CN1801628A - Data modulation, modulation method and device,code array method - Google Patents

Abstract

In a data demodulating method and apparatus, and a code arranging method, a multiplexer multiplexes an input data stream divided by a predetermined length into a plurality of types of pseudo random data streams using multiplexed information of predetermined bits by applying a predetermined multiplexing method to each of the pseudo random data streams. An encoder RLL-modulates the plurality of types of pseudo random data streams to create a modulated code stream including a minimum of DC components. The multiplexer generates the random data streams by inconsecutively scrambling the input data stream using the multiplexed information. The encoder weak DC-free RLL-modulates each of the multiplexed data streams without using a DC control sub code conversion table to which additional bits are added and provides a code stream including a minimum of DC components among multiplexed, RLL-modulated code streams.

Description

Data-modulated, demodulation method and equipment, and code aligning method

The application is that to submit to day be that September 27, application number in 2003 are 03165025.2, are entitled as the dividing an application of patent application of " data-modulated, demodulation method and equipment, and code aligning method ".

Priority

The application require respectively on September 27th, 2002 and on October 17th, 2002 in the korean patent application 2002-58809 of Korea S Department of Intellectual Property submission and the priority of 2002-63534, comprise its full content herein as a reference.

Technical field

The present invention relates to data-modulated and demodulation field, the invention particularly relates to data modulation method and equipment, data demodulation method and equipment and code aligning method, the modulation code error propagation probability that provides reduces, code efficiency is high and have DC suppresses ability.

Background technology

The multi-mode coding method provides the DC to there not being DC to suppress the modulation code of ability to suppress ability.In the multi-mode coding method, will add a position information and be inserted into input traffic, produce 2 according to additional a position information ^aRandom data stream, though this 2 ^aWhen carrying out the modulation do not have DC to suppress ability in the random data stream, also select to comprise in the data flow after the modulation of minimum DC component, so modulation back data flow has DC to suppress ability.

United States Patent (USP) 6,225,921 disclose " be used for the corresponding m-bit channel word of n-potential source word code/be decoded into; and m-bit channel word coding/decoding is become the device of corresponding n-potential source word ", wherein, code (d=1, k=7, m=2, n=3) redundancy is about 2%, and its encoding rate R is R=49/75=0.6533, its code efficiency R/C (d, k) be R/C (d, k)=0.6533/0.6793=96.2%.For convenience, at United States Patent (USP) 6,225, the modulation code that uses in 921 is called the A-code.

United States Patent (USP) 6,281, " method, modulator approach, demodulation method and the demodulated equipment thereof that distribute the RLL sign indicating number that DC inhibition ability strengthened " 815 disclosed, wherein, as code (d=1, k=8, n=12) redundancy is about 2%, and its encoding rate R is R=32/49=0.6531, its code efficiency R/C (d, k) be R/C (d, k)=0.6531/0.6853=95.3%.For convenience, at United States Patent (USP) 6,281, the modulation code that uses in 815 is called the B-code.Here, " C " refers to depend on the ability of " d " and " k ".

At Kees A.Schouhamer Immink, Shannon Foundation Publishers, chapter13 is in the controlled scramble method that 1999 " being used for the mass data storage system " describes, when 4 of redundancy being inserted in per 25 bytes of data, with these data RLL (1,7) modulation, encoding rate R is R=200/306=0.6536, code efficiency R/C (d, k) be R/C (d, k)=0.6536/0.6793=96.2%.The modulation code that uses in above-mentioned document is called the C-code.

Encoding rate in the above-mentioned conventional modulated method is similar,, in the scope of 95.3%-96.2%, has shown among Fig. 1 that the DC of expression A-code, B-code and C-code suppresses power spectrum density (PSD) curve of ability that is.

Yet in above-mentioned document in the disclosed multi-mode coding method, the frequency that data flow is become the utilization of the required additional information of random data should be increased to be had enough DC and suppresses ability.And even developed the higher modulation technique of code efficiency, DC suppresses ability also may be not enough.For example,, when disclosed B-code does not comprise redundant digit in 815, can suppress DC, still, not have under the situation of extra order, can not have enough DC to suppress ability when United States Patent (USP) 6,281.After this, can just suppress DC, suppress the weak code of ability when still not having redundant digit and be called weak no DC modulation code without redundant digit.

Fig. 2 shows the traditional multichannel multiplexing method that input traffic is converted to random data.In Korean Patent 1999-703183, disclose traditional multichannel multiplexing method, used this method,, input traffic has been converted to 2 by with adding a position information to the continuous scramble of input traffic ^aRandom data stream, this patent are by SANYO DENKI CO., and LTD submits to, is entitled as " digital modulation circuit, Ditital modulation method, digital demodulating circuit and digital demodulation method ".

