KR20000077063A - Apparatus and method for generating spreading code in cdma communication system - Google Patents

Abstract

PURPOSE: A spread code generating device is provided to generate a short spread code which has a period shorter than that of a sequence having a long period. CONSTITUTION: A spread code generating device comprises a plurality of registers(320-32s-1) which are reset by corresponding initial state values(0:s-1), respectively. Output values of the registers(320-32s-1) are input to logic sum operators(300-30s-1), respectively. Each of the logic sum operators(300-30s-1) logically sums an output of a corresponding register and a coefficient of a generator polynominal expression. Adders(311-31s-1) are connected between corresponding registers, respectively. A controller(360) generates a PN_ROLL_OVER signal and a mask selection signal. A selector(340) receives a mask1 signal and a mask2 signal to output a mask signal corresponding to the mask selection signal. A modulo-2 adder(350) adds output signals of the operators(330-33s-1) to output an added result as a short spread code.

Description

Apparatus and method for generating spreading code of code division multiple access communication system {APPARATUS AND METHOD FOR GENERATING SPREADING CODE IN CDMA COMMUNICATION SYSTEM}

The present invention relates to an apparatus and method for generating a spreading code in a code division multiple access communication system, and more particularly, to an apparatus and method for generating a spreading code for spread spectrum.

Since the spread spectrum of the conventional IS-95 CDMA technology must be 1.2288 * 10 ⁶ chip rate (chip rate, cps; chip per sec), a short PN code is generated at a rate of 1.2288 * 10 ⁶ chip. In addition, since the short spreading code should be generated during one frame (80msec / 3 = about 26.67msec) section of a sync channel, one period of the short spreading code is 2 ¹⁵ chip size.

1 shows a configuration of a conventional apparatus for generating a spreading code.

A conventional spreading code generator 15 of the shift registers (shift register) R1-R15 are 2 ¹⁵ -1 length of the ML sequence (M-sequence, Maximal-length sequence consisting of a series connection as shown in FIG. 1: hereinafter M The sequence is used in the same sense) A short spread code can be obtained by using a generator. However, one '0' is inserted after 14 '0' sequences generated every cycle (2 ¹⁵ -1) and used as a short diffusion code of length 2 ¹⁵ . The generator polynomial of the ML sequence generator is a feature for classifying codes and an element for determining partial correlation features of codes. In the case of the IS-95 standard, two different ML sequences are adopted and used as the standard specifications by dividing the two phase channels (Polynomial) into two different phase channels (In-phase & Quadrature-phase channels).

A short spread code having a predetermined interval Δ delay effect for the generated short spread code can be obtained by selectively modulo-2 adding the shift register value of the generated polynomial. That is, in FIG. 1, the modulo-2 adders 101-115 respectively input the outputs of the corresponding shift registers R1-R14 and the outputs of the logical product gates 122-135, respectively, and input two input signals to the modulo-2. Add to the next shift register. A mask (mask: Short_PN_Code_Mask [0:14] of FIG. 1) was used to select a value of the shift register to be modulo-2 added. In other words, different mask values may be applied to generate short spread codes having different phase differences.

Cdma2000, the leading North American standard for IMT-2000, supports wideband CDMA systems with spread spectrum greater than 1.2288 * 10 ⁶ . In this case, the short spread code used is only 2 ¹⁵ * N (N is a multiple of 3) in the ML sequence of 2 ^S -1 (S is an integer) rather than the existing ML sequence of 2 ¹⁵ -1 length. It is suggested as a standard to take and use. And the short spreading code length required for each of these chip rates may vary as shown in Table 1 below.

N Spread Spectrum (Chip Rate) = 1.2288 * 10 ⁶ × N Short spreading code length (P) for 1 frame of sync channel = 2 ¹⁵ chip × N Relevant longest sequence: r (M-sequence length: 2 ^r -1) One 1.2288 × 10 ⁶ 2 ¹⁵ chip 15 (2 ¹⁵ -1) 3 1.2288 × 10 ⁶ × 3 2 ¹⁵ × 3 chip 17 (2 ¹⁷ -1) 6 1.2288 × 10 ⁶ × 6 2 ¹⁵ × 6 chip 18 (2 ¹⁸ -1) 9 1.2288 × 10 ⁶ × 9 2 ¹⁵ × 9 chip 19 (2 ¹⁹ -1) 12 1.2288 × 10 ⁶ × 12 2 ¹⁵ × 12 chip 19 (2 ¹⁹ -1)

In addition, even if a phase delay for distinguishing each base station is applied to the short spread code thus generated, only this partially selected sequence should appear. However, the conventional method of making a short delay code with a phase delay by simply covering one mask has a problem of generating a sequence outside the selected ML sequence region.

