CN101860395A - Method and equipment for generating preamble sequence - Google Patents

Abstract

The invention discloses a method and equipment for generating a preamble sequence. The method comprises the following steps of: generating a frequency domain ZC sequence; determining a format and a time domain sampling point number of a target preamble sequence; performing inverse discrete Fourier transform of a corresponding preset small point number on the frequency domain ZC sequence according to the time domain sampling point number of the target preamble sequence to obtain a time domain sequence; performing interpolation on the time domain sequence, and converting the length of the time domain sequence into a length corresponding to the time domain sampling point number of the target preamble sequence; acquiring a phase rotation angle according to an initial position of the preset frequency domain resource; multiplying the time domain sequence with the converted length and the phase rotation angle, and performing phase conversion; performing corresponding subsequent processing on the time domain sequence with the converted phase according to the format of the target preamble sequence; and adding a cyclic prefix to the subsequent processed time domain sequence. The preamble sequence generating method disclosed by the embodiment of the invention avoids the occurrence of Fourier transform of a large point number so as to improve the operation speed, reduce the calculation quantity, improve the generating speed and reduce the power consumption and the circuit area at the same time.

Description

A kind of generation method and apparatus of preamble sequence

Technical field

The present invention relates to wireless communication field, relate in particular to a kind of generation method and apparatus of preamble sequence.

Background technology

LTE (Long Term Evolution, Long Term Evolution) system is thought accurate 4G wireless communication system widely, it has the transmission rate of the up 50M of descending 100M, support higher translational speed (350km/h) and bigger coverage radius of cell (100 kilometers) simultaneously, support that 200 users in every sub-district are simultaneously online.In addition, LTE also has band width configuration (1.4M～20M), support multi-media broadcasting service and end-to-end QoS characteristics such as (Quality of Service, service quality) flexibly.Therefore LTE also is considered to following aroused in interest developing direction and the candidate's standard of 4G technology of moving.

Before normal subscriber data traffic, UE (User Experience, user experience) at first will carry out random access procedure, so that be used for adjusting up (Uplink) transmitting time, distributes Radio Network Temporary Identifier (RNTI), at random access interference solution etc.In the up link of LTE, Random Access Channel PRACH is used for initiating user's the request of access at random, and the wherein general signaling procedure that inserts at random as shown in Figure 1.Random access procedure was divided into for four steps, and the first step is that UE sends random access guiding preamble sequence, and second one is that eNodeB sends accidental access response, wherein contains the line time adjustment information, and then UE adjusts up transmitting time according to this adjustment information.The 3rd step and the 4th step are Radio Resource control (Radio Resource Control) protocol signalings.Wherein the first step comprises the generative process of the generative process frequency domain ZC sequence of the Preamble sequence that the present invention relates to.UE will generate according to upper strata sequence of indication selection and according to certain step in 64 predefined Preamble sequences.

Being created in the whole random access procedure of Preamble is in consequence, and Preamble is by the Zadoff-Chu sequence promptly, the ZC sequence, and through cyclic shift, time-frequency conversion, the physical resource mapping generates.It is formula 1 that the time domain of ZC sequence generates formula:

$x_u\left(n\right)=e^{-j\frac{\mathrm{\πun}(n+1)}{N_{\mathrm{ZC}}}},0\≤n\≤N_{\mathrm{ZC}}-1---\left(1\right)$

N wherein _ZCBe sequence length, as shown in Figure 1, be divided into four kinds of forms.U is the generation root of ZC sequence, and for form 0～3, its value is 0～837, and is 0～137 for its value of format 4.

The time domain of a Preamble sequence constitutes as shown in Figure 2, and wherein 21 is CP (Cyclic Prefix, Cyclic Prefix), and 22 is the time domain sequences of Preamble, T _CPBe the length of Cyclic Prefix, T _SEQLength for time domain sequences.Preamble is divided into four kinds of forms according to the length difference, as shown in Figure 3, and T wherein _sBe LTE system time sampling sampling point interval, length is T _s=1/ (15000 * 2048) second.

