CN105323048B - The generation method of leading symbol in physical frame - Google Patents
The generation method of leading symbol in physical frame Download PDFInfo
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- CN105323048B CN105323048B CN201410229558.7A CN201410229558A CN105323048B CN 105323048 B CN105323048 B CN 105323048B CN 201410229558 A CN201410229558 A CN 201410229558A CN 105323048 B CN105323048 B CN 105323048B
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/26—Systems using multi-frequency codes
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04J—MULTIPLEX COMMUNICATION
- H04J13/00—Code division multiplex systems
- H04J13/0007—Code type
- H04J13/0055—ZCZ [zero correlation zone]
- H04J13/0059—CAZAC [constant-amplitude and zero auto-correlation]
Abstract
The invention discloses a kind of generation methods of leading symbol in physical frame, make inverse discrete fourier transform including the frequency-domain OFDM symbol to predetermined length to obtain time-domain OFDM symbol;The time-domain OFDM symbol of circulating prefix-length is intercepted as cyclic prefix from the time-domain OFDM symbol;The time-domain OFDM symbol of the circulating prefix-length based on above-mentioned interception generates modulated signal;Leading symbol is generated based on the cyclic prefix, the time-domain OFDM symbol and the modulated signal.The technical program solves in current DVB_T2 standard and other standards, there is no cyclic prefix in DVB_T2 spatial structure, it is not applied for relevant detection, and the problem of probability of failure occurs in leading symbol low complex degree receiving algorithm detection under complex frequency Selective Fading Channel.
Description
Technical field
The present invention relates to wireless broadcast communication technical field, in particular to the generation side of leading symbol in a kind of physical frame
Method.
Background technique
Generally for enabling the receiving end of ofdm system correctly to demodulate data transmitted by transmitting terminal, ofdm system must
It must realize between transmitting terminal and receiving end accurately and reliably time synchronization.Simultaneously as ofdm system to the frequency deviation of carrier wave very
Sensitivity, the receiving end of ofdm system it is also required to provide the carrier spectrum estimation method of precise and high efficiency, to carry out essence to carrier wave frequency deviation
True estimation and correction.
Currently, realizing that the transmitting terminal method synchronous with destination time is based on leading symbol in ofdm system
It realizes.Leading symbol is all known symbol sebolic addressing of transmitting terminal and receiving end of ofdm system, and leading symbol is as physical frame
Beginning (being named as P1 symbol), only occur a P1 symbol in each physical frame or multiple P1 symbols continuously occur, it is marked
The will beginning of the physical frame.The purposes of P1 symbol includes:
1) detect receiving end rapidly with determine transmitted in channel whether be expectation received signal;
2) basic configured transmission (such as FFT points, frame type information etc.) is provided so that receiving end can carry out it is subsequent
Reception processing;
3) original carrier frequency deviation and timing error are detected, reaches frequency and Timing Synchronization after compensating;
4) emergency alarm or broadcast system wake up.
The P1 Design of Symbols based on CAB spatial structure is proposed in DVB_T2 standard, preferably realizes above-mentioned function.
But still there are some limitations on low complex degree receiving algorithm.For example, the length in 1024,542 or 482 symbols is more
When diameter channel, relatively large deviation can be occurred by being timed thick synchronization using CAB structure, cause to estimate carrier wave integer frequency on frequency domain
Deflect away from existing mistake.In addition, in complex frequency Selective Fading Channel, such as when long multipath, DBPSK differential decoding may also
It can fail.Moreover, because there is no cyclic prefix in DVB_T2 spatial structure, and if needing to carry out the frequency-domain structure of channel estimation
The problem of combining, its channel estimation in frequency domain performance degradation will be caused.
Summary of the invention
Problems solved by the invention is not followed in DVB_T2 spatial structure in current DVB_T2 standard and other standards
Ring prefix is not applied for relevant detection, and leading symbol low complex degree under complex frequency Selective Fading Channel receives
There is the problem of probability of failure in algorithm detection.
To solve the above problems, the embodiment of the invention provides a kind of generation methods of leading symbol in physical frame, including
Following steps: inverse discrete fourier transform is made to obtain time-domain OFDM symbol to the frequency-domain OFDM symbol of predetermined length;From described
Time-domain OFDM symbol intercepts the time-domain OFDM symbol of circulating prefix-length as cyclic prefix;Based on being followed described in above-mentioned interception
The time-domain OFDM symbol of ring prefix length generates modulated signal;Based on the cyclic prefix, the time-domain OFDM symbol and described
Modulated signal generates leading symbol.
Optionally, before being used as circulation from the time-domain OFDM symbol of time-domain OFDM symbol interception circulating prefix-length
Before sewing further include: the various combination of the circulating prefix-length and modulated signal length is selected, so that finally formed leading
Symbol transmits signaling information by above-mentioned various combination.
Optionally, the various combination of the selection circulating prefix-length and modulated signal length, in the time domain
The bit number N that signaling information comprises determining that the signaling information of being transmitted is transmitted in OFDM symbol;Choose 2NA cyclic prefix is long
The various combination of degree and modulated signal length, so that finally formed leading symbol passes through above-mentioned 2NA various combination transmits
Signaling information.
Optionally, before being used as circulation from the time-domain OFDM symbol of time-domain OFDM symbol interception circulating prefix-length
Before sewing further include:
Determine the combination of a kind of circulating prefix-length and modulated signal length;
In the time-domain OFDM symbol for intercepting the circulating prefix-length, different initial positions is selected to intercept the tune
The time-domain OFDM symbol of signal length processed generates modulated signal so that finally formed leading symbol pass through it is described different
Signaling information is transmitted in initial position.
Optionally, the signaling information includes emergency alarm or broadcast system mark EAS_flag, transmitter flag information
TXID, hook information or other configured transmissions.
Optionally, make inverse discrete fourier transform in the frequency-domain OFDM symbol to predetermined length to obtain time domain
Further include following steps before OFDM symbol:
Determine the average power ratio of fixed sequence program and signaling sequence;
Fixed sequence program and signaling sequence are generated respectively on frequency domain according to the average power ratio;
Fixed sequence program and signaling sequence are filled to effective subcarrier, and between the fixed sequence program and signaling sequence
It is arranged in oem character set;
Null sequence subcarrier is filled respectively in effective subcarrier two sides to form the frequency-domain OFDM of predetermined length symbol
Number.
Optionally, the mean power of the fixed sequence program and signaling sequence is same or different.
Optionally, the power ratio of the fixed sequence program and signaling sequence is 1:1 or 3:2 or 2:1 or 3:1.
Compared with prior art, technical solution of the present invention has the advantages that
The generation method of leading symbol in the physical frame provided according to embodiments of the present invention, according to different channel circumstances
It determines circulating prefix-length, and intercepts the time-domain OFDM symbol of the circulating prefix-length as circulation from time-domain OFDM symbol
Prefix, to solve the problems, such as the decline of channel estimation in frequency domain performance.And the circulating prefix-length based on above-mentioned interception
Time-domain OFDM symbol generate modulated signal so that generate leading symbol have good fractional part of frequency offset estimation performance and
Timing Synchronization performance.