The above problem will be described with reference to FIG. 2. FIG. 2 shows an example of obtaining a short spread code having a length of 2 ¹⁵ * 3 (= p) from an ML sequence having a length of 2 ¹⁷ -1 (= m) as shown in (b). FIG extends the spreading code generation method with a 2 ¹⁵ -1 length, such as 1, taking only the first 3/4 portion from 2 ¹⁷ -1 length of the ML sequence for the length of the shift register 17 pieces you want to create a short spreading code assumes lets do it. As shown in FIG. 2 (b), when one value of one cycle of the binary ML sequence is taken as C0, it is assumed that one short spreading code is made by taking only the sequence value of 'p' length from here. The remaining 'm-p' sequences of the 'm' ML sequence values correspond to unused regions. This easy method to take only a portion of the entire ML sequence is to monitor the current state (State (D) of FIG. 2) of the shift register generating the ML sequence or to monitor the sequence output. As shown in (d) of FIG. 2, the initial state as shown in FIG. 2C immediately after the shift register state becomes' Sp-1 'or immediately after the'p-1'-th sequence is issued. It generates an initial state signal and returns the shift register to the initial state so that the first sequence C0 can be generated.

In order to apply a constant phase delay 'r' to the short diffusion code generated as described above (e) of FIG. 1, a phenomenon occurs when only one mask value, Mask_r, corresponding to 'r' is covered as shown in FIG. 1. see. In this case, as shown in (f) of FIG. 2, the phase delay value 'r' is applied to the ML sequence value of the 'A region' corresponding to the 'r-1' th from the '0' th sequence value. 'M-r' through 'm-1' th sequence values of the original full 'm' length ML sequence are generated, and '0' from the 'r' th 'p-1' ML sequences. ML sequence values from the first to 'pr-1' are generated. This is because, due to the inherent characteristics of the ML sequence, the delay value is determined by the current shift register state and the mask value. Since the period of the original ML sequence is 'm', the phase delay occurs based on this period. This result is contrary to the original intention to cyclically delay only the original ML sequence values from the '0' th sequence (C0) to the 'p-1' th (Cp-1). This results in the ML sequence values from the 'm-r' to the 'm-1'. That is, in order to achieve a desired cyclic phase delay as shown in (g) of FIG. 2, the phase is set to the ML sequence value corresponding to the '0' th sequence value (C0) to the 'r-1' th (Cr-1). The delay value 'r' is applied to generate the 'p-r' through 'p-1' th sequence values of the original ML sequence.

As described above, when a short spreading code is to be made using only one mask using a conventional spreading code generation method, an undesired output as in the case of 'area A' of FIG. 2 is obtained. The solution to the above problem is 'm' which is the length of the unused sequence of the original ML sequence instead of using 'Mask_r' which delays only 'r' in 'A region'. We need 'Mask_ (m-p + r)' which delays by -p.

Accordingly, an object of the present invention is to provide an apparatus and method for generating a short spreading code for spreading a band in a code division multiple access communication system.

Another object of the present invention is to provide an apparatus and method for generating a spreading code having a period smaller than this from a sequence having a long period in a code division multiple access communication system.

Another object of the present invention is a spreading code using at least two masks in consideration of the phase difference so that an unused sequence portion of the entire period of a sequence having a long period does not appear in a spreading code having a phase difference in a code division multiple access communication system The present invention provides an apparatus and method.

1 is a diagram showing the configuration of an apparatus for generating a spreading code for spreading a band in a conventional code division multiple access communication system;

2 is a diagram illustrating a generation process of a spreading code generated using one mask in a conventional code division multiple access communication system.

3 is a diagram illustrating a configuration of a spreading code generation device for spreading a bandwidth in a code division multiple access communication system according to an embodiment of the present invention.

4 is a diagram illustrating a timing relationship for generating a spreading code in the spreading code generating apparatus as shown in FIG. 3.

FIG. 5 is a diagram illustrating a process of generating a mask selection signal and a reload signal of an M sequence in the spreading code generating apparatus of FIG. 3.

DETAILED DESCRIPTION A detailed description of preferred embodiments of the present invention will now be described with reference to the accompanying drawings.

In the following description, specific details such as chip rate for generating short spreading codes, number of short spreading codes, and the like are shown to provide a more general understanding of the present invention. It will be apparent to those skilled in the art that the present invention may be readily practiced without these specific details and by modifications thereof.