Among Fig. 2, with the distance device to multiplexed information s _tWith the x of code modulated unit _{I, o}To x _{I, u-1}Carry out nonequivalence operation, with predetermined bit data x _{I, o}To x _{I, u-1}The input traffic of forming (being called code modulated unit) is converted to random data stream

In other words, by first code being modulated the x of unit with the distance device _{I, o}And primary data (multiplexed information) s _tCarry out nonequivalence operation, with the x of the first code unit of modulation _{I, o}Be converted to data y ^t _{I, o}By to the conversion after data y ^t _{I, o}With the x of code modulated unit _{I, 1}Carry out nonequivalence operation, with next x of code modulated unit _{I, 1}Be converted to data y ^t _{I, 1}Thereafter, data after the conversion of previous code modulated unit are repeated nonequivalence operation with the code modulated unit that will change, up to data input stream The last x of code modulated unit _{I, u-1}, so that produce data after the conversion of each code modulated unit.

Fig. 3 show with input traffic according to multichannel multiplexing method shown in Figure 2 be converted to random data, restriction run length (RLL) is modulated, records on the medium and during from storage medium playback, flow through RLL The invert stream of demodulation

During the inverting of data, except the RLL stream of inverting

The first demodulation code unit (multiplexed information st) and just outside the demodulation code unit (primary data or the demodulation code unit of not inverting) before requiring contrary demodulation code unit, repeat stream after nonequivalence operation produces demodulation by each being required contrary demodulation code unit

In other words, by to first y of demodulation code unit ^t _{I, o}And primary data (multiplexed information) s _tCarry out nonequivalence operation, with first y of demodulation code unit ^t _{I, o}Invert and be data x _{I, o}Below, by to first y of demodulation code unit that do not invert ^t _{I, o}With the y of demodulation code element ^t _{I, 1}Carry out nonequivalence operation, with the y of demodulation code unit ^t _{I, 1}Invert and be data x _{I, 1}Thereafter, to requiring contrary demodulation code unit and the just repetition of the demodulation code unit before requiring contrary demodulation code unit nonequivalence operation, flow up to RLL

Last demodulation code unit so that produce the data of inverting of each demodulation code unit.

As mentioned above, during the inverting of data, in the inverting of demodulation code unit, use a demodulation code unit of not inverting.Like this, when mistake occurring in requiring contrary demodulation code unit, this mistake also influences ensuing demodulation code unit.For example, as the y of demodulation code unit that do not invert ^T* _{I, u-3}When wrong, this erroneous effects data x that inverts ^* _{I, u-3}With ensuing data x ^* _{I, u-2}

Correspondingly, in the prior art, when RLL stream

When wrong, error propagation is to the data x that separates scramble ^* _{I, u-3}With ensuing data x ^* _{I, u-2}Error propagation is the general characteristic that utilizes the multi-mode coding method of scramble.

Summary of the invention

The invention provides a kind of data modulation method and equipment,, provide to have the efficient modulation code that higher DC suppresses ability by keeping the DC described in above-mentioned 3 references to suppress ability and the multi-mode coding method being applied to weak no DC modulation code.

The present invention also provides a kind of data modulation method and equipment and data demodulation method and equipment, so that reduce the possibility of error propagation.

The present invention also provides a kind of data modulation method and equipment and data demodulation method and equipment, adopts by keeping DC to suppress ability and interrupted scramble input data, produces the multichannel multiplexing method of pseudo-random data stream.

The present invention also provides and has satisfied a by generation (d, even k) code word of constraints is arranged weak no DC modulation code, arranges the method for code word then, thereby according to the border regularly arranged code word during the arrangement code stream time, also keeps the initial characteristic of code stream.

According to an aspect of the present invention, data modulation method is modulated to the n-position with the m-bit data (code word of n 〉=m), here, just minimum run length is defined as " d " and maximum run length is defined as " k ".Divide input traffic by predetermined length, according to the predetermined multichannel multiplexing method multiplexed input traffic of multiplexed information, so that multiplexed data flow is provided.Multiplexed data flow is weak no DC restriction run length (RLL)-modulation, does not comprise the DC control routine conversion table of the separation of extra order, then, is provided at the code stream that has minimum DC component in the code stream multiplexed, that RLL modulates.

According to a further aspect in the invention, data modulation method is that (code word of n 〉=m) here, is defined as minimum run length " d " and maximum run length is defined as " k " in the n-position with m-potential source data-modulated.By each pseudo-random data stream is used predetermined multichannel multiplexing method, will be multiplexed as polytype pseudo-random data stream by the input traffic of predetermined length division with the multiplexed information of pre-determined bit.These polytype pseudo-random data stream are carried out RLL modulation, carried out code stream after the modulation that best DC suppresses so that produce.

According to another aspect of the invention, data modulation method is that (code word of n 〉=m) here, is defined as minimum run length " d " and maximum run length is defined as " k " in the n-position with m-potential source data-modulated.By each pseudo-random data stream is used predetermined multichannel multiplexing method, will be multiplexed as polytype pseudo-random data stream by the input traffic that predetermined length is divided with the pre-determined bit multiplexed information.Multiplexed data flow is weak no DC RLL modulation, does not utilize the DC control routine conversion table that comprises extra order, and is provided at the code stream that comprises minimum DC component in the code stream multiplexed, the RLL modulation.