Further, by selecting the various combination of circulating prefix-length and modulated signal length, so that finally formed
Leading symbol transmits signaling information by above-mentioned various combination;Or determine that a kind of circulating prefix-length is believed with modulation
The combination of number length, and in the time-domain OFDM symbol for intercepting the circulating prefix-length, select different initial positions to cut
The time-domain OFDM symbol of the modulated signal length is taken to generate modulated signal, so that finally formed leading symbol is described in
Signaling information is transmitted in different initial position.
Further, using the modulated signal of time-domain OFDM symbol and the structure of time-domain OFDM symbol (as leading character
Number) it ensure that the peak value for utilizing delay correlation may be significantly in receiving end.Also, during generating the leading symbol,
The modulated signal for designing time-domain OFDM symbol can be to avoid receiving end by continuous wave CO_2 laser perhaps mono-tone interference or appearance
When protection interval length is identical with modulated signal length in the isometric multipath channel with modulated signal length, or reception signal
There is error detection peak value.
Detailed description of the invention
Fig. 1 is the process signal of the specific embodiment of the generation method of leading symbol in a kind of physical frame of the invention
Figure;
Fig. 2 is the CAB structure of the leading symbol generated using the generation method of leading symbol in physical frame shown in FIG. 1
Schematic diagram;
Fig. 3 A is the CAB of a kind of transmission emergency alarm of the invention or the leading symbol of broadcast system mark EAS_flag
Structural schematic diagram;
Fig. 3 B is the leading symbol of another transmission emergency alarm or broadcast system mark EAS_flag of the invention
CAB structural schematic diagram;
Fig. 4 is to generate the specific of frequency-domain OFDM symbol in a kind of physical frame of the invention in the generation method of leading symbol
The flow diagram of embodiment.
Specific embodiment
Inventor has found do not have cyclic prefix in DVB_T2 spatial structure in current DVB_T2 standard and other standards, and
And there is the problem of probability of failure in leading symbol low complex degree receiving algorithm detection under frequency selective fading channels.
In view of the above-mentioned problems, inventor after study, provides a kind of generation method of leading symbol in physical frame.?
It is provided with cyclic prefix in spatial structure, solves the problems, such as the decline of channel estimation in frequency domain performance, utilizes the cyclic prefix part
All or part of data segment generate modulated signal so that generate leading symbol have good small frequency deviation and Timing Synchronization
Performance.
By selecting the various combination of the circulating prefix-length and modulated signal length, so that finally formed leading
Symbol transmits signaling information by above-mentioned various combination;Or determine that a kind of circulating prefix-length and modulated signal are long
The combination of degree, and in the time-domain OFDM symbol for intercepting the circulating prefix-length, selecting different initial positions to intercept should
The time-domain OFDM symbol of modulated signal length generates modulated signal, so that finally formed leading symbol passes through the difference
Initial position transmit signaling information.
Further, it ensure that carrier frequency offset receiving end within the scope of -500kHz to 500kHz still can handle to connect
The collection of letters number.
To make the above purposes, features and advantages of the invention more obvious and understandable, with reference to the accompanying drawing to the present invention
Specific embodiment be described in detail.
As shown in Fig. 1 the specific embodiment of the generation method of leading symbol in a kind of physical frame of the invention
Flow diagram.With reference to Fig. 1, the generation method of leading symbol includes the following steps: in physical frame
Step S15: inverse discrete fourier transform is made to the frequency-domain OFDM symbol of predetermined length to obtain time domain OFDM symbol
Number;
Step S16: it is used as from the time-domain OFDM symbol of time-domain OFDM symbol interception circulating prefix-length before recycling
Sew;
Step S17: the time-domain OFDM symbol of the circulating prefix-length based on above-mentioned interception generates modulated signal;
Step S18: leading symbol is generated based on the cyclic prefix, the time-domain OFDM symbol and the modulated signal.
In the present embodiment, as described in step S15, inverse discrete Fourier transform is made to the frequency-domain OFDM symbol of predetermined length
It changes to obtain time-domain OFDM symbol.
Inverse discrete fourier transform described in this step is that frequency-region signal is commonly converted into the mode of time-domain signal,
It will not be described here.
P1_XiTime-domain OFDM symbol is obtained after making inverse discrete fourier transform:
Wherein, M is effective non-zero sub-carriers
Number.
As described in step S16, it is used as and follows from the time-domain OFDM symbol of time-domain OFDM symbol interception circulating prefix-length
Ring prefix.
In the present embodiment, the circulating prefix-length is equal to or less than the predetermined length.With the predetermined length
For 1024, the circulating prefix-length can be 1024 or less than 1024.Preferably, the circulating prefix-length is
512, the latter half (length 512) of the time domain OFDM symbol is usually intercepted as cyclic prefix, to solve frequency domain letter
Estimate the problem of performance decline in road.
Wherein, the determining circulating prefix-length be usually required according to wireless broadcast communication system confrontation multipath it is long
Degree, system can obtain the minimum length of robust correlation peak and the ratio of spatial structure transmission signaling in minimum threshold level
Special number is any one or more of because usually determining.If only need frequency-domain structure transmit signaling, and spatial structure is fixed and
Without transmitting signaling, then only need to consider to need the multipalh length fought, system that can obtain robust phase in minimum threshold level
Close peak value one of minimum length or two.In general, the length of cyclic prefix is longer, the performance for fighting long multipath is got over
It is good, and the length of cyclic prefix and modulated signal length are longer, postpone relevant peak value and get over robust.In general, cyclic prefix
Length and modulated signal length, which need to be more than or equal to system, can obtain the minimum long of robust correlation peak in minimum threshold level
Degree.
As described in step S17, the time-domain OFDM symbol of the circulating prefix-length based on above-mentioned interception generates modulation letter
Number.In practice, modulated signal length is generally without departing from the length of cyclic prefix part.
Specifically, this step includes:
1) a frequency deviation sequence is set;
2) by the time domain OFDM of the time-domain OFDM symbol of the circulating prefix-length or the part circulating prefix-length
Symbol is multiplied by the frequency deviation sequence to obtain the modulated signal.
For example, setting NcpFor determining circulating prefix-length, LenBFor modulated signal length.Modulated signal length is by system
The minimum length of robust correlation peak can be obtained in minimum threshold level to determine.Usual modulated signal length is more than or equal to
The minimum length.If NAFor the length of time-domain OFDM symbol, if sampled point serial number 0,1 ... the N of time-domain OFDM symbolA-1.
If N1 is the sampled point serial number for the corresponding time-domain OFDM symbol of starting point that selection is copied to modulated signal section, N2 is selection duplication
To the corresponding time-domain OFDM symbol sampled point serial number of terminal of modulated signal section.Wherein,
N2=N1+LenB-1
For ease of description, time-domain OFDM symbol is divided into 2 parts, first segment is the portion not intercepted as cyclic prefix
Divide time-domain OFDM symbol (the generally front of the time-domain OFDM symbol), when second segment is part of the interception as cyclic prefix
Domain OFDM symbol (the generally rear portion of the time-domain OFDM symbol).If interception time-domain OFDM symbol is all used as cyclic prefix,
Then the length of first segment is 0.N1 is centainly fallen in second segment, that is, is selected to the part time-domain OFDM symbol of modulated signal section
Range without departing from interception as cyclic prefix part time-domain OFDM symbol range.