The generative process of the Preamble sequence of stipulating among the agreement 3GPP TS36.211 is as shown in Equation 2:

X wherein _{U, v}(n) be the ZC sequence of time domain, u is a root, and v is a cyclic shift amount index, and actual cyclic shift number of samples is C _v0≤t＜T _SEQ+ T _CP,

Be the number of Resource Block of LTE (Resource Block) sub-carriers,

Be the number of eNodeB for the ascending resource piece of this user's distribution,

Be the original position of eNodeB for the Preamble sequence frequency domain resource of this user's distribution, this position is unit with the Resource Block.β _PRACHFor the factor is adjusted in power control.K=Δ f/ Δ f _RA, wherein Δ f is data subcarrier (meta 15kHz of LTE system or 7.5kHz) at interval, Δ f _RABe Preamble sequence subcarrier in frequency domain interval.

It is a fixing frequency domain side-play amount.Δ f _RAWith

Value as shown in Figure 4.

The Preamble generative process of stipulating in the LTE agreement can be decomposed into the realization unit in implementation procedure, its structure as shown in Figure 5, time domain sequences generation unit 51 generates the ZC sequence of time domain according to formula 1, cycle shift unit 52 is selected the side-play amount of a cyclic shift according to the indication on eNodeB and UE upper strata, ZC sequence to time domain is carried out cyclic shift, and its process can be represented by formula 3:

x _u，v(n)＝x _u((n+C _v)mod?N _ZC) (3)

Wherein, C _vBe by the cyclic shift amount that calculates.Finish the time domain generative process of ZC sequence this moment, and the length of this time domain sequences is 839 or 139, as shown in Figure 1.Carry out discrete Fourier transform through DFT unit 53 then, generate frequency domain ZC sequence, counting of this DFT operation is identical with the length of time domain ZC sequence, is 839 or 139.Frequency domain map unit 54 is finished the mapping of frequency domain resource.The shared bandwidth of Preamble sequence is 1.08M, and wherein the shared bandwidth of frequency domain sequence is 1.048M, and all the other are the protection interval.For fear of access interference, eNodeB is used for transmitting the Preamble sequence of this 1.08M for the user has distributed different frequency domain positions.Therefore UE needs this frequency domain sequence is moved on the frequency band of eNodeB appointment, and the original position of this frequency band is the k in the formula 2 ₀, frequency band length is 1.08M, frequency domain ZC sequence then is placed on the space of middle 1.048M of above allocated frequency band.IFFT unit 55 is transformed into time domain with the ZC of frequency domain.Counting of this IFFT operation counted for the time-domain sampling of this Preamble sequence correspondence, the time-domain sampling that Fig. 6 and Fig. 7 are respectively the Preamble sequence correspondence of format0 and the format4 schematic diagram of counting.For Preambleformat1, format2, format3 needs through repetitive 56, and format0 is carried out the repetition of corresponding number of times and obtains, and through adding CP unit 58, finishes the generation of the Preamble sequence of time domain then.

Can see by Fig. 6 and Fig. 7, counting of the maximum of IFFT reaches 24576 in the IFFT unit 55, and during the IFFT on ordinary meaning realizes, its operand will be huge and be difficult to realize, further, huge operand will inevitably cause the increase of high power consumption and circuit area.

Summary of the invention

In view of this, the invention provides a kind of generation method and apparatus of preamble sequence, with solve in the prior art amount of calculation big, be difficult to problem such as realization.Its scheme is specially:

A kind of generation method of preamble sequence comprises:

Generate frequency domain ZC sequence;

Determine the form and the time domain sampling number of target preamble sequence;

Count according to the time-domain sampling of described target preamble sequence described frequency domain ZC sequence is carried out accordingly default small point inverse discrete Fourier transform, obtain time domain sequences;

Time domain sequences is carried out interpolation, its length transition is returned and the described target preamble sequence time-domain sampling corresponding length of counting;

Original position according to preset frequency domain resource obtains phase rotation angle;

Time domain sequences after the length transition and described phase rotation angle are multiplied each other, carry out phase transition;

Carry out corresponding subsequent processing according to the form of the described target preamble sequence time domain sequences after to described phase transition;

Add the time domain sequences after Cyclic Prefix arrives described subsequent treatment, obtain target preamble sequence.

Preferably, when the time-domain sampling of described target preamble sequence is counted when being 1024, it is 1024 inverse discrete Fourier transform that described ZC sequence is carried out sampling number.

Preferably, when the time-domain sampling of described target preamble sequence is counted more than or equal to 2048 the time, it is 2048 inverse discrete Fourier transform that described ZC sequence is carried out sampling number.

