have excellent mutual-correlation characteristics. The code generated from the PN generation equation corresponding to the reciprocal is generated by simply replacing the code (x ₁ , x ₂ , ..., x _{N -2} , x _{N -1} ) generated from the original PN generation expression _{N -1} , x _{N -2} , ..., x ₂ , x ₁ ). For example, 16m code may be generated by using the ^{1 + X 8 + X 11 +} X 14 + X 15 corresponding to the inverse of the code 16e generation equation.

Figures 24 (a) and (b) show cross-correlation characteristics when 16e code and 16m code are generated from different PN generation equations. The seed value for generating the 16e code and the 16m code is the same as [1 0 1 0 1 0 1 1 0 0 0 0 0 0]. The PN generation formulas for generating the 16e code and the 16m code are 1 + X ¹ + X ⁴ + X ⁷ + X ¹⁵ and 1 + X ⁸ + X ¹¹ + X ¹⁴ + X ^15, respectively. 24 (a) shows the normalized cross-correlation property between 16e codes (200) and 16m codes (200). The maximum peak is 0.30108 and the average is 0.073896. FIG. 24 (b) shows the normalized cross-correlation property between the 3 rd 16e code and the 100 th 16m code. The maximum peak is 0.24903, and the average is 0.074018. That is, the 16e code and the 16m code generated from the PN generation expression having reciprocal relations with each other can exhibit almost the same cross-correlation characteristic as the codes generated from the same PN generation expression shown in FIG. 9 (b).

In the above example, using the 16e ranging structure as it is as a 16m ranging structure means a structure in which a ranging code is allocated to each subcarrier as data is allocated to each subcarrier in OFDM. In this case, the data subcarrier spacing and the ranging subcarrier spacing are the same. Hereinafter, the length of the actual ranging code and the number of subcarriers and the variation of how many OFDM symbols are used in time do not depart from the meaning of the same structure.

In the above description, the 16m ranging structure uses the same time / frequency resources and codes of the same length as the 16e ranging structure. However, the above description is merely an example for facilitating understanding of the present invention. The 16m ranging structure may use time / frequency resources and / or code lengths of different types / sizes from 16 ranging structure. The 16m ranging structure can use a time / frequency region smaller than the 16 ranging structure and can use a code shorter than the code assigned to the 16 ranging structure. In this case, the frequency bandwidth of the 16m ranging structure is preferably equal to the frequency bandwidth of the ranging structure used in the 16m only mode. For example, it is possible to reduce the frequency resource from 144 subcarriers to 72 subcarriers, so that 72 length codes instead of 144 length codes can be used. In this case, the 16m ranging structure may use only some of the 144 length codes (e.g., 72 length codes from the beginning) after generating a 144-length small code from the long PN code for the same operation as the 16e ranging structure.

Example 1-3: New 16m Raging  Allocation of code

In the previous section, we discussed how to generate 16m code using PN code used in 16e code. Hereinafter, a method of generating a 16m ranging code using a different kind of code instead of a short PN code will be discussed. For example, a 16m ranging code may be generated using a CAZAC sequence. In this case, it may be difficult to generate a code of a specific length due to the characteristics of the CAZAC sequence. For example, when the length of the 16m ranging code is not a prime, in the case of a CAZAC sequence (e.g., a Zadoff-Chu sequence), the number of codes having orthogonality is small. Therefore, it is preferable to modify the length of the ZC sequence after generating the ZC sequence of the decimal length adjacent to the length of the 16m ranging code.

For example, a ZC sequence having the smallest number of decimal digits of the number larger than the required length can be generated, and then used for a required length. When the 16m ranging structure uses the same number of subcarriers as the 16e ranging structure (i.e., 144 code lengths), a 16m ranging code can be generated by truncating 5 samples in a 149-length ZC sequence. The cut-off position may be a sample before or after the sequence.

As another example, a ZC sequence having the largest decimal length in the number less than the required length may be generated and zero added to provide the required length. As an example, a 16m ranging code of 144 lengths may be generated by adding 0 to 5 samples to a 139-length ZC sequence. The position of 0 may be the sample before or after the sequence.

As another example, a ZC sequence having a largest decimal length among a number smaller than a required length may be generated and cyclic extended to a required length. For example, a 144-length 16m ranging code may be generated by generating a 139-length ZC sequence and cyclically expanding 5 samples. It is also possible to copy a cyclic extension to the back side by copying as many copies as necessary from the preceding sample, or copy the necessary number from the back sample and insert it in the front side.