The CDMA communication system assigns different phase delay values of short spread PN codes to distinguish base stations and to multi-path when a multi-path delay, a general channel characteristic of a mobile communication channel, occurs. Uncorrelated the interference between the two. The short spread PN code (hereinafter, referred to as short spreading code) uses codes having the same phase delay value for all terminals connected to one base station. If the base station to which the terminal is connected is changed by handoff, Code using a phase delay value should be used. In particular, when a soft handoff is in progress, one terminal may assign two or more different phase delay values to each demodulator of the multipath demodulator. In this case, in order to generate a short spreading code having a desired phase delay value, a mask suitable for a desired phase delay value is generally used in a short spreading code generator having a phase delay value of '0'.

On the other hand, in a CDMA system such as IS-95, IS-95A, or cdma2000 (IS-2000), a short spreading code has one '0' in an ML sequence having a maximum length of 32767 at a chip rate of 1.2288 MHz. An additional 32768 cycles of binary code are used, the length of which corresponds to one frame (80 msec / 3) of the Sync Channel. However, in the third generation CDMA system, IS-2000 or UMTS CDMA system, the standard is set to have a wider spreading frequency band than that of IS-95. For example, 1.2288x3 = 3.6864MHz, which is three times the spreading frequency of IS-95. In the 3xcdma2000 (IS-2000) system with the bandwidth of, the frequency of 32768 * 3, which is three times longer than the conventional 32768 IS-95 short spreading code, is used to keep the frame length of the sync channel the same (80 msec / 3). This requires a short spread code with a length. That is, in a system supporting wideband communication having a wider spreading bandwidth than a conventional CDMA communication system, a period of a short spreading code required according to an application band is changed. However, if the ML sequence is used with a short spreading code as in the conventional IS-95, the theoretical nature of the ML sequence indicates that the full period is 2 ^S -1 (S is an integer). convenience of a single full-wave (full period) of the ML sequence in the case of adding a single zero is made of 2 ^S) is therefore created, it requires a short spreading code is 2 ¹⁵ * N (N is a multiple of 3 is) for A situation arises in which a short spread code cannot be used and only a partial period of an ML sequence of 2 ^N * N (even greater than N = 2) can be used.

However, when the short spreading code consists of only a part of the full period of the ML sequence, as mentioned earlier, when a short spreading code having a constant phase delay value is used, a mask is simply applied as in the conventional method. When overwritten, the generated code invades the region of the unwanted portion rather than the desired region of the ML sequence to generate a code value. Accordingly, in the embodiment of the present invention, when the desired length of the short spreading code is to select a partial period which is part of the theoretical full period of the ML sequence, a short spreading code having a desired phase delay value is selected. Suggest how to generate. In the embodiment of the present invention, for convenience of explanation, examples of IS-95 and IS-2000 are given, but the present invention is applicable to all cases in which the short spreading code consists of only a partial period of the ML sequence.

3 is a diagram illustrating a structure of a spreading code generator having a 32768 * N (N = 3,6,9,12, etc.) chip period according to an embodiment of the present invention.

Referring to FIG. 3, the registers 320 to 32s-1 have a structure of a shift register. The registers 320 to 32s-1 are initialized by an initial state value (initial state [0: s-1]). In addition, the Rr-1 value of the register 32s-1 is input to the logical AND operator 300-30s-1. The AND operator 300 to 30s-1 performs an AND operation on the coefficients a0 to as-1 of the generated polynomial corresponding to the output of the register 32s-1. Adders 311 to 31s-1 are connected between the corresponding registers and registers, respectively, and modulo-2 adds the outputs of the corresponding logical product operators 301 to 30s-1 and the previous register output to the registers of the next stage. Save it.

The controller 360 generates a PN_ROLL_OVER signal or the like for controlling the 32768 * N period and generates a mask selection signal for selecting the corresponding mask. The selector 340 inputs mask 1 (mask1 [0: s-1]) and mask2 (mask2 [0: r-1]) and receives a mask signal corresponding to the mask selection signal output from the controller 360. Select and print. The logical product operators 330 to 33s-1 for inputting the outputs R0 to Rr-1 of the registers 320 to 32s-1 and the mask signal selected by the selector 340 output the logical AND operations of the two inputs. The modulo-2 adder 350 modulo-2 adds the outputs of the AND products 330 to 33s-1 and outputs them with a short spreading code.

Referring to FIG. 3, the structure of a spreading code generator according to an embodiment of the present invention first cuts only a desired length from a 2 ^S -1 length (s: shift register number) spreading code generated by an ML sequence generator to repeatedly generate it. In order to generate the PN code generator, an ML sequence generator 370 for generating an ML sequence capable of reloading initial shift registers R0 to Rs-1 according to the generation polynomial of the ML sequence, and the entire ML sequence generated. The controller 360 controls to select only the desired spread spectrum length from the spreading code.