Preferably, when the form of described target preamble sequence was format 0 or format 4, described subsequent treatment was do-nothing operation.

Preferably, when the form of described target preamble sequence was format1, format2 or format3, described subsequent treatment was for to carry out the repetitive operation of corresponding number of times to the time domain sequences after the described phase transition.

Preferably, generate frequency domain ZC sequence according to following process:

Generate time domain ZC sequence according to formula;

Calculate described time domain ZC sequence and;

From described ZC sequence, select the time domain sample value according to default frequency domain index value;

The time domain sample value of described selection is carried out conjugate operation;

Obtain described time domain ZC sequence and with described conjugate operation after the multiplied result of time domain sample value;

Generate phase rotation angle according to the cyclic shift amount that sets in advance;

Multiply each other with described time domain ZC sequence with the multiplied result and the described phase rotation angle of time domain sample value behind the described conjugate operation, obtain frequency domain ZC sequence.

A kind of generation equipment of preamble sequence comprises:

The frequency domain ZC sequence generation unit is used to generate frequency domain ZC sequence;

Determining unit is used for determining the form and the time domain sampling number of target preamble sequence;

The inverse discrete Fourier transform unit is used for counting according to the time-domain sampling of described target preamble sequence described frequency domain ZC sequence is carried out accordingly default small point inverse discrete Fourier transform, obtains time domain sequences;

Interpolating unit is carried out interpolation to time domain sequences, and its length transition is returned and the described target preamble sequence time-domain sampling corresponding length of counting;

The angle generation unit is used for obtaining phase rotation angle according to the original position of preset frequency domain resource;

First unit that multiplies each other is used for time domain sequences after the length transition and described phase rotation angle are multiplied each other, and carries out phase transition;

The subsequent treatment unit is used for form according to the described target preamble sequence time domain sequences after to described phase transition and carries out corresponding subsequent processing;

Add cyclic prefix unit, be used to add the time domain sequences after Cyclic Prefix arrives described subsequent treatment, obtain target preamble sequence.

Preferably, described frequency domain ZC sequence generation unit comprises:

Time domain ZC sequence generating unit is used for generating time domain ZC sequence according to formula;

Sum unit, be used to calculate described time domain ZC sequence and;

The sampling point selected cell is used for selecting the time domain sample value according to default frequency domain index value from described ZC sequence;

Conjugate unit is used for the time domain sample value of described selection is carried out conjugate operation;

First unit that multiplies each other, be used to obtain described time domain ZC sequence and with described conjugate operation after the multiplied result of time domain sample value;

The angle generation unit is used for generating phase rotation angle according to the cyclic shift amount that sets in advance;

Second unit that multiplies each other is used for described first the multiply each other result of unit and the result of described angle generation unit multiplied each other, and obtains frequency domain ZC sequence.

Preferably, described interpolating unit comprises: three times of up-sampling unit that order links to each other, first low pass filter, the first twice up-sampling unit, second low pass filter unit, the second twice up-sampling unit, the 3rd low pass filter unit.

From above-mentioned technical scheme as can be seen, the generation method of the disclosed preamble sequence of the embodiment of the invention is at the different time domain sampling number, preestablished dissimilar small point IFFT conversion, avoid the situation appearance of IFFT conversion of counting greatly, thereby improved arithmetic speed, then it has been carried out equivalent operation, the final generation is equivalent to the frequency domain resource mapping and the IFFT computing preamble sequence of counting greatly, and the dependence interpolation operation, according to different demands, adjust its accuracy.

By said method, reduced the amount of calculation in the preamble sequence generative process, improved formation speed, reduced power consumption and circuit area simultaneously.

Description of drawings

In order to be illustrated more clearly in the embodiment of the invention or technical scheme of the prior art, to do to introduce simply to the accompanying drawing of required use in embodiment or the description of the Prior Art below, apparently, accompanying drawing in describing below only is some embodiments of the present invention, for those of ordinary skills, under the prerequisite of not paying creative work, can also obtain other accompanying drawing according to these accompanying drawings.