Multiplexing

Example 2-1: Load regulation and / or identification

When the 16e terminal and the 16m terminal coexist, the 16e terminal can not use the information and resources of the 16m system. That is, the 16e terminal can use only the 16e ranging structure. On the other hand, a 16m terminal can use a 16e ranging structure as well as a 16m ranging structure. 16e terminal and 16m terminal can exist together in the cell of the 16m system and the number / ratio of the 16e terminal and the 16m terminal can be changed in the short term or in the mid / long term according to the 16m terminal penetration rate. Therefore, the 16m system needs a method of allocating each ranging structure and adjusting the load according to the number of 16e terminals and 16m terminals. That is, there is a need for a method for allowing a 16m terminal to effectively use the 16e ranging structure and the 16m ranging structure.

For efficient use of 16e ranging resources and 16m ranging resources, a base station can adjust the number and / or period of ranging slots. 16e and 16m ranging slots, respectively. Since the information on the ranging slot is a signal that has already been broadcasted, the information about the ranging slot broadcasted by the base station can be partially modified, so that the load can be easily adjusted without further consideration. However, this method is limited by the period of broadcasting information, and accurate ranging performance of each terminal must be guaranteed at a boundary point where information of a ranging slot changes. Particularly, in the case of the initial ranging, changing the position of the ranging slot in a state where the uplink synchronization does not match may cause confusion.

Therefore, it is possible to consider the position of the fixed ranging slot for a certain period of time and to consider the load control method therein. Such an example is shown in Figs. 25-29. In the figure, each box represents a ranging slot.

25 illustrates a method for adjusting the load of 16e and 16m ranging slots. Referring to FIG. 25, the 16e terminal can perform ranging only through the 16e ranging slot. On the other hand, a 16m terminal can select a 16e ranging slot and a 16m ranging slot by probability values. That is, the 16m terminal determines whether 16e ranging or 16m ranging is used with probability of P _A or P _B. Each probability value has a value between 0 and 1.

FIG. 26 illustrates a load adjustment method when there are a plurality of 16e and 16m ranging slots. Referring to FIG. 26, the 16m terminal first determines whether 16e ranging or 16m ranging is used with probability of P _A or P _B. Thereafter, the 16m terminal can again select which slot to use within the selected ranging. The slots in the 16e ranging are determined by probabilities P _A1 to P _A4 and the slots in the 16m range are determined by the probabilities of P _B1 to P _B4 . Each probability value has a value between 0 and 1.

FIG. 27 illustrates another method of adjusting the load when there are a plurality of ranging slots. When the method illustrated in FIG. 26 is applied, since the 16e ranging slot is used simultaneously by the 16e terminal and the 16m terminal, the BS can not distinguish the terminal performing the ranging. For this reason, when a base station allocates uplink resources to a corresponding terminal as a response to ranging, there is a restriction that a 16m terminal is unconditionally allocated to a legacy region irrespective of the terminal type. Therefore, it is preferable that the base station can determine whether the terminal attempting ranging is a legacy 16e terminal or a 16m terminal. The terminal type can be identified by separating the ranging code according to the terminal type.

Referring to FIG. 27, a 16e terminal attempts ranging using a 16e ranging slot and a 16e code set. On the other hand, a 16m terminal uses a 16m code set 1 when using a 16e ranging slot and a 16m code set 2 when using a 16m ranging slot. Here, the 16m code sets 1 and 2 may be the same or different from each other. Also, any one code set may include a different code set. However, since the 16e code set and the 16m code set 1 are allocated to the same radio resource, mutual-correlation characteristics should be good between the two code sets. When detecting the 16e ranging, the base station determines which code set the detected code belongs to, thereby knowing whether the terminal attempting ranging is a legacy 16e terminal or a 16m terminal. Information about a terminal attempting ranging can be used for the next resource allocation, thereby enabling efficient system operation.

In the method illustrated in Figs. 25-27, each probability value may be broadcast via system information. In this case, not all probability values need to be broadcast. For example, the base station may broadcast only P _A , and the terminal may obtain P _B from 1-P _A. In addition, the terminal may have a predetermined probability value. In this case, it is not necessary to broadcast or predefine all probability values.

Embodiment 2-1: Terminal information ( Mobile Information )

A method in which the terminal itself determines what ranging structure to use according to the capability / state information of the terminal can be used. In this case, the base station can directly know the state / information of the terminal through the type of the ranging structure that the terminal attempts. The terminal capability / status information includes information on whether or not the H-FDD (Half Duplex Frequency Division Duplex) or the F-FDD (Half Duplex Frequency Division Duplex) is supported, whether it is an emergency or an LBS . It is also possible to apply different probability values according to the capability / status information of the terminal.