According to of the present invention also on the one hand, data demodulation method is demodulated into the m position with the input digital data of n position, and (the demodulation code unit of n 〉=m) has the data flow of not inverting of predetermined length so that produce.With multiplexed information this data flow of not inverting is separated scramble discontinuously, so that produce the data flow of inverting.

According to also one side of the present invention, be that (n 〉=m) method of code word is defined as 1 with minimum run length restriction " d ", and maximum run length restriction " k " is defined as 7 in the n position with m potential source data arrangement.When code word a is connected to code word b, code word a is previous code word, from code word b1 and b2, select code word b, the code stream that wherein code word a is connected to code word b1 is X1, the code stream that wherein code word a is connected to code word b2 is X2, arrange code word b1 and b2, with have figure place according to the value in the code word " 1 " be very or idol predict the reverse link parameter INV of the transformation of next code.When code word a is connected to code word b1 or b2, though according to the border rule with code word a, b1 or b2 are modulated into the code word of another type,, arrange code stream X1 and X2 to have reverse link parameter INV.

Also on the one hand equipment is by being defined as minimum run length " d " and maximum run length is defined as " k " according to of the present invention, and m-potential source data-modulated is become the n-position, and (code word of n 〉=m) is so that improve DC inhibition ability.This equipment comprises: multiplexer, with the input data multiplex of multiplexed information, so that multiplexed data stream is provided to dividing by predetermined length; And encoder, need not add the DC control subcode conversion table of extra order, this multiplexed data stream is carried out weak no DC RLL modulation; And selector, selection comprises the code stream of minimum DC component in code stream multiplexed, the RLL modulation.

According to of the present invention also on the one hand, data modulating device is that (code word of n 〉=m) here, is defined as minimum run length " d " and maximum run length is defined as " k " in the n-position with m-potential source data-modulated.Data modulating device comprises: multiplexer, by predetermined multichannel multiplexing method is applied to each pseudo-random data stream, with the multiplexed information of pre-determined bit, will be multiplexed as polytype pseudo-random data stream by the input traffic that predetermined length is divided; And encoder, these polytype pseudo-random data stream are carried out RLL modulation, wherein carried out code stream after the modulation that best DC suppresses so that produce.

According to of the present invention also on the one hand, data modulating device is that (code word of n 〉=m) here, is defined as minimum run length " d " and maximum run length is defined as " k " in the n-position with m-potential source data-modulated.Data modulating device comprises: multiplexer, by predetermined multichannel multiplexing method is applied to each pseudo-random data stream, with the multiplexed information of pre-determined bit, will be multiplexed as polytype pseudo-random data stream by the input traffic that predetermined length is divided; And encoder, need not add the DC control subcode conversion table of extra order, this multiplexed data stream is carried out weak no DC RLL modulation; And selector, selection comprises the code stream of minimum DC component in code stream multiplexed, the RLL modulation.

According to of the present invention also on the one hand, data demodulates equipment comprises: decoder, the input digital data of each n position is demodulated into the m-position, and (the demodulation code unit of n 〉=m) has the data flow of not inverting of predetermined length so that produce; And demultiplexer, separate scramble with the multiplexed information data flow of discontinuously this not being inverted, so that produce the data flow of inverting.

Can realize the operation of method of the present invention with the computer executable instructions of computer-readable media.

Explain all the other aspects of the present invention and advantage in the following description, in description, can partly understand aspect these and advantage, also can in practice of the present invention, learn.

Description of drawings

In conjunction with the accompanying drawings, these and/or others of the present invention and advantage will become obviously, also can be easier to understand from following description to embodiment:

Fig. 1 shows power spectrum density (PSD) curve of conventional code;

Fig. 2 shows traditional multichannel multiplexing method;

Fig. 3 shows the error propagation characteristic when reproducing with the represented traditional multichannel multiplexing method data converted of Fig. 2;

Fig. 4 is the block diagram of the data modulating device of an aspect according to an embodiment of the invention;

Fig. 5 shows the multichannel multiplexing method of the pseudo-scramble of utilizing the multiplexer that is applied to Fig. 4;

Fig. 6 shows the error propagation characteristic when reproducing with the represented traditional multichannel multiplexing method data converted of Fig. 5;

Fig. 7 shows the PSD curve, shows that the DC in the data modulation method of an aspect according to an embodiment of the invention suppresses ability;

Fig. 8 has shown primary key group's code word characteristic;

Fig. 9 has shown the auxiliary code group's who is used for DC control code word characteristic;

Figure 10 has shown next code group ncg definite according to the quantity EZ of ended zero;

Figure 11 shows run-length restriction (RLL) condition when just code word a is connected to code word b;

Parameter I NV when Figure 12 has shown the RLL condition that does not satisfy Figure 11 before and after the code conversion changes;

Figure 13 shows the example that the code stream that caused by code word b1 that is used for DC control and b2 is dispersed;

Figure 14 has shown the multiplexed information that is converted to multiplexed ID in synchronizing signal and multiplexed ID inserter shown in Figure 4;

Figure 15 A has shown the main code conversion table that produces and arrange when considering above-mentioned condition to 15E;

Figure 16 has shown the subcode conversion table that is used for DC control that produces when considering above-mentioned condition and arrange;

Figure 17 shows the PSD curve of the RLL of an aspect (1,7) sign indicating number according to an embodiment of the invention;

Figure 18 has shown the packing density and the record efficiency of RLL (1,7) sign indicating number according to an embodiment of the invention, and the packing density and the record efficiency of A-code, B-code and C-code;

Figure 19 shows the PSD curve of the RLL of an aspect (2,10) sign indicating number according to an embodiment of the invention; With

Figure 20 has shown packing density and the record efficiency of RLL (2,10), and existing 8-14 modulation adds the packing density and the record efficiency of (EFMP) sign indicating number.