Modulated signal part, cyclic prefix part are identical as a part of information in time-domain OFDM symbol.Wherein, it modulates
Signal section is only to have modulated frequency deviation or other signals, therefore can use the phase of modulated signal part with cyclic prefix part
The correlation of pass value and modulated signal part and time-domain OFDM symbol does Timing Synchronization and small inclined estimation.In practice, it adjusts
Signal length processed is usually no more than circulating prefix-length.If modulated signal length is greater than circulating prefix-length, the portion exceeded
Divide the expense that will increase system, causes the decline of efficiency of transmission, and it is only capable of enhanced modulation signal section and time-domain OFDM symbol
Correlation robustness, under the expense maintained like, this partial-length should increase to cyclic prefix part, it is by band
Carry out more performance benefits.
As shown in Fig. 2, A segment table shows that time-domain OFDM symbol, C segment table show that cyclic prefix, B segment table show modulated signal.The frequency deviation
Sequence isWherein fSHIt can be chosen for the corresponding subcarrier in frequency domain interval (i.e. 1/ of time-domain OFDM symbol
NAT), wherein T is sampling period, NAFor the length of time-domain OFDM symbol.In this example, NAIt is 1024, takes fSH=1/
1024T.In other instances, in order to keep correlation peak sharp, fSHAlso it can choose as 1/ (LenBT).Work as LenB=NCPWhen,
fSH=1/NCPT.Such as LenB=NCPWhen=512, fSH=1/512T.
In other embodiments, M (t) can also be designed to other sequences, such as m-sequence or the window sequence of some simplification
Deng.
The modulated signal of the part time-domain OFDM symbol is P1_B (t), and P1_B (t) is accorded with by the part time domain OFDM
It number is obtained multiplied by frequency deviation sequence M (t), i.e. P1_B (t) are as follows:
Wherein, N1 is that selection is copied to modulated signal section
The corresponding time-domain OFDM symbol of starting point sampled point serial number.
As described in step S18, before being generated based on the cyclic prefix, the time-domain OFDM symbol and the modulated signal
Lead symbol.
Specifically, the cyclic prefix is spliced in the front of the time-domain OFDM symbol as protection interval, and by institute
Modulated signal is stated to splice at the rear portion of the OFDM symbol as frequency modulation sequence to generate leading symbol, as shown in Figure 2.
For example, leading symbol can be according to using following time-domain expression:
In a preferred embodiment, the predetermined length NA=1024;NcpFor the half of the predetermined length, that is, work as
NAWhen=1024, Ncp=512.
When not needing the spatial structure transmission signaling with the leading symbol, when generating modulated signal, one is only taken to consolidate
Fixed starting point.Preferably, Len is setB=NcpAnd N1=NA-Ncp, i.e.,
Work as NA=1024, NcpWhen=512, LenB=512, N1=512.
Further, in this embodiment also by generating different cyclic prefix and modulated signal, so that finally
The leading symbol of formation is also different, so as to can make to it when leading symbol of the receiving end in the physical frame that demodulation receives
Postpone related operation, and according to the different delay of setting is attempted, wherein length of delay only has the design parameter for matching leading symbol,
Apparent correlation peak can be just obtained, different leading symbols is distinguished with this, to reach the spatial structure in leading symbol
Transmit the purpose of signaling information.
One specific example is to further include following steps before the step S16: selecting the circulating prefix-length
With the various combination of modulated signal length, believe so that finally formed leading symbol transmits signaling by above-mentioned various combination
Breath.
Specifically, which includes:
1) the bit number N for the signaling information of being transmitted is determined;
2) 2 are chosenNThe various combination of a circulating prefix-length and modulated signal length, so that finally formed leading character
Number pass through above-mentioned 2NA various combination transmits signaling information.
In practice, some signaling informations (such as emergency alarm or broadcast system identify EAS_flag) only need 1 ratio
Spy, some signaling informations (such as transmitter flag information TXID) need 4 bits.Therefore, according to the signaling information of being transmitted
Bit number (being set as N) is to determine the various combination of circulating prefix-length and modulated signal length, the total number of various combination
2N。
By taking the signaling information of transmission is emergency alarm or broadcast system identifies EAS_flag as an example.
For example, the EAS flag of 1 bit of transmission.If the sampled point serial number 0 for the OFDM symbol that predetermined length is 1024,
1,…,1023.If NcpFor determining circulating prefix-length, LenBFor modulated signal length.If NAFor the length of time-domain OFDM symbol
Degree.
If EAS flag=0, takes Ncp=LenB=512;NAFor 1024 OFDM symbol correspondence serial number 512~
1023 sampled point is copied to C as cyclic prefix, NAFor the correspondence serial number 512~1023 of 1024 OFDM symbol
B is generated after sampled point and frequency modulation sequence, is put into the rear portion of A.
If EAS flag=1, takes NCP=512+K;LenB=512-K;NAFor the correspondence serial number of 1024 OFDM symbol
C is copied to as cyclic prefix, N for the sampled point of 512-K~1023AFor the correspondence serial number 512 of 1024 OFDM symbol
B is generated after the sampled point and frequency modulation sequence of+K~1023, is put into the rear portion of A.
Preferably, it can use Nc=NA/ 2+K, Nb=NA/2-K;Pass through selection 2NA different K carrys out the signaling of transmission of n-bit
Information.
It is a kind of CAB structure transmitted emergency broadcast system and identify the leading symbol of EAS_flag with reference to shown in Fig. 3 A
Schematic diagram.Wherein, the value of K is 0 (corresponding EAS_flag=0) and 16 (corresponding EAS_flag=1).
Time-domain expression are as follows:
If EAS_flag=1
If EAS_flag=0
The frequency deviation sequence isWherein fSHIt can be chosen for corresponding frequency domain of time-domain OFDM symbol
Carrier wave interval, that is, 1/NAT, wherein T is sampling period, NAFor the length of time-domain OFDM symbol, in this example, NAIt is 1024, takes fSH
=1/1024T.
Another specific example is, further includes following steps before the step S16:
Determine the combination of a kind of circulating prefix-length and modulated signal length;
In the time-domain OFDM symbol for intercepting the circulating prefix-length, different initial positions is selected to intercept the tune
The time-domain OFDM symbol of signal length processed generates modulated signal so that finally formed leading symbol pass through it is described different
Signaling information is transmitted in initial position.
By taking the signaling information of transmission is emergency alarm or broadcast system identifies EAS_flag as an example.
For example, the predetermined length is 1024, NCPFor 512+K, LenBLength for 512-K, entire leading symbol is
2048, wherein frequency modulation value fSH=1/1024T is indicated by selecting different initial position N1 to be used to transmit 1 bit signalling
Emergency alarm or broadcast system identify EAS_flag.
If EAS_flag=1, N1=512-L is taken, i.e., NAFor 1024 OFDM symbol correspondence serial number 512-L~
B is generated after the sampled point and frequency modulation sequence of 1023-2L, is put into the rear portion of A.