FIG. 28 shows an example of selecting a 16e or 16m ranging slot according to whether the terminal supports the H-FDD or the F-FDD. 16m terminals supporting only H-FDD use 16e ranging slots and 16m terminals supporting F-FDD use 16m ranging slots. The base station can only serve F-FDDs for terminals that have accessed using a 16m ranging slot.

FIG. 29 shows an example in which a 16e or 16m ranging slot is selected according to whether the terminal is in an emergency state or an LBS service is required. A general 16m terminal can select a 16e or 16m ranging structure with probability of P _A1 or P _A2 . Similarly, a 16m terminal that is in an emergency or needs an LBS service may select a 16e or 16m ranging structure with a probability of P _B1 or P _B2 . In this case, P _A1 and P _A2 can be freely set in consideration of the ranging load. However, P _B1 is preferably set lower than P _B2 . Considering that the 16m ranging structure has better detection and delay time estimation capability than the 16e ranging structure, it is desirable that a 16m terminal in an emergency or requiring an LBS service tries to perform ranging using a 16m ranging structure Because.

The probability values of P _A and P _B may be broadcast by the base station or may be known values of the 16m terminal. Also, it is also possible that only one value such as P _A is broadcast in the base station, and the P _B value is determined by a predetermined rule of each terminal. For example, it is possible to set P _B1 = P _A2 - offset and P _B2 = P _A1 + offset. In addition, by setting P _A1 = 1, typical 16e and 16m terminals use the 16e ranging structure, and only 16m terminals that need an emergency or LBS service can use the 16m ranging structure. When the above mode is fixedly used, it is preferable that the base station use a value that the 16m terminal knows beforehand rather than a probability value.

Embodiment 2-3: A case in which different bandwidths are used Multiplexing

30 shows a case where 16e and 16m systems use different system bandwidths. In general, the time estimating capability is proportional to the reciprocal of the frequency band occupied by the sequence. Therefore, when the ranging structure occupies a wide band through subcarrier allocation distributed in the frequency domain, the time estimating ability is superior in a system having a larger bandwidth. Therefore, as illustrated in FIG. 29, it is desirable that a 16m terminal that is in an emergency state or requires an LBS service uses a 16m ranging structure with a high probability. Specifically, a general 16m terminal can select a 16e or 16m ranging structure with probability of P _A1 or P _A2 . Similarly, a 16m terminal that is in an emergency or needs an LBS service may select a 16e or 16m ranging structure with a probability of P _B1 or P _B2 . In this case, P _A1 and P _A2 can be freely set in consideration of the ranging load. On the other hand, P _B1 is set lower than P _B2 . For example, it is possible to set P _B1 = P _A2 - offset and P _B2 = P _A1 + offset. In addition, by setting P _A1 = 1, typical 16e and 16m terminals use the 16e ranging structure, and only 16m terminals that need an emergency or LBS service can use the 16m ranging structure. When the above mode is fixedly used, it is preferable that the base station use a value that the 16m terminal knows beforehand rather than a probability value.

Embodiment 2-4: Multi-carrier Multiplexing

31 illustrates a 16e and 16m ranging structure in the case of using a multi-carrier. Referring to FIG. 31, there is one or two legacy carriers. Each legacy carrier exists differently. Each legacy carrier can attempt ranging independently using each ranging code. Therefore, the 16e ranging code can use only a PN code of 144 length regardless of the multi-carrier. On the other hand, a 16m ranging can use a long code over the entire frequency band. By making the length of the 16m ranging code longer, it is possible to improve the delay time estimation capability of the 16m ranging. The enhanced time estimating capability of the 16m ranging can be applied to the 16m terminal in emergency or LBS service. Specifically, a general 16m terminal can select a 16e or 16m ranging structure with probability of P _A1 or P _A2 . Similarly, a 16m terminal that is in an emergency or needs an LBS service may select a 16e or 16m ranging structure with a probability of P _B1 or P _B2 . In this case, P _A1 and P _A2 can be freely set in consideration of the ranging load. On the other hand, P _B1 is set lower than P _B2 . For example, it is possible to set P _B1 = P _A2 - offset and P _B2 = P _A1 + offset. In addition, by setting P _A1 = 1, typical 16e and 16m terminals use the 16e ranging structure, and only 16m terminals that need an emergency or LBS service can use the 16m ranging structure. When the above mode is fixedly used, it is preferable that the base station use a value that the 16m terminal knows beforehand rather than a probability value.