In order to generate a spreading code having a predetermined phase difference with respect to the selected spreading code, a value of each shift register may be selectively selected according to a mask value to generate a delayed spreading code having a predetermined phase difference with respect to the original spreading code. A modulo-2 adder 350 for modulo-2 addition and a selector 240 for selecting one of two mask values to generate the spreading code.

Figure 4 illustrates the timing of generating a short spread code of 2 ¹⁵ * 3 chip cycles in accordance with an embodiment of the present invention.

In the embodiment of the present invention, an operation principle of the present invention will be described by taking an example of generating a short spread code having a 2 ¹⁵ x 3 chip period p when the spread band is 1.2288 x 10 ⁶ x 3 chip rate.

3 and 4, an ML sequence generator having at least 2 ¹⁷ −1 periods may be used to generate a short spreading code having 2 ¹⁵ × 3 chips periods (p). The polynomial of the generation of the ML sequence generator is generally expressed as follows.

In Equation 1, the coefficients an, n = 0, 1,... , 16 is a coefficient of the polynomial and has a value of 0 or 1. This may be configured using a 17-stage shift register 320-32s-1 and a modulo-2 adder 310-31s-2 as in the ML sequence generator 370 of FIG. 3. The initial values (0 to s-1) of the 17-stage register of the ML sequence generator 370 should be reloadable. This is because the 2 ¹⁵ x 3 chip period spreading code can be generated by continuously reloading the initial value of the 17-stage register of the ML sequence generator 370 every 2 ¹⁵ x 3 chips.

As described above, the spreading code generator needs a control signal (Short PN code Initial State load enable signal) generating unit for reloading the initial value of the 17-stage register of the ML sequence generator 270 every 2 ¹⁵ x 3 chip cycles. The control signal is generated at the controller 360. The controller 360 may generate the control signal by using a counter having a period of 2 ¹⁵ x 3 (p) or having a device for comparing and determining the values of the shift registers R0 to Rs-1. The method of using a value of the shift register R0 ~ Rs-1 is re-state value value (State of the Shift Register) of the shift register S _p-1 when the initial state S ₀ (Initial State S ₀₎ in FIG. 4 In order to load, a control signal (Short PN code Initial State load enable signal) may be generated. As described above, a short spread code of 2 ¹⁵ x 3 (= p) cycles may be generated from the ML sequence generator 270 having 2 ¹⁷ −1 (= m) cycles.

For a short spread code obtained in the above manner, a short spread code having a constant phase difference can be generated by selectively modulating the state values of the shift registers by modulo-2, which is performed by 380 of FIG. . The selection of the shift register value to which the modulo-2 is added is determined according to the mask value, and different mask values are required according to the desired phase difference.

In the embodiment of the present invention, the short spreading code of 2 ¹⁵ x 3 periods is obtained by truncating an M-sequence of 2 ¹⁷ -1 periods. In this case, when generating a short spreading code having a phase difference using the mask, a code of an unused region among the generated codes should be considered. In consideration of this, at least two types of mask sets are provided in an embodiment of the present invention. In the embodiment of the present invention, it is assumed that mask1 and mask2 are used. That is, in the exemplary embodiment of the present invention, two masks are provided, and the first mask is applied to the M sequence of the first section, and the second mask is applied to the M sequence of the second section. To generate one short spreading code.

The mask operation is performed by the selector 340, which is controlled by the controller 360. At this time, the controller 360 maintains a specific mask selection before the length of the generated spreading code becomes the desired phase difference value r of the generated spreading code, and when the phase difference value r is exceeded (that is, the spreading code having the desired length Generates a mask selection signal for selecting another mask.

Referring to the mask selection process as described above in detail, when the original non-truncated ML sequence as shown in 413 of Figure 4 as 'Mo', the diffusion code 'M' as shown in 419 of FIG. As described above, a sequence 'Mo' like 413 is truncated at p = 2 ¹⁵ x3 length. At this time, 'Mr' as shown in 421 of FIG. 4 having a phase difference from 'M' to 'r' is a mask required to 'r' phase delay the shift register output values of the generator of code 'M' as shown in 419. (Mask: in the embodiment of the present invention, it is assumed that 'mask1'). One problem is that if the code value of 'M' is used during the [C0: Cr-1], the code value of [Cp: Cm] is the unused code values of the original 'Mo' code. The code within the range will be generated. Therefore, in order to solve the problem of unwanted code generation as described above, an embodiment of the present invention creates a phase difference of 'r + m -p' rather than 'r' during this range ([C0: Cr-1]). use 'mask2'.