If EAS_flag=0, N1=512+L is taken, i.e., NAFor 1024 OFDM symbol correspondence serial number 512+L~
B is generated after 1023 sampled point and frequency modulation sequence, is put into the rear portion of A.
It is another leading symbol for transmitting emergency alarm or broadcast system mark EAS_flag with reference to shown in Fig. 3 B
CAB structural schematic diagram.Wherein, the value of L is 8.
Time-domain expression are as follows:
If EAS_flag=1
If EAS_flag=0
In another example the predetermined length is 1024, NCPFor 512+15*L, LenBFor 512, N1 can use 512+i*L, 0≤i <
16, then can indicate 16 kinds it is different follow the example of, transmit 4bit signaling information.For example, different transmitters can be different by taking
N1 come transmit the corresponding mark TXID of the transmitter, the same transmitter can also by timesharing change N1 send pass
Defeated parameter.Preferably, L takes 16.
In another example the predetermined length is 1024, NCPFor 512+7*L, LenBFor 512, N1 can use 512+i*L, 0≤i <
7, transmit 3bit signaling information.Preferably, L takes 16.
Further, frequency-domain OFDM symbol is generated in the generation method with reference to leading symbol in a kind of physical frame shown in Fig. 4
Number specific embodiment flow diagram.
Specifically, further include following steps before the step S15 in above-mentioned flow diagram shown in FIG. 1:
Step S11: the average power ratio of fixed sequence program and signaling sequence is determined;
Step S12: fixed sequence program and signaling sequence are generated respectively on frequency domain according to the average power ratio;
Step S13: fixed sequence program and signaling sequence are filled to effective subcarrier, and the fixed sequence program and signaling
It is arranged between sequence in oem character set;
Step S14: null sequence subcarrier is filled respectively in effective subcarrier two sides to form the frequency domain of predetermined length
OFDM symbol.
Specifically, as described in step S11, the average power ratio of fixed sequence program and signaling sequence is determined.Wherein, described
Fixed sequence program includes that receiving end can be used to do the relevant information of carrier frequency synchronization and Timing Synchronization, the signaling sequence includes
Each basic configured transmission.
In the present embodiment, the fixed sequence program and signaling sequence are permanent mode sequence, and fixed sequence program and signaling sequence
In each plural number mould it is all equal.It should be noted that the plural number includes real number (i.e. plural imaginary part is zero).In this way, letter
Enable sequence identical with the mean power of fixed sequence program.
In other embodiments, the mean power of fixed sequence program and signaling sequence can be the same or different, can basis
Practical application request adjustment, selection increase the power of fixed sequence program to obtain better channel estimation and whole inclined estimation performance, or
Person selects the power for increasing signaling sequence to improve the practical signal-to-noise ratio on signaling carrier to improve signaling decoding performance.Therefore,
The average power ratio of fixed sequence program and signaling sequence be according to whole inclined estimation performance, channel estimating performance, Xie Xinling performance and
The equilibrium of Timing Synchronization performance considers and determines.In the present embodiment, the average power ratio of the fixed sequence program and signaling sequence
It can be 1:1 or 3:2 or 2:1 or 3:1.When fixed sequence program length is identical with signaling sequence length, average power ratio
As the ratio between power summation.
After determining average power ratio, the Amplitude Ration of fixed sequence program and signaling sequence is just accordingly obtained.Work as average power ratio
For 2:1, and when fixed sequence program and signaling sequence are permanent mode sequence, the Amplitude Ration of corresponding fixed sequence program and signaling sequence is
As described in step S12, fixed sequence program and signaling sequence are generated respectively on frequency domain according to the average power ratio.
In the present embodiment, signaling sequence is generated on frequency domain can use any one of the following two kinds mode, below
Both concrete modes for generating signaling sequence are described in detail.
Mode 1:
1.1 determine length, number and the amplitude of signaling sequence;
1.2 based on the signaling sequence length and number determine CAZAC sequence generate formula in root value;Wherein,
The length of signaling sequence is less than or equal to root value, and root value is more than or equal to twice of the number of signaling sequence.It is excellent
Selection of land, root value are chosen for the length of signaling sequence.
For example, determining sequence length L and signaling number.For example, to pass N number of bit, then signaling number num is 2NAnd it selects
Select the root value that CAZAC sequence generates exp (j π qn (n+1)/root) in formula.Wherein, sequence length L is less than or equal to
Root value, and root value is greater than equal to 2*num.Usual root value is prime number.
The different q value of 1.3 selections generates CAZAC sequence, and wherein the number of q value is equal to the number of signaling sequence, and any
The sum of two q values are not equal to root value;And generated CAZAC sequence is needed by cyclic shift, the digit of cyclic shift by
Corresponding root value and q value determine.
For example, num different q of selection0、q1、……、qnum-1Generate CAZAC sequence:
S (n)=exp (j π qn (n+1)/root), n=0 ... root-1.
Sequence after cyclic shift are as follows:
sk(n)=[s (k), s (k+1) ..., s (L-1), s (0) ..., s (k-1)]
Wherein, k is the digit of cyclic shift.
It should be noted that in the present embodiment, the q selectedi(0≤i≤num-1) must satisfy following conditions: any
2 qi、qj(0≤i, j≤num-1) meets qi+qj≠root.
Under the above conditions, the sequence so that whole frequency-domain OFDM symbol PAPR low is preferentially selected.And if L be greater than etc.
In 2*num, preferentially selecting the autocorrelation value of the such sequence of root=L. is zero.
1.4 choose the signaling sequence from all CAZAC sequences according to the number of identified signaling sequence.It needs
If being noted that L=root, do not need to intercept, obtained CAZAC sequence can be used as signaling sequence.
For example, the continuous part sequence or full sequence that each sequence truncation length in num sequence is L are made
For signaling sequence.