32 shows an example in which the legacy 16e system and the 16m system have different frequency bands. Referring to FIG. 32, there are two legacy areas, each of which includes a 16e ranging structure. On the other hand, the 16m ranging structure has a frequency band twice that of the legacy 16e ranging structure. Since the frequency band of the 16m ranging structure is larger than that of the 16e ranging structure, the time estimation capability of the 16m ranging can be more excellent. The enhanced time estimating capability of the 16m ranging can be applied to the 16m terminal in emergency or LBS service. Specifically, a general 16m terminal can select a 16e or 16m ranging structure with probability of P _A1 or P _A2 . Similarly, a 16m terminal that is in an emergency or needs an LBS service may select a 16e or 16m ranging structure with a probability of P _B1 or P _B2 . In this case, P _A1 and P _A2 can be freely set in consideration of the ranging load. On the other hand, P _B1 is set lower than P _B2 . For example, it is possible to set P _B1 = P _A2 - offset and P _B2 = P _A1 + offset. In addition, by setting P _A1 = 1, typical 16e and 16m terminals use the 16e ranging structure, and only 16m terminals that need an emergency or LBS service can use the 16m ranging structure. When the above mode is fixedly used, it is preferable that the base station use a value that the 16m terminal knows beforehand rather than a probability value.

re-send ( Retransmission  ( re - trial ))

It can be assumed that the 16m ranging structure has better detection and delay time estimation capability than the 16e ranging structure. In addition, when the ranging fails, it can be assumed that the channel status of the ranging slot attempted by the terminal is not good or that many terminals are using it. When the UE fails in ranging, the ranging success rate can be increased by selecting a 16e or 16m ranging structure with a different probability from the previous one in the next retransmission (retry). For example, even if the terminal that failed initial ranging selects the 16e ranging structure in the first attempt, the 16m ranging structure can be selected at the time of retransmission.

As another example, it is also possible to change the probability value at each retransmission. For example, at the first transmission, a 16e ranging structure or a 16m ranging structure is selected using P _A and P _B. In this case, it is assumed that the specific terminal has failed in selecting the 16m ranging structure and attempting ranging. At the time of retransmission, the specific terminal can change the probability of selecting each ranging structure. For example, at the second transmission, the specific terminal can select a 16e ranging structure or a 16m ranging structure using P _A + P _C and P _B -P _C. P _C , a variation unit of probability, may be broadcast at the base station or may be known to the terminal in advance.

In the above description, the 16e ranging structure and the 16m ranging structure are separately described, but this is merely a convenience of explanation. For example, when there are a plurality of 16e ranging slots, it is possible to apply the embodiment according to the present invention independently for each slot. It is also possible to apply the embodiment according to the present invention independently for each slot when there are a plurality of 16m ranging slots.

The embodiments described above are those in which the elements and features of the present invention are combined in a predetermined form. Each component or feature shall be considered optional unless otherwise expressly stated. Each component or feature may be implemented in a form that is not combined with other components or features. It is also possible to construct embodiments of the present invention by combining some of the elements and / or features. The order of the operations described in the embodiments of the present invention may be changed. Some configurations or features of certain embodiments may be included in other embodiments, or may be replaced with corresponding configurations or features of other embodiments. It is clear that the claims that are not expressly cited in the claims may be combined to form an embodiment or be included in a new claim by an amendment after the application.

In this document, the embodiments of the present invention have been mainly described with reference to the data transmission / reception relationship between the terminal and the base station. The specific operation described herein as being performed by the base station may be performed by its upper node, in some cases. That is, it is apparent that various operations performed for communication with a terminal in a network composed of a plurality of network nodes including a base station can be performed by a network node other than the base station or the base station. A 'base station' may be replaced by terms such as a fixed station, a Node B, an eNode B (eNB), an access point, and the like. The term 'terminal' may be replaced with terms such as User Equipment (UE), Mobile Station (MS), and Mobile Subscriber Station (MSS).

Embodiments in accordance with the present invention may be implemented by various means, for example, hardware, firmware, software, or a combination thereof. In the case of hardware implementation, an embodiment of the present invention may include one or more application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs) field programmable gate arrays, processors, controllers, microcontrollers, microprocessors, and the like.