Embodiment

Now, with reference to these embodiment of the present invention, the example has been described in the accompanying drawings in detail, wherein, similar label is all represented similar assembly.Describe these embodiment hereinafter, purpose is by explaining the present invention with reference to the accompanying drawings.

Fig. 4 is the block diagram of data modulating device according to an embodiment of the invention.With reference to figure 4, can express input traffic as equation 1, and as in the equation 2, divide with vXu briquet cutting appts. 10.In other words, (=k) data flow promptly, is v data flow of u byte long input traffic to be divided into vXu.

x＝(x ₀，x ₁，...，x _k-1，...，x _1-1) ......(1)

$B_x=\left[\begin{array}{c}{x}_{\mathrm{0,0}},x_{\mathrm{0,1}},...,x_{0,u-1}\\ x_{\mathrm{1,0}},x_{\mathrm{1,1}},...,x_{1,u-1}\\ ...\\ x_{i,0},x_{i,1},...x_{i,j},...,x_{i,u-1}\\ x_{v-\mathrm{1,0}},x_{v-\mathrm{1,1}},...,x_{v-1,u-1}\end{array}\right]=\left[\begin{array}{c}\underset{\&OverBar;}{{\mathrm{<figure-callout\; id="0"\; label="y"\; filenames="A200610000506.800271.png,A200610000506.800331.png"\; state="\{\{state\}\}">y</figure-callout>}}_0}\\ \underset{\&OverBar;}{{\mathrm{<figure-callout\; id="1"\; label="y"\; filenames="A200610000506.800271.png,A200610000506.800281.png"\; state="\{\{state\}\}">y</figure-callout>}}_1}\\ ...\\ \underset{\&OverBar;}{y_i}\\ ...\\ \underset{\&OverBar;}{y_{v-1}}\end{array}\right]---\left(2\right)$

Here, x _{I, j}=x _Ixu+j

The multiplexer 20 that utilizes pseudo-scramble is by adding a position information to each vXu data flow, and each the vXu data stream multiplexing that will be divided by vXu briquet cutting appts. 10 is L=2 ^aIndividual data flow is then according to the multiplexed information s that is added, with L=2 ^aData flow is converted to pseudo-random data.Data flow with the u byte length

Be multiplexed as and contain 2 of different content ^aThe u byte data is shown in equation 3 and 4.

$\underset{\&OverBar;}{C_y}=\left(\underset{\&OverBar;}{{\mathrm{<figure-callout\; id="0"\; label="C"\; filenames="A200610000506.800271.png,A200610000506.800331.png"\; state="\{\{state\}\}">C</figure-callout>}}_0},\underset{\&OverBar;}{{\mathrm{<figure-callout\; id="1"\; label="C"\; filenames="A200610000506.800271.png,A200610000506.800281.png"\; state="\{\{state\}\}">C</figure-callout>}}_1},\&CenterDot;\&CenterDot;\&CenterDot;,\underset{\&OverBar;}{C_i},\&CenterDot;\&CenterDot;\&CenterDot;,\underset{\&OverBar;}{C_{v-1}}\right)---\left(3\right)$

$C_i=\left[\begin{array}{c}{\mathrm{<figure-callout\; id="0"\; label="s"\; filenames="A200610000506.800271.png,A200610000506.800331.png"\; state="\{\{state\}\}">s</figure-callout>}}_0,{{\mathrm{<figure-callout\; id="0"\; label="y"\; filenames="A200610000506.800271.png,A200610000506.800331.png"\; state="\{\{state\}\}">y</figure-callout>}}^0}_{i,0},x_{i,1},...,x_{i,q-1},x_{i,q+1},...,{y^0}_{i,p^{*}q},..,x_{i,u-1}\\ {\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A200610000506.800271.png,A200610000506.800281.png"\; state="\{\{state\}\}">s</figure-callout>}}_1,{{\mathrm{<figure-callout\; id="0"\; label="y"\; filenames="A200610000506.800271.png,A200610000506.800331.png"\; state="\{\{state\}\}">y</figure-callout>}}^1}_{i,0},x_{i,1},..,x_{i,q-1},{y^1}_{i,q},x_{i,q+1},...,{y^1}_{i,p^{*}q},..,x_{i,u-1}\\ s_{L-1},{y^{L-1}}_{i,0},x_{i,1},..,x_{i,q-1},{y^{L-1}}_{i,q+1},...,{y^{L-1}}_{i,p^{*}q},..,x_{i,u-1}\end{array}\right]=\left[\begin{array}{c}f(\underset{\&OverBar;}{y_i}/s_0)\\ f(\underset{\&OverBar;}{y_i}/s_1)\\ f(\underset{\&OverBar;}{y_i}/s_{L-1})\end{array}\right]----\left(4\right)$

Wherein, u-1 is the multiple of q, p=0, and 1 ..., r, r are divide equally (share) of (u-1)/q, q refers to scramble index at interval.Function

Refer to multiplexed information s input traffic Be converted to the result of random data.