Fig. 1 is a ZC Format Series Lines schematic diagram;

Fig. 2 is that the time domain of Preamble sequence constitutes schematic diagram;

Fig. 3 is a Preamble Format Series Lines schematic diagram;

Fig. 4 is Δ f _RAWith

The value schematic diagram;

Fig. 5 generates the device structure schematic diagram for Preamble;

Fig. 6 is the time-domain sampling of the Preamble format0 sequence correspondence schematic diagram of counting;

Fig. 7 is the time-domain sampling of the Preamble format4 sequence correspondence schematic diagram of counting;

Fig. 8 is the generation method flow diagram of embodiment 1 disclosed preamble sequence;

Fig. 9 is the generation method flow diagram of embodiment 2 disclosed preamble sequences;

Figure 10 is that embodiment 3 disclosed frequency domain ZC sequence generate method flow diagram;

Figure 11 is that preamble sequence disclosed by the invention generates the device structure schematic diagram;

Figure 12 is the structural representation of frequency domain ZC sequence generation unit disclosed by the invention;

Figure 13 is the structural representation of interpolating unit disclosed by the invention.

Embodiment

Below in conjunction with the accompanying drawing in the embodiment of the invention, the technical scheme in the embodiment of the invention is clearly and completely described, obviously, described embodiment only is the present invention's part embodiment, rather than whole embodiment.Based on the embodiment among the present invention, those of ordinary skills belong to the scope of protection of the invention not making the every other embodiment that is obtained under the creative work prerequisite.

The invention discloses a kind of generation method of preamble sequence, avoided the calculating process of the IFFT that counts greatly, solved the problem that operand in the prior art is big and be difficult to realize.Its embodiment is as described below:

Embodiment one

The flow process of the generation method of the disclosed preamble sequence of present embodiment comprises as shown in Figure 8:

Step S81, the described time domain ZC sequence of conversion are frequency domain ZC sequence;

According to formula 1, under the situation of given other parameters, obtain time domain ZC sequence in this step.The transfer process of present embodiment frequency domain ZC sequence is same as the prior art, at first time domain ZC sequence is carried out cyclic shift, then it is carried out the DFT conversion.

Step S82, the form of determining target preamble sequence and time domain sampling number;

Can see by Fig. 1, the preamble sequence of the corresponding different-format of the length of different ZC sequences, and for the preamble sequence of different-format, when system bandwidth not simultaneously, its time domain sampling number is also inequality, and promptly sequence length is also different, so subsequent operation also can be different.

Step S83, according to described target preamble sequence and the time domain sampling number described frequency domain ZC sequence is carried out accordingly default inverse discrete Fourier transform IFFT, obtain time domain sequences;

Preestablished sampling number among the present invention and be 1024 or 2048 two types small point inverse discrete Fourier transform, counted, chosen different small point IFFT conversion according to the time-domain sampling of different preamble sequences.

Suppose to be input as F _u(k), k=0,1 ..., N _ZC-1, the both sides zero padding is to N _IfftPoint is output as H _u(i), i=0,1 ..., N _Ifft-1, wherein, for Preamble format4, it is 1024 target preamble sequence that time-domain sampling is counted, N _Ifft=1024, and for other sampling numbers more than or equal to 2048 situation, N _Ifft=2048.

Step S84, time domain sequences is carried out interpolation, its length transition is returned and the described target preamble sequence time-domain sampling corresponding length of counting;

Change into 2048 owing in the default small point IFFT conversion process time-domain sampling counted greater than the length of 2048 sequence, so need by interpolation, its length be changed back its original length at this, change for different length, the process of interpolation is also different.

Through the time domain sequences U after the interpolation _u(t), t=0,1 ... L-1, L is for to count corresponding with the time-domain sampling of target preamble sequence.

Step S85, obtain phase rotation angle according to the original position of preset frequency domain resource;

According to According to formula 4

$A_{n_{\mathrm{PRB}}^{\mathrm{RA}}}=e^{\frac{\mathrm{<figure-callout\; id="2"\; label="j"\; filenames="HSA00000140904400021.png,HSA00000140904400022.png"\; state="\{\{state\}\}">j</figure-callout>}2\mathrm{\&pi;t}(n_{\mathrm{PRB}}^{\mathrm{RA}}-(N_{\mathrm{RB}}^{\mathrm{UL}}/2-3))N_{\mathrm{SC}}^{\mathrm{RB}}K}{L}}---\left(4\right)$

Generate the angle of phase place rotation.In this step, the band bending amount of frequency domain is converted to the phase deviation of time domain.