For example, signaling sequence length L=353, quantity num=128, then it is immediate prime number that root, which may be selected,
353.The value range of q is 1~352, and the value range of each sequence cyclic shift digit is 1~353.All optional
In signaling sequence, preferably out following 128 groups, q value and cyclic shift position difference are as shown in the table:
Q value value table
Cyclic shift digit table
According to above-mentioned known signaling sequence, a preferably fixed sequence program is calculated, as following formula indicates:
Wherein, ωnValue it is as shown in the table by rows from left to right in order:
5.43 | 2.56 | 0.71 | 0.06 | 2.72 | 0.77 | 1.49 | 6.06 | 4.82 | 2.10 |
5.62 | 4.96 | 4.93 | 4.84 | 4.67 | 5.86 | 5.74 | 3.54 | 2.50 | 3.75 |
0.86 | 1.44 | 3.83 | 4.08 | 5.83 | 1.47 | 0.77 | 1.29 | 0.16 | 1.38 |
4.38 | 2.52 | 3.42 | 3.46 | 4.39 | 0.61 | 4.02 | 1.26 | 2.93 | 3.84 |
3.81 | 6.21 | 3.80 | 0.69 | 5.80 | 4.28 | 1.73 | 3.34 | 3.08 | 5.85 |
1.39 | 0.25 | 1.28 | 5.14 | 5.54 | 2.38 | 6.20 | 3.05 | 4.37 | 5.41 |
2.23 | 0.49 | 5.12 | 6.26 | 3.00 | 2.60 | 3.89 | 5.47 | 4.83 | 4.17 |
3.36 | 2.63 | 3.94 | 5.13 | 3.71 | 5.89 | 0.94 | 1.38 | 1.88 | 0.13 |
0.27 | 4.90 | 4.89 | 5.50 | 3.02 | 1.94 | 2.93 | 6.12 | 5.47 | 6.04 |
1.14 | 5.52 | 2.01 | 1.08 | 2.79 | 0.74 | 2.30 | 0.85 | 0.58 | 2.25 |
5.25 | 0.23 | 6.01 | 2.66 | 2.48 | 2.79 | 4.06 | 1.09 | 2.48 | 2.39 |
5.39 | 0.61 | 6.25 | 2.62 | 5.36 | 3.10 | 1.56 | 0.91 | 0.08 | 2.52 |
5.53 | 3.62 | 2.90 | 5.64 | 3.18 | 2.36 | 2.08 | 6.00 | 2.69 | 1.35 |
5.39 | 3.54 | 2.01 | 4.88 | 3.08 | 0.76 | 2.13 | 3.26 | 2.28 | 1.32 |
5.00 | 3.74 | 1.82 | 5.78 | 2.28 | 2.44 | 4.57 | 1.48 | 2.48 | 1.52 |
2.70 | 5.61 | 3.06 | 1.07 | 4.54 | 4.10 | 0.09 | 2.11 | 0.10 | 3.18 |
3.42 | 2.10 | 3.50 | 4.65 | 2.18 | 1.77 | 4.72 | 5.71 | 1.48 | 2.50 |
4.89 | 4.04 | 6.12 | 4.28 | 1.08 | 2.90 | 0.24 | 4.02 | 1.29 | 3.61 |
4.36 | 6.00 | 2.45 | 5.49 | 1.02 | 0.85 | 5.58 | 2.43 | 0.83 | 0.65 |
1.95 | 0.79 | 5.45 | 1.94 | 0.31 | 0.12 | 3.25 | 3.75 | 2.35 | 0.73 |
0.20 | 6.05 | 2.98 | 4.70 | 0.69 | 5.97 | 0.92 | 2.65 | 4.17 | 5.71 |
1.54 | 2.84 | 0.98 | 1.47 | 6.18 | 4.52 | 4.44 | 0.44 | 1.62 | 6.09 |
5.86 | 2.74 | 3.27 | 3.28 | 0.55 | 5.46 | 0.24 | 5.12 | 3.09 | 4.66 |
4.78 | 0.39 | 1.63 | 1.20 | 5.26 | 0.92 | 5.98 | 0.78 | 1.79 | 0.75 |
4.45 | 1.41 | 2.56 | 2.55 | 1.79 | 2.54 | 5.88 | 1.52 | 5.04 | 1.53 |
5.53 | 5.93 | 5.36 | 5.17 | 0.99 | 2.07 | 3.57 | 3.67 | 2.61 | 1.72 |
2.83 | 0.86 | 3.16 | 0.55 | 5.99 | 2.06 | 1.90 | 0.60 | 0.05 | 4.01 |
6.15 | 0.10 | 0.26 | 2.89 | 3.12 | 3.14 | 0.11 | 0.11 | 3.97 | 5.15 |
4.38 | 2.08 | 1.27 | 1.17 | 0.42 | 3.47 | 3.86 | 2.17 | 5.07 | 5.33 |
2.63 | 3.20 | 3.39 | 3.21 | 4.58 | 4.66 | 2.69 | 4.67 | 2.35 | 2.44 |
0.46 | 4.26 | 3.63 | 2.62 | 3.35 | 0.84 | 3.89 | 4.17 | 1.77 | 1.47 |
2.03 | 0.88 | 1.93 | 0.80 | 3.94 | 4.70 | 6.12 | 4.27 | 0.31 | 4.85 |
0.27 | 0.51 | 2.70 | 1.69 | 2.18 | 1.95 | 0.02 | 1.91 | 3.13 | 2.27 |
5.39 | 5.45 | 5.45 | 1.39 | 2.85 | 1.41 | 0.36 | 4.34 | 2.44 | 1.60 |
5.70 | 2.60 | 3.41 | 1.84 | 5.79 | 0.69 | 2.59 | 1.14 | 5.28 | 3.72 |
5.55 | 4.92 | 2.64 |
The amplitude of fixed sequence program and signaling sequence is determined according to average power ratio.For example, if fixed sequence program and signaling sequence
Average power ratio be 1:1, fixed sequence program and signaling sequence modulus value are 1 in above-described embodiment, and length is identical, meets function
Rate compares demand.For another example in other embodiments, if the average power ratio of fixed sequence program and signaling sequence is 2:1, if fixed
Sequence and the permanent mould of signaling sequence, it is assumed that the amplitude of fixed sequence program is 1, then the amplitude of signaling sequence is
Mode 2:
2.1 determine length, number and the amplitude of signaling sequence;
2.2 based on the signaling sequence length and number determine CAZAC sequence generate formula in several root values;
Wherein, the length of signaling sequence is less than or equal to the minimum value in several selected root values, and selected several
The sum of a root value is more than or equal to twice of the number of signaling sequence.Preferably, root value is chosen for the length of signaling sequence
Degree.
For example, determining sequence length L and signaling number.For example, to pass N number of bit, then signaling number num is 2N, and
CAZAC sequence is selected to generate several K root of exp (j π qn (n+1)/root) in formulak(0≤k≤K-1).Wherein, signaling
Sequence length L is less than or equal to all rootkIn minimum value, and several rootkAnd be more than or equal to 2*num, i.e.,Usual rootkValue is prime number.
2.3 are directed to each root value, and different q value is selected to generate CAZAC sequence, wherein the number of q value be less than or
Equal to the 1/2 of corresponding root value, and the sum of any two q value is not equal to corresponding root value;And generated CAZAC sequence
Column are needed by cyclic shift, and the digit of cyclic shift is determined by corresponding root value and q value.
For example, being directed to each rootk(0≤k≤K-1) selects numkA different q0、q1、 Generate CAZAC sequence
Arrange exp (j π qn (n+1)/rootk), n=0 ... rootk-1.Wherein,
And
In the method 2, for each root value, different q values is selected to generate CAZAC sequence and generated
CAZAC sequence needs to be referred to the description of aforesaid way 1 by the mode of cyclic shift, and details are not described herein.
It should be noted that in the present embodiment, the q selectedi(0≤i≤numk- 1) following conditions be must satisfy: any
2 qi、qj(0≤i,j≤numk- 1) meet qi+qj≠rootk。
Under the above conditions, the sequence so that whole frequency-domain OFDM symbol PAPR low is preferentially selected.And it can preferentially select it
In a root=L.The autocorrelation value for the sequence that the root in this way is generated is zero.
2.4 choose the signaling sequence from each obtained CAZAC sequence according to the number of identified signaling sequence
Column.If be emphasized that wherein some root=L, according to caused by the root value for the length for being chosen for signaling sequence
CAZAC sequence determines the signaling sequence.
For example, the continuous part sequence or full sequence that each sequence truncation length in num sequence is L are made
For signaling sequence.