According to the figure place of the multiplexed information s that is added, synchronizing signal and multiplexed ID inserter 30 can have a plurality of channels (L=2, here ^a).Synchronizing signal and multiplexed ID inserter 30 insert 2 with synchronous mode ^aMultiplexed pseudo-random data stream, the multiplexed pseudo-random data stream of promptly having added multiplexed information s then, is converted to multiplexed ID with multiplexed information s.

According to the multiplexed information that adds, weak no DC rll encoder device 40 can have a plurality of channels (L=2, here ^a), and modulation code is carried out weak no DC RLL modulate.Here, according to the RLL modulation, m-potential source data are converted to the n-bit word, and (n 〉=m), it is subject to minimum run length " d " constraints and maximum run length " k " constraints.

For satisfying the code word of predetermined RLL condition, this code can suppress DC to weak no DC rll encoder device 40 when the additional DC that is comprising extra order suppresses not have redundancy under the absent variable condition of code conversion table with code coding, but has weak DC to suppress ability.Promptly, the RLL (1 of minimum run length d=1 and maximum run length k=7,7,8,12) sign indicating number is grouped into a plurality of code words according to above-mentioned RLL condition with code word, with main code conversion table and subcode conversion table these code words RLL is modulated, arrange code word in the described main code conversion table, make the streams of code words of source word have the DC control performance, described subcode conversion table is used for satisfying the DC control of predetermined RLL condition, and makes by unnecessary code word is shifted out the main code conversion table.

Synchronizing signal and multiplexed ID inserter 30 can be by being defined as 2 with minimum run length " d ", " k " is defined as 7 with maximum run length, multiplexed information is converted to multiplexed ID,, thereby reduces the interference noise of signal so that increase the size in minimum mark or hole.As on the other hand, weak no DC rll encoder device 40 can code, for example, RLL (2,10,8,15) sign indicating number, here, minimum run length restriction " d " is 2, maximum run length restriction " k " is 10.

Comparator and selector 50 are 2 ^aSelect the RLL modulation back stream of DC component minimum number in the stream of RLL modulation back.

Fig. 5 shows the multichannel multiplexing method that utilizes the pseudo-scramble that is applied to multiplexer 20 shown in Figure 4.The present invention with reference to utilize pseudo-scramble discontinuously the method for scramble input data as multichannel multiplexing method.

In utilizing the multichannel multiplexing method of pseudo-scramble, as shown in Figure 2, if mistake appears in Data Position, this mistake just causes the mistake of next data.Correspondingly, if scramble data and do not influence the DC component of code stream discontinuously just can reduce the possibility of error propagation to next data.

Among Fig. 5, by with discontinuous q distance device, to multiplexed information s _tAnd x _{I, 0}To x _{I, u-1}Discontinuous q multiplexed information carry out nonequivalence operation, will comprise x _{I, 0}To x _{I, u-1}The input traffic of u byte long

Be converted to pseudo-random data

As multiplexed information s _tFigure place a be less than or when equaling to import the figure place m of data, use multiplexed information s _tAll input traffics with the u byte long

Multiplexed.Yet, if a＜m, a position of then importing the m position of a position of highest significant position (MSB) of least significant bit (LSB), input data of data or input data has shown and the conversion efficient much at one of pseudo-random data is arrived in all m positions to the conversion of pseudo-random data.

In other words, by first code is modulated the x of unit _{I, 0}And primary data (multiplexed information) s _tCarry out nonequivalence operation, with the x of the first code unit of modulation (first data that will modulate) _{I, 0}Be modulated to data y ^t _{I, 0}Not to the x of code modulated unit _{I, 1}To x _{I, q-1}Carry out nonequivalence operation, like this, the x of code modulated unit _{I, 1}To x _{I, q-1}Export constant.Thereafter, to modulating back data y ^t _{I, 0}The x of code modulated unit with discontinuous q modulation unit _{I, q}Carry out nonequivalence operation, so that produce next modulation back data y ^t _{I, q}Repeat nonequivalence operation up to input traffic

Last discontinuous q modulation unit.

Error propagation characteristic when Fig. 6 shows reproduction according to the pseudo-random data of the multichannel multiplexing method modulation of the pseudo-scramble of the utilization represented among Fig. 5.During data are inverted, data flow

Be the RLL stream with the demodulation of decoder (not shown), described decoder comes demodulated data stream according to the RLL modulator approach of using between modulation period.And structure shown in Figure 6 can be called demultiplexer, and it separates the scramble data of not inverting discontinuously with multiplexed information, so that the back data flow of inverting is provided.