Step S86, time domain sequences after the length transition and described phase rotation angle are multiplied each other, carry out phase transition;

Realize the offset of frequency domain by the phase transition of time domain.

Step S87, carry out corresponding subsequent processing according to the form of the described target preamble sequence time domain sequences after to described phase transition;

For different preamble Format Series Lineses, its post-treatment operations is different.

Step S88, interpolation Cyclic Prefix arrive the time domain sequences after the described subsequent treatment, obtain target preamble sequence.

Add cyclic prefix CP for time domain sequences, obtain target preamble sequence.

As can be seen from the above step, this method is at the different time domain sampling number, preestablished dissimilar small point IFFT conversion, avoid the situation appearance of IFFT conversion of counting greatly, thereby improved arithmetic speed, then it has been carried out equivalent operation, the final generation is equivalent to the frequency domain resource mapping and the IFFT computing preamble sequence of counting greatly, and the dependence interpolation operation, according to different demands, adjust its accuracy.

By said method, reduced the amount of calculation in the preamble sequence generative process, improved formation speed, reduced power consumption and circuit area simultaneously.

Embodiment two

As can be seen from the above-described embodiment, according to different preamble Format Series Lineses and time domain sampling point parameter, its concrete generative process is different, and present embodiment will be further detailed at above-mentioned difference.Its flow process comprises as shown in Figure 9:

Step S91, generation frequency domain ZC sequence;

Step S92, the form of determining target preamble sequence and time domain sampling number;

According to the preliminary election requirement, definite form and time domain sampling number that needs the preamble sequence of generation.

Step S93, judge that the time-domain sampling of described target preamble sequence counts, execution in step S941 when being 1024, when more than or equal to 2048 the time, execution in step S942;

Step S941, described ZC sequence is carried out sampling number is 1024 inverse discrete Fourier transform, obtains time domain sequences;

Counting for the time-domain sampling of target preamble sequence equals 1024 situations, owing to have and its corresponding sampling points number in the IFFT unit, then it is carried out conversion according to the corresponding sampling points number.

Step S942, described ZC sequence is carried out sampling number is 2048 inverse discrete Fourier transform, obtains time domain sequences;

Count when equaling 2048 when the time-domain sampling of target preamble sequence, it carried out the IFFT conversion according to 2048 sampled points, and but its greater than 2048 o'clock, in order to reduce its amount of calculation, carry out the IFFT conversion according to 2048 sampled points equally.

Step S95, described time domain sequences is carried out interpolation, its length transition is become and the described target preamble sequence time-domain sampling corresponding length of counting;

Owing in the IFFT conversion process length of time domain sequences is changed into 1024 or 2048, sampling number is transformed to 2048 greater than the length of 2048 sequence by unified, so need be at this, by interpolation, its length is extended to and the described target preamble sequence time-domain sampling corresponding length of counting.Change for different length, the process of interpolation is also different.

Through the time domain sequences U after the interpolation _u(t), t=0,1 ... L-1, the L value is counted for the target preamble sequence time-domain sampling.

Step S96, obtain phase rotation angle according to the original position of preset frequency domain resource;

According to

According to formula 4

$A_{n_{\mathrm{PRB}}^{\mathrm{RA}}}=e^{\frac{\mathrm{<figure-callout\; id="2"\; label="j"\; filenames="HSA00000140904400021.png,HSA00000140904400022.png"\; state="\{\{state\}\}">j</figure-callout>}2\mathrm{\&pi;t}(n_{\mathrm{PRB}}^{\mathrm{RA}}-(N_{\mathrm{RB}}^{\mathrm{UL}}/2-3))N_{\mathrm{SC}}^{\mathrm{RB}}K}{L}}---\left(4\right)$

Generate the angle of phase place rotation.In this step, the side-play amount of frequency domain is converted to the phase deviation of time domain.

Step S97, time domain sequences after the length transition and described phase rotation angle are multiplied each other, carry out phase transition;

Realize the band bending of frequency domain by the phase transition of time domain.

The form of step S98, the described target preamble sequence of judgement, when its form is format0 or format4, execution in step S991, when its form is format1, format2 or format3, execution in step S992;

For different preamble Format Series Lineses, its post-treatment operations is different.