For example, for example, L=353, num=128.Preferentially select root for 353 by mode 1.Then, q=is selected
1,2,…128.Meet qi+qj≠353,(0≤i,j≤128-1).Finally, being 353 by each sequence truncation to length.
In another example L=350, num=256.It selects root1 for 353, root2=359 by mode 2, is then directed to
Root1=353, selects q=1,2,3 ... 128 totally 128 sequences, qi+qj≠353.Then it is directed to root2=359, selects q
=100,101,102 ... 227 totally 128 sequences, in total 256 sequence.It is finally 353 by each sequence truncation to length.
The amplitude of fixed sequence program and signaling sequence is determined according to average power ratio.For example, if fixed sequence program and signaling sequence
Average power ratio be 1:1, fixed sequence program and signaling sequence modulus value are 1 in above-described embodiment, and length is identical, meets function
Rate compares demand.For another example in other embodiments, if the average power ratio of fixed sequence program and signaling sequence is 2:1, if fixed sequence
Column and the permanent mould of signaling sequence, it is assumed that the amplitude of fixed sequence program is 1, then the amplitude of signaling sequence is
In addition, in other examples, if the impermanent mould of fixed sequence program and signaling sequence, amplitude coefficient is calculated more
Complexity, but average power ratio demand may be implemented, which is not described herein again.
As described in step S13, the fixed sequence program and signaling sequence are filled to effective subcarrier, and the fixed sequence
It is arranged between column and signaling sequence in oem character set.
In one preferred embodiment, the equal length of the length of the fixed sequence program and the signaling sequence, and
The length is less than the 1/2 of the predetermined length.Wherein, the predetermined length is 1024, but can also be according to being in practical application
System demand and change.
By taking predetermined length is 1024 as an example, if the length of fixed sequence program is that N (carries effective subcarrier of fixed sequence program
Number be N), the length of signaling sequence be M (i.e. the number of effective subcarrier of carrier signaling sequence is M), in the present embodiment
In, M=N.In other embodiments, N can also be slightly larger than M.
Between the fixed sequence program and signaling sequence in oem character set arrange, i.e., fixed sequence program fill to even subcarrier (or
Odd subcarrier) on position, correspondingly, signaling sequence is filled to odd subcarrier (or even subcarrier) position, thus in frequency domain
The distribution of fixed sequence program and the arrangement of signaling sequence oem character set is presented on effective subcarrier.It should be noted that when fixing
When sequence and the inconsistent length of signaling sequence (such as M > N), it can be realized by way of zero padding sequence subcarrier solid
Sequencing column and the arrangement of signaling sequence oem character set.
As described in step S14, null sequence subcarrier is filled respectively in effective subcarrier two sides to form predetermined length
Frequency-domain OFDM symbol.
In a preferred embodiment, this step includes: to fill the zero of equal length respectively in effective subcarrier two sides
Sequence subcarrier is to form the frequency-domain OFDM symbol of predetermined length.
Along the example for being 1024 to predetermined length, the G=1024-M-N of the length of null sequence subcarrier, two sides filling
(1024-M-N)/2 null sequence subcarrier.
Further, in order to guarantee that receiving end can still be located within the scope of -500kHz to 500kHz in carrier frequency offset
Reason receives signal, and the value of (1024-M-N)/2 is typically larger than critical length value (being set as TH), and the critical length value is by system symbol
Rate and predetermined length determine.For example, system symbol rate of the predetermined length for 1024,7.61M, the sample rate of 9.14M, then For example, M=N=353, then G=318, two sides are respectively filled
159 null sequence subcarriers.
Therefore, subcarrier (i.e. frequency-domain OFDM symbol) P1_X of predetermined length (1024)0,P1_X1,…,P1_X1023By
Following manner filling generates:
Wherein, fixed sequence program subcarrierSignaling sequence subcarrierLocating odd even position can be interchanged.
Although the invention has been described by way of example and in terms of the preferred embodiments, but it is not for limiting the present invention, any this field
Technical staff without departing from the spirit and scope of the present invention, may be by the methods and technical content of the disclosure above to this
Inventive technique scheme makes possible variation and modification, therefore, anything that does not depart from the technical scheme of the invention, according to this
The technical spirit of invention any simple modifications, equivalents, and modifications to the above embodiments, belong to skill of the present invention
The protection scope of art scheme.
Claims (28)
1. the generation method of leading symbol in a kind of physical frame, which comprises the steps of:
Inverse discrete fourier transform is made to obtain time-domain OFDM symbol to the frequency-domain OFDM symbol of predetermined length;
The time-domain OFDM symbol of circulating prefix-length is intercepted as cyclic prefix from the time-domain OFDM symbol;
The time-domain OFDM symbol of the circulating prefix-length based on above-mentioned interception generates modulated signal;
Leading symbol is generated based on the cyclic prefix, the time-domain OFDM symbol and the modulated signal, wherein the circulation
Prefix length is the multipalh length that confrontation is usually required according to wireless broadcast communication system, system can obtain in minimum threshold level
To any one or more of factor of bit number for transmitting signaling needed for the minimum length of robust correlation peak and spatial structure
It determines,
The various combination of the circulating prefix-length and modulated signal length is selected, so that finally formed leading symbol is by upper
Various combination is stated to transmit signaling information.
2. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that the circulating prefix-length
It is the bit number of transmission signaling according to needed for spatial structure because usually determining.
3. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that the circulating prefix-length
Equal to or less than the predetermined length.
4. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that described to be based on above-mentioned interception
The circulating prefix-length time-domain OFDM symbol generate modulated signal include:
One frequency deviation sequence is set;
The time-domain OFDM symbol of the time-domain OFDM symbol of the circulating prefix-length or the part circulating prefix-length is multiplied
With the frequency deviation sequence to obtain the modulated signal.
5. the generation method of leading symbol in physical frame as claimed in claim 4, which is characterized in that the frequency of the frequency deviation sequence
Bias is determined according to the corresponding subcarrier in frequency domain interval of time-domain OFDM symbol or according to modulated signal length.
6. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that described to be based on the circulation
Prefix, the time-domain OFDM symbol and the modulated signal generate leading symbol
The cyclic prefix is spliced and is spelled in the front of the time-domain OFDM symbol as protection interval, and by the modulated signal
It connects at the rear portion of the OFDM symbol as frequency modulation part to generate leading symbol.
7. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that the selection circulation
The various combination of prefix length and modulated signal length, so that finally formed leading symbol is transmitted by above-mentioned various combination
Signaling information includes:
Determine the bit number N for the signaling information of being transmitted;
Choose 2NThe various combination of a circulating prefix-length and modulated signal length, so that finally formed leading symbol is by upper
State 2NA various combination transmits signaling information.
8. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that from the time domain OFDM
Before the time-domain OFDM symbol of symbol interception circulating prefix-length is as cyclic prefix further include:
Determine the combination of a kind of circulating prefix-length and modulated signal length;
In the time-domain OFDM symbol for intercepting the circulating prefix-length, different initial positions is selected to intercept the modulated signal
The time-domain OFDM symbol of length generates modulated signal, so that finally formed leading symbol passes through the different initial position
To transmit signaling information.