Among Fig. 6, to primary data (multiplexed data s _t) and first y of demodulation code unit ^t _{I, 0}Carry out nonequivalence operation, then, carry out nonequivalence operation to requiring each contrary discontinuous q demodulation code unit and each the demodulation code unit before each q demodulation code unit, so that produce data recovered.

In other words, to first y of demodulation code unit ^t _{I, 0}And primary data (multiplexed data s _t) carry out nonequivalence operation, so that produce the data x that inverts _{I, 0}Not to the x of demodulation code unit _{I, 1}To x _{I, q-1}Carry out nonequivalence operation, and the x of demodulation code unit _{I, 1}To x _{I, q-1}Export constant.Thereafter, to first y of demodulation code unit ^t _{I, 0}The one y of q demodulation code unit of (not inverting) and discontinuous q demodulation code unit ^t _{I, q}Carry out nonequivalence operation, so that produce the data x that inverts _{I, q}Below, repeat nonequivalence operation, up to the data flow of not inverting

Last discontinuous q demodulation code unit.

Correspondingly,, be stored on the medium such as CD, flow as RLL with pseudo-random data RLL modulation From storage medium playback.Then, if only at the RLL stream that is not converted to another categorical data by nonequivalence operation Data x ^* _{I, q+1}In mistake appears, mistake does not just propagate into another data.Error propagation just occurs when only producing mistake in the RLL stream after corresponding to the reproduction of input data, described input data are modulated to the data of another type through nonequivalence operation.

When the multichannel multiplexing method according to the pseudo-scramble of the represented utilization of Fig. 5 is converted to pseudo-random data with data, compare with the multichannel multiplexing method that Fig. 2 is represented, the possibility of error propagation is reduced to 1/q (q is the cycle of nonequivalence operation).Here, should determine that the value of q is to accept the DC ability after the RLL modulation.The possibility of error propagation and DC suppress ability and can reduce with the increase of the value of q.On the contrary, the possibility of error propagation and DC suppress ability can increase along with the reducing of value of q.

Fig. 7 has described the PSD curve, shows that DC suppresses the change of ability along with nonequivalence operation cycle q.The DC that has shown code stream after the modulation of depending on nonequivalence operation cycle q suppresses ability, and wherein, the figure place a of multiplexed information st is 2, and multiplexed length u is 50, and the figure place m of the input data that modulate is 8.To multiplexed information s _t2 of LSB of 2 and 8 input data carry out nonequivalence operations.The PSD curve display nonequivalence operation cycle q when being 1 byte, 5 bytes, 10 bytes, 15 bytes and 20 bytes the DC with the results change of nonequivalence operation suppress ability.From Fig. 7 as seen, though per 5 bytes are carried out nonequivalence operation,, it is almost constant that DC suppresses ability, and the error propagation rate can be reduced to 1/5.

Explain weak according to an embodiment of the invention no DC RLL modulation code now.

Suppress merit rating RLL (d, k, m, n) sign indicating number according to packing density and DC.Here, the m index is according to figure place (also referring to the figure place of source data or the figure place of information word), n refers to modulate the figure place (also being called the channel figure place) of back code word, d refer to can be between " 1 " of code word position continuous 0 minimum number (minimum run length restriction), k refers to the maximum number (maximum run length restriction) of continuous 0 between " 1 " in the code word.Crack, position between the code word is represented by the T corresponding to the cycle of the clock signal of use in record or reproduction.

In modulator approach, can be by reducing number n but do not change minimum run length restriction d and number m increase packing density.Yet the RLL sign indicating number should satisfy minimum run length restriction d and the maximum run length restriction k in the code word.Like this, (d, k) quantity of the code word of condition is 2 to satisfy RLL ^m(m is the figure place of data) or 2 ^mMore than.Yet for reality is used the RLL sign indicating number, the part that code word is connected with code word also should satisfy RLL (d, k) condition, and when the DC of code component influenced the performance of optical recording and/or reproducer, the code word that use should have DC inhibition ability.

In an embodiment of the present invention, produce two types code table, that is, be used for the main code conversion table and the subcode conversion table of DC control, be used for the code word of the source code that will modulate.

The method that produces code word in main code conversion table and the subcode conversion table is described below, and with RLL (1,7) sign indicating number as an example, here, the minimum run length restriction is 1, maximum run length restriction 7.

Fig. 8 illustrates a plurality of code word groups and these code words group's of main conversion code word characteristic.

When the minimum run length restriction is d, the maximum run length restriction is k, the figure place of source data is m, the figure place of modulation back code word is n, continuous 0 quantity from the LSB that modulates the back code word to MSB is ended zero (EZ), and continuous 0 number from MSB to LSB is guiding zero (LZ), according to the LZ condition with d=1, k=7, the code word of m=8 and 0≤EZ≤5 is classified as follows.

(1) the code word number of satisfied 1≤LZ≤7 is 210.

(2) the code word number of satisfied 0≤LZ≤4 is 316.

(3) the code word number of satisfied 0≤LZ≤2 is 264.