Step S991, the time domain sequences after the described phase transition is carried out do-nothing operation;

Step S992, the time domain sequences after the described phase transition carried out the repetitive operation of corresponding number of times;

Because the sequence of format1, format2 and format3 form can obtain by the repetitive operation to format0, described repetitive operation is to connect this time domain sequences after described time domain sequences, and concrete connection number of times is decided according to different types.

Step S910, interpolation Cyclic Prefix arrive the time domain sequences after the described subsequent treatment, obtain target preamble sequence.

Add cyclic prefix CP for time domain sequences, obtain target preamble sequence.

At different preamble Format Series Lineses and time domain sampling point parameter, the generative process of preamble sequence has been carried out more detailed description in the present embodiment.

Embodiment three

The generation of preamble sequence need rely on frequency domain ZC sequence among the present invention, and except that utilizing method of the prior art to generate the frequency domain ZC sequence, present embodiment discloses a kind of new frequency domain ZC sequence generation method, and its flow process comprises as shown in figure 10:

Step S 101, generate time domain ZC sequence according to formula;

Step S102, calculate described time domain ZC sequence and;

Utilize formula 5 sequence of calculations and,

$Z_{\mathrm{sum}}=\underset{n=0}{\overset{N_{\mathrm{ZC}}-1}{\mathrm{\&Sigma;}}}{x}_u\left(n\right)---\left(5\right)$

Step S103, the default frequency domain index value of basis are selected the time domain sample value from described ZC sequence;

The index value of supposing this moment is k, and according to the characteristic of ZC sequence, this moment, the time domain index value corresponding with it was u ' k, and then Ci Shi sample value is x _u(u ' k), wherein u ' satisfies mod (u ' u, N _ZC)=1;

Step S104, the time domain sample value of described selection is carried out conjugate operation;

With described sample value x _u(u ' k) carry out conjugate operation to obtain

Step S105, obtain described time domain ZC sequence and with described conjugate operation after the multiplied result of time domain sample value;

With described

With described Multiply each other according to formula 6,

$Z_u\left(k\right)=Z_{\mathrm{sum}}{x}_u^{*}\left(u^{\&prime;}k\right)---\left(6\right)$

The cyclic shift amount that step S106, basis set in advance generates phase rotation angle;

According to cyclic shift amount C _vAccording to formula 7

$A_{C_v}={\mathrm{<figure-callout\; id="2"\; label="e\; j"\; filenames="HSA00000140904400021.png,HSA00000140904400022.png"\; state="\{\{state\}\}">e</figure-callout>}}^{\frac{j}{}}---\left(7\right)$

Generate the angle of phase place rotation.

Step S107, multiply each other, obtain frequency domain ZC sequence with described time domain ZC sequence with the multiplied result and the described phase rotation angle of time domain sample value behind the described conjugate operation.

According to formula 8

$F_u\left(k\right)=A_{C_v}{Z}_u\left(k\right)---\left(8\right)$

Obtain frequency domain ZC sequence.

Because the sampling number of time domain ZC sequence is 839 or 139, with conventional DFT base-2,4,8 count requires and do not match, so directly it being carried out DFT, can computational speed to occur slow, amount of calculation is big, be difficult for problem such as realization.And the method for disclosed generation frequency domain ZC sequence has adopted a series of equivalent operation in the present embodiment, substitute DFT computing of the prior art and cyclic shift, owing to need not consider computing value type and the unmatched situation of DFT computing value type, the step that requires to the evaluation type does not appear, avoided because the evaluation type does not match, problems such as the amount of calculation that adopts the DFT computing to cause is big, arithmetic speed slow, difficult realization, further improved the formation speed of preamble sequence, and formation efficiency.

The present invention discloses a kind of generation equipment of preamble sequence, its structure as shown in figure 11, comprise: frequency domain ZC sequence generation unit 111, determining unit 112, inverse discrete Fourier transform unit 113, interpolating unit 114, angle generation unit 115, first multiply each other unit 116, subsequent treatment unit 117 and add cyclic prefix unit 118, wherein:

Time domain ZC sequence generating unit 111 is used to generate frequency domain ZC sequence; Determining unit 112 is used for determining the form and the time domain sampling number of target preamble sequence; Inverse discrete Fourier transform unit 113 is used for counting according to the time-domain sampling of described target preamble sequence described frequency domain ZC sequence is carried out accordingly default small point inverse discrete Fourier transform, obtains time domain sequences; Interpolating unit 114 is used for described time domain sequences is carried out interpolation, its length transition is become and the described target preamble sequence time-domain sampling corresponding length of counting; Angle generation unit 115 is used for obtaining phase rotation angle according to the original position of preset frequency domain resource; First unit 116 that multiplies each other is used for time domain sequences after the length transition and described phase rotation angle are multiplied each other, and carries out phase transition; Subsequent treatment unit 117 is used for form according to the described target preamble sequence time domain sequences after to described phase transition and carries out corresponding subsequent processing; Add cyclic prefix unit 118 and be used to add the time domain sequences of Cyclic Prefix after the described subsequent treatment, obtain target preamble sequence.

The structure of frequency domain ZC sequence generation unit 111 can be same as the prior art, also can be as shown in figure 12, comprise: multiply each other unit 1115, angle generation unit 1116 and third phase of time domain ZC sequence generating unit 1111, sum unit 1112, sampling point selected cell 1113, conjugate unit 1114, second taken advantage of unit 1117, wherein:

Time domain ZC sequence generating unit 1111 is used for generating time domain ZC sequence according to formula, sum unit 1112 be used to calculate described time domain ZC sequence and; Sampling point selected cell 1113 is used for selecting the time domain sample value according to default frequency domain index value from described ZC sequence; Conjugate unit 1114 is used for the time domain sample value of described selection is carried out conjugate operation; Second multiply each other unit 1115 be used to obtain described time domain ZC sequence and with described conjugate operation after the multiplied result of time domain sample value; Angle generation unit 1116 is used for generating phase rotation angle according to the cyclic shift amount that sets in advance; Third phase takes advantage of unit 1117 to be used for described second the multiply each other result of unit and the result of described angle generation unit multiplied each other, and obtains frequency domain ZC sequence.

The structure of interpolating unit 114 as shown in figure 13, comprise: three times of up-sampling unit 1141, first low pass filter 1142, the first twice up-sampling unit 1143, second low pass filter unit 1144, the second twice up-sampling unit 1145, the 3rd low pass filter unit 1146, each unit order successively links to each other, import from described three times of up-sampling unit 1141 through the time domain sequences that IFFT obtains, it is repeatedly sampled and low-pass filtering operation,, take out the value corresponding that is positioned at the different disposal process with it according to different time domain sequences form and sampling numbers.

The present invention does not limit the structure of interpolating unit, and multiple combining form can also be arranged, and by adjusting its combining form, can realize improving the purpose of preamble sequence accuracy.

Each embodiment adopts the mode of going forward one by one to describe in this specification, and what each embodiment stressed all is and the difference of other embodiment that identical similar part is mutually referring to getting final product between each embodiment.For the disclosed device of embodiment, because it is corresponding with the embodiment disclosed method, so description is fairly simple, relevant part partly illustrates referring to method and gets final product.

The professional can also further recognize, the unit and the algorithm steps of each example of describing in conjunction with embodiment disclosed herein, can realize with electronic hardware, computer software or the combination of the two, for the interchangeability of hardware and software clearly is described, the composition and the step of each example described prevailingly according to function in the above description.These functions still are that software mode is carried out with hardware actually, depend on the application-specific and the design constraint of technical scheme.The professional and technical personnel can use distinct methods to realize described function to each specific should being used for, but this realization should not thought and exceeds scope of the present invention.

The method of describing in conjunction with embodiment disclosed herein or the step of algorithm can directly use the software module of hardware, processor execution, and perhaps the combination of the two is implemented.Software module can place the storage medium of any other form known in random asccess memory (RAM), internal memory, read-only memory (ROM), electrically programmable ROM, electrically erasable ROM, register, hard disk, moveable magnetic disc, CD-ROM or the technical field.

To the above-mentioned explanation of the disclosed embodiments, make this area professional and technical personnel can realize or use the present invention.Multiple modification to these embodiment will be conspicuous concerning those skilled in the art, and defined herein General Principle can realize under the situation that does not break away from the spirit or scope of the present invention in other embodiments.Therefore, the present invention will can not be restricted to these embodiment shown in this article, but will meet and principle disclosed herein and features of novelty the wideest corresponding to scope.