FIG. 5 is a flowchart illustrating a process in which the controller 360 generates a mask selection signal and generates a reload signal of an initial state of the ML sequence in FIG. 3.

Referring to FIG. 5, the counter CNT is a state of an ML sequence and an index of an output value, and assumes an arbitrary state desired by a user as a '0'-th state. Therefore, in step 511, the controller 360 initializes the counter state to 0, and then increments the counter value by 1 in step 513 whenever a clock is generated. In step 515, the counter value is compared with the phase delay value 'r' after the count value is increased by one. If the counter CNT value is less than the phase delay value 'r' in the comparison process, the process proceeds to step 517 and the signal MASK_SELECTION for selecting 'mask2' is turned 'ON'; otherwise, the mask selection (MASK_SELECTION) is turned off in step 521. Select 'mask1'. Then, the selector 340 selects and outputs the corresponding mask1 or mask2 according to the mask selection signal of the controller 360. In this case, the mask selection signal applied to the selector 340 is equal to 425, and thus the mask output from the selector 340 is equal to 423. The mask output from the selector 340 is applied to the AND gates 330-33r-1.

If mask 1 is selected in step 521, the controller 360 checks whether the value of the counter CNT matches the desired length of short diffusion code 'p-1' (step 523). If the value of the counter CNT is not the length of the desired spreading code, the process returns to step 513 and repeats the above operation. However, if the value of the counter CNT coincides with the desired short spreading code length in step 523, an initial state reload signal is generated and applied to the M sequence generator 270 in step 525. The M sequence generator 370 then loads the initial state value [0: s-1] and returns to the initial state of the ML sequence.

Spreading code according to an embodiment of the present invention as described above, the synchronization channel generating apparatus 1 to generate a spreading code having a length of a short spreading code for the frame, in the ^S 2 -1 length spreading code generated by the ML sequence generator Calculating the ML sequence of the desired length section and the first mask to generate a short spread code having a desired length, and calculating and truncating the ML sequence of the unwanted length section and a second mask having a predetermined phase difference with the first mask Use Therefore, a short spreading code is generated by repeating the above process. At this time, a part in the ML sequence should be selected in consideration of the balance of the partial correlation result of the spreading code and the distribution of the binary values. In addition, there is an advantage in that a spreading code having a predetermined phase difference may be generated due to an effect of delaying the spreading code at a predetermined interval with respect to the spreading code selected only as much as necessary in the ML sequence.

Claims (3)

A spreading code generation device for a code division multiple access communication system, ML sequence generation having a 2 ^S -1 length and an ML sequence generated according to a predetermined initial value, and reloading the initial value for every ML sequence of a desired length having a length smaller than the 2 ^S -1 length. An ML sequence generator that repeats the generation operation of the ML sequence, A mask selector having at least two first and second masks having a predetermined phase difference, wherein the mask selector selects the first mask in the ML sequence section of the desired length and selectively outputs the second mask in a section other than the first mask; Spreading of the code division multiple access communication system comprising an adder for modulating the output of the ML sequence generator and the mask selector by modulo-2 to generate the spreading code, and an adder for truncating the received ML sequence when the second mask is input. Code generator. In from the ML sequence having a length of 2 ^S -1 to a code division multiple access communication system, the spreading code generating device for generating a spreading code having a length less than the length of 2 ^S -1, ML sequence generation having a length of 2 ^S -1 and the ML sequence generated according to a predetermined initial value, and reloading the initial value upon receiving a reload control signal, and repeatedly performing the generation operation of the ML sequence. Generator, A controller for analyzing the length of the generated ML sequence and generating the reload control signal and the mask selection signal when an ML sequence having a desired length is generated; A mask selector having at least two first and second masks having a predetermined phase difference, and selectively outputting a second mask when the mask selection signal is generated; Spreading of the code division multiple access communication system comprising an adder for modulating the output of the ML sequence generator and the mask selector by modulo-2 to generate the spreading code, and an adder for truncating the received ML sequence when the second mask is input. Code generator. 2 according to a spreading code generating method for a CDMA communication system for generating a spread code having a length less than the length from the 2 ^S -1 ^S -1 ML sequence having a length, 2 ^S -1, and having a length ML sequence generator polynomial and the generated ML sequence according to a predetermined initial value in the step of -2 to adding the generated ML sequence and a first mask to generate the spreading code module and, Analyzing the length of the generated ML sequence, reloading the initial value every time a ML sequence of a desired length is generated, and modulating the second mask having a predetermined phase difference with the first mask modulo-2 A spreading code generation method of a code division multiple access communication system comprising a process of truncating a sequence.