In order to modulate 8 potential source data, the code word number should be more than at least 256 or 256.Yet in group (1), the code word number is less than 256, like this, just gets the shortage that the code word that satisfies different LZ conditions partly comes to replenish code word.In other words, the code word that satisfies LZ=0 from group (2) deducts 51 " 1010xxxxxxxx " code words, is added to the code word among the group (1) then.Then, the code word number among the group (1) becomes 261, and the code word number among the group (2) becomes 265, and the code word number among the group (3) becomes 264.As a result, group (1), (2) and (3) all comprise the code word more than 256 or 256, like this, can satisfy the minimum number " 256 " of the code word of the 8 potential source data that will modulate.Take out 256 code words from each group (1), (2) and (3), cause 3 primary key group MCG1, MCG2 and MCG3.Among Fig. 8, primary key group MCG1 is corresponding to comprising group (1), and group (1) comprises code word that satisfies 1≤LZ≤7 and 51 code words of taking out from group (2), and primary key group MCG2 and MCG3 are respectively corresponding to group (2) and (3).The code word of the source data that will modulate with 256 code words conducts of each primary key group MCG1, MCG2 and MCG3 only.

Fig. 9 shows a plurality of code word groups of the subcode conversion table that is used for DC control and these code words group's code word characteristic.

Code word in the subcode conversion table is to satisfy code word, the primary key group MCG1 of 6≤EZ≤7, and the redundant code word of MCG2 and MCG3 and the code word that satisfies 5≤LZ≤6 or LZ=3 are then as the auxiliary code group.Describe the condition of the code word that produces the subcode conversion table below in detail, represent the auxiliary code group with ACG1, ACG2 and ACG3.

Auxiliary code group ACG1 comprises 15 code words, and these 15 code words derive from: satisfy 5 redundant code words+satisfied 6≤EZ≤7 of 8 code words+primary key group MCG1 of 6≤EZ≤7 and LZ ≠ 0 and 2 " 1010xxxxxxxx " code words of LZ=0.

Auxiliary code group ACG2 comprises 40 code words, and these 40 code words derive from: 2 " 1010xxxxxxxx " code words of 9 redundant code words of 21 code words+primary key group MCG2 of 12 code words of satisfied 6≤EZ≤7 and 0≤LZ≤6+satisfied 0≤EZ≤5 and 5≤LZ≤6-satisfied 6≤EZ≤7 and LZ=0.

Auxiliary code group ACG3 comprises 51 code words, and these 51 code words derive from: 8 redundant code words of 33 code words+primary key group MCG3 of 10 code words of satisfied 6≤EZ≤7 and 0≤LZ≤3+satisfied 0≤EZ≤5 and LZ=3.

Figure 10 has shown parameter ncg, parameter ncg represents according to reference to figure 6 described main code conversion tables with reference to the determined next code group M=ncgdet of quantity EZ_a of the ended zero of the previous code word a of subcode conversion table of the described DC of the being used for control of figure 9, that is the next code group of previous code word a.Determine code group under the code word b according to digital EZ_a.In other words, if digital EZ_a is " 0 ", the code group of code word b be " 1 " (=MCG1), if 1≤EZ_a≤3, the code group of code word b be 2 (=MCG2), if 4≤EZ_a≤7, the code group of code word b be 3 (=MCG3).

The part that connects code word a and code word b must satisfy RLL (d, k) condition.

Figure 11 shows RLL (d, k) condition when code word b is connected with code word a.Being added to the value that the LZ_b number of the guiding zero of code word b obtains by the EZ_a number with the ended zero of code word a should and be less than or equal to maximum run length k more than or equal to minimum run length d, and purpose is to satisfy RLL (d, k) condition.

Figure 12 shows code word a and b and does not meet (d, the k) change of the parameter I NV before and after code modulated during condition with reference to the described RLL of Figure 11.Parameter I NV represents the transformation of next code word, and here, if the figure place of code word intermediate value " 1 " is an even number, parameter I NV is exactly " 0 ", and if the figure place of code word intermediate value " 1 " is an odd number, parameter I NV is exactly " 1 ".In addition, digital sum value (DSV) parameter refers to the DSV in the streams of code words, and low absolute DSV represents that streams of code words comprises DC or low frequency component in a small amount.DC value in code word and value (CSV) the parametric representation code word is used to measure DC or low frequency component during the code modulated, and low CSV represents that code word comprises DC or low frequency component in a small amount.If being accumulated to the INV value of current code word in streams of code words is " 0 ", the CSV value of next code word is added to the DSV value that is added to the code word before next code word, so that renewal PSV value.If the INV value of accumulation is " 1 ", the symbol of the CSV of next code word is negated, be added to the DSV value of accumulation then, so that renewal DSV value.

With reference to Figure 12, determine code group under the code word b according to the quantity EZ_a of the ended zero of previous code word a.Specifying under the situation of a code group as the code group of code word b, the code group of code word b can not satisfy RLL (d, k) condition, wherein specified code group is taken out code word owing to the code word that lacks main code conversion table and the subcode conversion table that is used for DC control from another code conversion table.Among Figure 12, the code group of code word b is violated d≤EZ_a+LZ_b≤k,, has changed the quantity EZ_a of the ended zero of code word a here.Be not inconsistent the code word change that is caused with the RLL condition and be called " border rule ".The figure place of the value " 1 " in the expression streams of code words is that the parameter I NV of even number or odd number may change from the state before the code modulated to some extent according to the border rule.Like this, code word is to be used for the predetermined sequence arrangement of code conversion table of DC control.