9. the generation method of leading symbol in physical frame as claimed in claim 1 or 8, which is characterized in that the signaling information
EAS_flag, transmitter flag information TXID, hook information or other transmission ginsengs are identified including emergency alarm or broadcast system
Number.
10. the generation method of leading symbol in physical frame as claimed in claim 1 or 8, which is characterized in that the modulated signal
Length is that can obtain the minimum length of robust correlation peak in minimum threshold level according to system to determine.
11. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that the predetermined length is
1024。
12. the generation method of leading symbol in physical frame as described in claim 1, which is characterized in that described to pre- fixed length
It further includes before following steps that the frequency-domain OFDM symbol of degree, which makees inverse discrete fourier transform to obtain time-domain OFDM symbol:
Determine the average power ratio of fixed sequence program and signaling sequence;
Fixed sequence program and signaling sequence are generated respectively on frequency domain according to the average power ratio;
Fixed sequence program and signaling sequence are filled to effective subcarrier, and are in odd even between the fixed sequence program and signaling sequence
It is staggered;
Fill null sequence subcarrier respectively in effective subcarrier two sides to form the frequency-domain OFDM symbol of predetermined length.
13. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that generate letter on frequency domain
The sequence is enabled to include:
Determine the length, number and amplitude of signaling sequence;
Length and number based on the signaling sequence determine that CAZAC sequence generates the root value in formula;Wherein, signaling sequence
Length be less than or equal to root value, and root value is more than or equal to twice of number of signaling sequence;
Different q values is selected to generate CAZAC sequence, wherein the number of q value is equal to the number of signaling sequence, and any two q value
The sum of be not equal to root value;And generated CAZAC sequence is needed by cyclic shift, the digit of cyclic shift is by corresponding
Root value and q value determine;
Signaling sequence needed for being chosen from all CAZAC sequences according to the number of identified signaling sequence.
14. the generation method of leading symbol in physical frame as claimed in claim 13, which is characterized in that the signaling sequence
Length is 353, the number of signaling sequence is 128, root value is 353;
The value of q value is following all numerical value:
1,9,10,16,18,21,28,29,32,35,49,51,53,54,55,57,59,60,61,65,68,70,74,75,76,
77,78,82,84,85,86,88,90,95,96,103,113,120,123,125,126,133,134,135,137,138,
140,141,142,145,147,148,150,151,155,156,157,161,163,165,167,170,176,178,179,
181,182,184,185,187,194,200,201,204,209,210,217,222,223,224,225,229,232,234,
235,237,239,241,244,246,247,248,249,251,252,253,254,255,262,270,272,273,280,
282,290,291,306,307,308,309,311,313,314,315,317,320,326,327,330,331,333,336,
338,340,342,345,347,349;
The digit of cyclic shift is following all numerical value:
105,244,172,249,280,251,293,234,178,11,63,217,83,111,282,57,85,134,190,
190,99,180,38,191,22,254,186,308,178,251,277,261,44,271,265,298,328,282,155,
284,303,113,315,299,166,342,133,115,225,13,26,326,148,195,145,185,121,58,162,
118,151,182,230,39,249,305,309,144,188,181,265,140,212,137,10,298,122,281,
181,267,178,187,177,352,4,353,269,38,342,288,277,88,124,120,162,204,174,294,
166,157,56,334,110,183,131,171,166,321,96,37,261,155,34,149,156,267,332,93,
348,300,245,101,186,117,329,352,215,55.
15. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that generate letter on frequency domain
The sequence is enabled to include:
Determine the length, number and amplitude of signaling sequence;
Length and number based on the signaling sequence determine that CAZAC sequence generates several root values in formula;Wherein, signaling
The length of sequence be less than or equal to several selected root values in minimum value, and several selected root values it
With twice of the number for being more than or equal to signaling sequence;
For each root value, different q values is selected to generate CAZAC sequence, wherein the number of q value is less than or equal to corresponding
Root value 1/2, and the sum of any two q value be not equal to corresponding root value;And generated CAZAC sequence need by
The digit of cyclic shift, cyclic shift is determined by corresponding root value and q value;
Signaling sequence needed for being chosen from each obtained CAZAC sequence according to the number of identified signaling sequence.
16. the generation method of leading symbol in physical frame as claimed in claim 15, which is characterized in that be directed to each root
Value selects the number of q value different, and the number summation of these q values is equal to the number of signaling sequence.
17. the generation method of leading symbol in physical frame as claimed in claim 15, which is characterized in that in several root values
A root value be chosen for the length of signaling sequence.
18. the generation method of leading symbol in physical frame as claimed in claim 17, which is characterized in that described according to determining
The length of signaling sequence the signaling sequence is chosen from each obtained CAZAC sequence includes: according to being chosen for signaling
CAZAC sequence caused by the root value of the length of sequence determines the signaling sequence.
19. the generation method of leading symbol in the physical frame as described in claim 13 or 15, which is characterized in that the root value
For prime number.
20. the generation method of leading symbol in physical frame as claimed in claim 14, which is characterized in that the fixed sequence program
Generation is that the signaling sequence based on generation is calculated.
21. the generation method of leading symbol in physical frame as claimed in claim 20, which is characterized in that the fixed sequence program
Are as follows:
Wherein, ωnValue it is as follows by rows from left to right in order:
5.43,2.56,0.71,0.06,2.72,0.77,1.49,6.06,4.82,2.10,5.62,4.96,4.93,4.84,
4.67,5.86,5.74,3.54,2.50,3.75,0.86,1.44,3.83,4.08,5.83,1.47,0.77,1.29,0.16,
1.38,4.38,2.52,3.42,3.46,4.39,0.61,4.02,1.26,2.93,3.84,3.81,6.21,3.80,0.69,
5.80,4.28,1.73,3.34,3.08,5.85,1.39,0.25,1.28,5.14,5.54,2.38,6.20,3.05,4.37,
5.41,2.23,0.49,5.12,6.26,3.00,2.60,3.89,5.47,4.83,4.17,3.36,2.63,3.94,5.13,
3.71,5.89,0.94,1.38,1.88,0.13,0.27,4.90,4.89,5.50,3.02,1.94,2.93,6.12,5.47,
6.04,1.14,5.52,2.01,1.08,2.79,0.74,2.30,0.85,0.58,2.25,5.25,0.23,6.01,2.66,
2.48,2.79,4.06,1.09,2.48,2.39,5.39,0.61,6.25,2.62,5.36,3.10,1.56,0.91,0.08,
2.52,5.53,3.62,2.90,5.64,3.18,2.36,2.08,6.00,2.69,1.35,5.39,3.54,2.01,4.88,
3.08,0.76,2.13,3.26,2.28,1.32,5.00,3.74,1.82,5.78,2.28,2.44,4.57,1.48,2.48,
1.52,2.70,5.61,3.06,1.07,4.54,4.10,0.09,2.11,0.10,3.18,3.42,2.10,3.50,4.65,
2.18,1.77,4.72,5.71,1.48,2.50,4.89,4.04,6.12,4.28,1.08,2.90,0.24,4.02,1.29,
3.61,4.36,6.00,2.45,5.49,1.02,0.85,5.58,2.43,0.83,0.65,1.95,0.79,5.45,1.94,
0.31,0.12,3.25,3.75,2.35,0.73,0.20,6.05,2.98,4.70,0.69,5.97,0.92,2.65,4.17,
5.71,1.54,2.84,0.98,1.47,6.18,4.52,4.44,0.44,1.62,6.09,5.86,2.74,3.27,3.28,
0.55,5.46,0.24,5.12,3.09,4.66,4.78,0.39,1.63,1.20,5.26,0.92,5.98,0.78,1.79,
0.75,4.45,1.41,2.56,2.55,1.79,2.54,5.88,1.52,5.04,1.53,5.53,5.93,5.36,5.17,
0.99,2.07,3.57,3.67,2.61,1.72,2.83,0.86,3.16,0.55,5.99,2.06,1.90,0.60,0.05,
4.01,6.15,0.10,0.26,2.89,3.12,3.14,0.11,0.11,3.97,5.15,4.38,2.08,1.27,1.17,
0.42,3.47,3.86,2.17,5.07,5.33,2.63,3.20,3.39,3.21,4.58,4.66,2.69,4.67,2.35,
2.44,0.46,4.26,3.63,2.62,3.35,0.84,3.89,4.17,1.77,1.47,2.03,0.88,1.93,0.80,
3.94,4.70,6.12,4.27,0.31,4.85,0.27,0.51,2.70,1.69,2.18,1.95,0.02,1.91,3.13,
2.27,5.39,5.45,5.45,1.39,2.85,1.41,0.36,4.34,2.44,1.60,5.70,2.60,3.41,1.84,
5.79,0.69,2.59,1.14,5.28,3.72,5.55,4.92,2.64.
22. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that the fixed sequence program
The equal length of length and the signaling sequence, and the length is less than the 1/2 of the predetermined length.
23. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that in effective sub- load
It includes: in effective subcarrier two that null sequence subcarrier is filled respectively to form the frequency-domain OFDM symbol of predetermined length in wave two sides
Fill the null sequence subcarrier of equal length respectively to form the frequency-domain OFDM symbol of predetermined length in side.
24. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that the zero sequence of every side filling
The length of column subcarrier is greater than critical length value, which is determined by systematic sampling rate, symbol rate and predetermined length.
25. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that the fixed sequence program and
Signaling sequence is permanent mode sequence.
26. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that the fixed sequence program and
The mean power of signaling sequence is same or different.
27. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that the fixed sequence program and
The average power ratio of signaling sequence is according to whole inclined estimation performance, channel estimating performance, Xie Xinling performance and Timing Synchronization performance
Balanced consider and determine.
28. the generation method of leading symbol in physical frame as claimed in claim 12, which is characterized in that the fixed sequence program and
The average power ratio of signaling sequence is 1:1 or 3:2 or 2:1 or 3:1.
Priority Applications (44)
Application Number | Priority Date | Filing Date | Title |
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CN201410229558.7A CN105323048B (en) | 2014-05-28 | 2014-05-28 | The generation method of leading symbol in physical frame |
CN201611099582.9A CN106713208B (en) | 2014-05-28 | 2014-05-28 | Method for generating preamble symbol in physical frame |
CN201910362874.4A CN110190938B (en) | 2014-05-28 | 2014-05-28 | Method for generating preamble symbol in physical frame |
CN201611106688.7A CN106534032A (en) | 2014-05-28 | 2014-05-28 | Method for generating frequency domain OFDM symbol |
CN201611106330.4A CN106789810A (en) | 2014-05-28 | 2014-05-28 | The generation method of leading symbol in physical frame |
CN201611199976.1A CN106998312B (en) | 2014-04-16 | 2015-02-06 | Preamble symbol receiving method |
KR1020197038044A KR102196222B1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
KR1020207036622A KR102347011B1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
US15/304,854 US10778484B2 (en) | 2014-04-16 | 2015-04-16 | Preamble symbol transmitting method and device, and preamble symbol receiving method and device |
CA3212005A CA3212005A1 (en) | 2014-04-16 | 2015-04-16 | Preamble symbol generation and receiving method, and frequency-domain symbol generation method and device |
KR1020167032058A KR102033742B1 (en) | 2014-04-16 | 2015-04-16 | Method and apparatus for receiving preamble symbol |
KR1020167032057A KR101975551B1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
KR1020197018441A KR102114352B1 (en) | 2014-04-16 | 2015-04-16 | Method and apparatus for receiving preamble symbol |
KR1020197012400A KR102108291B1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
PCT/CN2015/076812 WO2015158293A1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
CA2945858A CA2945858C (en) | 2014-04-16 | 2015-04-16 | Preamble symbol receiving method and device |
US15/304,853 US10411929B2 (en) | 2014-04-05 | 2015-04-16 | Preamble symbol receiving method and device |
US15/304,851 US11071072B2 (en) | 2014-04-16 | 2015-04-16 | Preamble symbol receiving method and device |
PCT/CN2015/076808 WO2015158292A1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
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US15/304,857 US10148476B2 (en) | 2014-04-05 | 2015-04-16 | Preamble symbol generation and receiving method, and frequency-domain symbol generation method and device |
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PCT/CN2015/076813 WO2015158294A1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
KR1020207035510A KR102234307B1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
KR1020197033488A KR102191859B1 (en) | 2014-04-16 | 2015-04-16 | Method for generating preamble symbol, method for receiving preamble symbol, method for generating frequency domain symbol, and apparatuses |
US16/172,662 US11201770B2 (en) | 2014-04-16 | 2018-10-26 | Preamble symbol generation and receiving method, and frequency-domain symbol generation method and device |
US16/172,727 US11025465B2 (en) | 2014-04-16 | 2018-10-27 | Preamble symbol receiving method and device |
US16/726,928 US10958494B2 (en) | 2014-04-16 | 2019-12-26 | Preamble symbol receiving method and device |
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US16/992,038 US11088884B2 (en) | 2014-04-16 | 2020-08-12 | Preamble symbol generation and receiving method, and frequency-domain symbol generation method and device |
US16/992,039 US11082274B2 (en) | 2014-04-16 | 2020-08-12 | Preamble symbol generation and receiving method, and frequency-domain symbol generation method and device |
US16/992,040 US11128504B2 (en) | 2014-04-16 | 2020-08-12 | Preamble symbol generation and receiving method, and frequency-domain symbol generation method and device |
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KR102642932B1 (en) | 2014-08-07 | 2024-03-05 | 원 미디어, 엘엘씨 | Method for dynamic configuration of a flexible orthogonal frequency division multiplexing phy transport data frame |
MX2017001613A (en) | 2014-08-07 | 2018-01-24 | Coherent Logix Inc | Multi-partition radio frames. |
CA3194847A1 (en) | 2014-08-25 | 2016-03-03 | ONE Media, LLC | Dynamic configuration of a flexible orthogonal frequency division multiplexing phy transport data frame preamble |
KR102342727B1 (en) | 2015-03-09 | 2021-12-24 | 원 미디어, 엘엘씨 | System discovery and signaling |
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CN106713208A (en) | 2017-05-24 |
CN106713208B (en) | 2020-04-17 |
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