Claims (9)

1. the generation method of a preamble sequence is characterized in that, comprising:

Generate frequency domain ZC sequence;

Determine the form and the time domain sampling number of target preamble sequence;

Count according to the time-domain sampling of described target preamble sequence described frequency domain ZC sequence is carried out accordingly default small point inverse discrete Fourier transform, obtain time domain sequences;

Time domain sequences is carried out interpolation, its length transition is returned and the described target preamble sequence time-domain sampling corresponding length of counting;

Original position according to preset frequency domain resource obtains phase rotation angle;

Time domain sequences after the length transition and described phase rotation angle are multiplied each other, carry out phase transition;

Carry out corresponding subsequent processing according to the form of the described target preamble sequence time domain sequences after to described phase transition;

Add the time domain sequences after Cyclic Prefix arrives described subsequent treatment, obtain target preamble sequence.

2. method according to claim 1 is characterized in that, when the time-domain sampling of described target preamble sequence is counted when being 1024, it is 1024 inverse discrete Fourier transform that described ZC sequence is carried out sampling number.

3. method according to claim 2 is characterized in that, when the time-domain sampling of described target preamble sequence is counted more than or equal to 2048 the time, it is 2048 inverse discrete Fourier transform that described ZC sequence is carried out sampling number.

4. method according to claim 3 is characterized in that, when the form of described target preamble sequence was format0 or format4, described subsequent treatment was do-nothing operation.

5. method according to claim 4 is characterized in that, when the form of described target preamble sequence was format1, format2 or format3, described subsequent treatment was for to carry out the repetitive operation of corresponding number of times to the time domain sequences after the described phase transition.

6. according to any described method among the claim 1-5, it is characterized in that, generate frequency domain ZC sequence according to following process:

Generate time domain ZC sequence according to formula;

Calculate described time domain ZC sequence and;

From described ZC sequence, select the time domain sample value according to default frequency domain index value;

The time domain sample value of described selection is carried out conjugate operation;

Obtain described time domain ZC sequence and with described conjugate operation after the multiplied result of time domain sample value;

Generate phase rotation angle according to the cyclic shift amount that sets in advance;

Multiply each other with described time domain ZC sequence with the multiplied result and the described phase rotation angle of time domain sample value behind the described conjugate operation, obtain frequency domain ZC sequence.

7. the generation equipment of a preamble sequence is characterized in that, comprising:

The frequency domain ZC sequence generation unit is used to generate frequency domain ZC sequence;

Determining unit is used for determining the form and the time domain sampling number of target preamble sequence;

The inverse discrete Fourier transform unit is used for counting according to the time-domain sampling of described target preamble sequence described frequency domain ZC sequence is carried out accordingly default small point inverse discrete Fourier transform, obtains time domain sequences;

Interpolating unit is carried out interpolation to time domain sequences, and its length transition is returned and the described target preamble sequence time-domain sampling corresponding length of counting;

The angle generation unit is used for obtaining phase rotation angle according to the original position of preset frequency domain resource;

First unit that multiplies each other is used for time domain sequences after the length transition and described phase rotation angle are multiplied each other, and carries out phase transition;

The subsequent treatment unit is used for form according to the described target preamble sequence time domain sequences after to described phase transition and carries out corresponding subsequent processing;

Add cyclic prefix unit, be used to add the time domain sequences after Cyclic Prefix arrives described subsequent treatment, obtain target preamble sequence.

8. equipment according to claim 1 is characterized in that, described frequency domain ZC sequence generation unit comprises:

Time domain ZC sequence generating unit is used for generating time domain ZC sequence according to formula;

Sum unit, be used to calculate described time domain ZC sequence and;

The sampling point selected cell is used for selecting the time domain sample value according to default frequency domain index value from described ZC sequence;

Conjugate unit is used for the time domain sample value of described selection is carried out conjugate operation;

First unit that multiplies each other, be used to obtain described time domain ZC sequence and with described conjugate operation after the multiplied result of time domain sample value;

The angle generation unit is used for generating phase rotation angle according to the cyclic shift amount that sets in advance;

Second unit that multiplies each other is used for described first the multiply each other result of unit and the result of described angle generation unit multiplied each other, and obtains frequency domain ZC sequence.

9. according to claim 7 or 8 described methods, it is characterized in that described interpolating unit comprises: three times of up-sampling unit that order links to each other, first low pass filter, the first twice up-sampling unit, second low pass filter unit, the second twice up-sampling unit, the 3rd low pass filter unit.

Images