In the case of an implementation by firmware or software, an embodiment of the present invention may be implemented in the form of a module, a procedure, a function, or the like which performs the functions or operations described above. The software code can be stored in a memory unit and driven by the processor. The memory unit may be located inside or outside the processor, and may exchange data with the processor by various well-known means.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit of the invention. Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

The present invention can be applied to a method of performing communication in a wireless communication system. In particular, the present invention can be applied to a ranging scheme and a multiplexing scheme supporting a legacy support mode in a wireless communication system. More specifically, the present invention can be applied to a ranging structure and a multiplexing technique when IEEE 802.16e ranging structure and IEEE 802.16m ranging structure are used together.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

FIG. 1 is a diagram illustrating an example of multiplexing resources of the IEEE 802.16e system 16e and the IEEE 802.16m system 16m in terms of TDM (Time Division Multiplexing) and FDM (Frequency Division Multiplexing).

2 and 3 illustrate an OFDMA (Orthogonal Frequency Division Multiple Access) symbol structure for ranging.

4 shows a PRBS (Pseudo Random Binary Sequence) generator for generating a ranging code.

FIG. 5 shows a ranging structure in a wireless MAN-OFDMA (Metropolitan Area Network-Orthogonal Frequency Division Multiple Access) reference system.

6 shows an example of performing 16e and 16m ranging in the legacy support mode according to the embodiment of the present invention.

7-8 show an example of allocating codes for 16m ranging according to an embodiment of the present invention.

9 shows correlation characteristics of the range codes used in 16e.

10-13 illustrate a method of generating a 16m ranging code with different seed values according to an embodiment of the present invention and correlation characteristics of codes generated thereby.

14-23 illustrate a method of generating a 16m ranging code by varying the phase of a code according to an embodiment of the present invention and correlation characteristics of codes generated by the method.

FIG. 24 shows a method of generating a 16m ranging code using a code generation formula according to an embodiment of the present invention and correlation characteristics of codes generated by the method.

25-29 illustrate an example of performing load regulation according to an embodiment of the present invention.

30-32 show examples of multiplexing 16e and 16m ranging according to an embodiment of the present invention when legacy 16e and 16m use different frequency bands.

Claims (15)

A method for performing ranging in a wireless communication system, Selecting a specific ranging structure based on a probability value from a first ranging structure supporting a 16e system and a second ranging structure supporting a 16m system; And And transmitting the ranging signal through the specific ranging structure, The code resource for the first ranging structure is generated using a first PN (pseudorandom noise) code generation formula 1 + X ¹ + X ⁴ + X ⁷ + X ¹⁵ , Code resources for the second ranging structure is generated using a second PN code generation equation ^{1 + X 8 + X 11 +} X 14 + X 15, In the standard communication situation, the probability value of the first ranging structure is given as P _A1 (0 <P _A1 <1) and the probability value of the second ranging structure is given as P _A2 (P _A1 + P _A2 = 1) In addition, In the emergency communication situation, the probability value of the first ranging structure is given as P _B1 (0 <P _B1 <1), and the probability value of the second ranging structure is given as P _B2 (P _B1 + P _B2 = 1) In addition, P _B1 is set to be lower than P _B2 , Wherein P _B1 is set to P _A2 - offset (offset is a positive integer) and P _B2 is set to P _A1 + offset. The method according to claim 1, Wherein the specific ranging structure is selected arbitrarily or based on a predetermined criterion. 3. The method of claim 2, Wherein the predetermined criteria comprises a probability value, a capability of the terminal, a state of the terminal, or any combination thereof. A terminal for performing ranging in a wireless communication system, RF module; And A processor for controlling the RF module, The processor selects a specific ranging structure based on a probability value from a first ranging structure supporting the 16e system and a second ranging structure supporting the 16m system and outputs a ranging signal through the specific ranging structure However, The code resource for the first ranging structure is generated using a first PN (pseudorandom noise) code generation formula 1 + X ¹ + X ⁴ + X ⁷ + X ¹⁵ , Code resources for the second ranging structure is generated using a second PN code generation equation ^{1 + X 8 + X 11 +} X 14 + X 15, In the standard communication situation, the probability value of the first ranging structure is given as P _A1 (0 <P _A1 <1) and the probability value of the second ranging structure is given as P _A2 (P _A1 + P _A2 = 1) In addition, In the emergency communication situation, the probability value of the first ranging structure is given as P _B1 (0 <P _B1 <1), and the probability value of the second ranging structure is given as P _B2 (P _B1 + P _B2 = 1) In addition, P _B1 is set to be lower than P _B2 , Wherein P _B1 is set to P _A2 - offset (offset is a positive integer) and P _B2 is set to P _A1 + offset. 5. The method of claim 4, Wherein the specific ranging structure is selected arbitrarily or based on a predetermined criterion. 6. The method of claim 5, Wherein the predetermined criterion comprises a probability value, a capability of the terminal, a state of the terminal, or any combination thereof. delete delete delete delete delete delete delete delete delete

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