Figure 13 shows dispersing of streams of code words that the code word b1 that is used for DC control and b2 cause.Distinguishing feature according to the code modulated of the embodiment of the invention is that two code words in the optional code conversion table have opposite INV characteristic (figure place of the value " 1 " in the expression streams of code words is odd number or even number), and purpose is a control direct current (DC).Like this, owing to the code word in two optional code conversion tables has opposite INV characteristic, so one that can arrange in two code words is used for best DC control.As mentioned above, according to boundary condition, parameter I NV may be changed.Yet this change is in the time can identical phenomenon occurring in two code conversion tables that the DC control point is selected, unimportant when promptly all changing parameter I NV in two code conversion tables.Correspondingly, in an embodiment of the present invention, consider that following condition comes the design code conversion table.

At first, the position A code word a being connected to code word b can select code word b1 and b2 as code word b.In this case, identical among the ended zero of code word a quantity EZ_a and " xxxxxxxxx101 ", identical among the guiding of code word b1 quantity LZ_b1 zero and " 101xxxxxxxxx ", the guiding of code word b2 quantity LZ_b2 zero with " 101xxxxxxxxx " in identical.In other words, have code word as a plurality of guiding in " 101xxxxxxxxx " zero and be placed in identical position among primary key group MCG1 and the auxiliary code group ACG1, have code word as a plurality of ended zero in " xxxxxxxxx101 " and be placed in identical position among primary key group MCG1 and auxiliary code group ACG1, primary key group MCG2 and auxiliary code group ACG2 and primary key group MCG3 and the auxiliary code group ACG3.Correspondingly, when among a plurality of ended zero of code word a and " xxxxxxxxx101 " when identical, the parameter I NV of code word a changes or does not change.Like this, according to the border rule, code stream under the code word b1 and the code stream under the code word b2 have opposite INV characteristic.

Below, when code word b1 is connected with code word c respectively with b2, be connected to the position B of code word c at code word b, though code word b1, b2 or c are modulated to the code word of another type according to the border rule, but the code stream that code word b1 is connected to code word c has opposite parameter I NV with the code stream that code word b2 is connected to code word c.

Explain synchronous mode and multiplexed ID now.

In continuous 0 maximum number " k " between " 1 " position being restricted to 7 modulator approach, use the synchronous mode " 010000000010000000010 " of violating restriction k=7.

Synchronous mode: 010000000010000000010

As shown in figure 14,4 bit multiplexed information are modulated to 6 bit multiplexed ID, so that with data stream multiplexing.In this case, be L=2 with a data stream translation ⁴=16 types random data stream.

Figure 15 A has illustrated the main code conversion table of considering above-mentioned condition and producing and arrange to 15E.

Figure 16 has shown the subcode conversion table that is used for DC control of considering above-mentioned condition and producing and arrange.Check (whether the code word of Figure 13 a) violates run-length restriction with code word (the code word c of Figure 13) subsequently to previous code word.When previous code word and code word are not subsequently violated run-length restriction, should use the code word in the subcode conversion table.

Figure 17 shows according to the present invention the PSD curve of the code stream of RLL (1,7) modulation.

Figure 18 will be according to an embodiment of the invention the encoding rate and the code efficiency of the encoding rate of RLL (1,7) sign indicating number and code efficiency and traditional A-code, B-code and C-code compare.RLL (1,7) sign indicating number has the code efficiency that suppresses ability and Geng Gao to traditional A-code, the B-code DC similar with the C-code.As a result, packing density can be improved about 2%.

Figure 19 shows the PSD curve, and the DC that the DC that shows RLL (2,10,8,15) according to an embodiment of the invention suppresses ability and the 8-14 modulation used on traditional DVD adds (EFMP) sign indicating number suppresses ability.Here, except the main code conversion table, the EFMP sign indicating number also utilizes the code conversion table of the separation that is used for DC control to suppress DC.An example of RLL (2,10,8,15) sign indicating number is disclosed in the korean patent application 2001-21360 that the applicant submits to.Embodiments of the invention are carried out weak no DC RLL modulation, and it is with the main code conversion table and be used for the subcode conversion table that DC controls, and does not use the subcode conversion table of the separation that comprises extra order.

Figure 20 will compare according to the encoding rate of the RLL (2,10,8,15) of the embodiment of the invention and the encoding rate and the code efficiency of code efficiency and EFMP sign indicating number.RLL (2,10,8,15) sign indicating number has the code efficiency that suppresses ability and Geng Gao with the similar DC of EFMP sign indicating number, and this has just increased 5.4% with packing density.

Embodiments of the invention can be effectively applied to store the multiple medium of numerical data, especially such as the high density medium of high-density digital multipurpose CD (HD-DVD).

As mentioned above, the present invention can combine weak no DC modulation code with the multi-mode coding method, so that provide DC inhibition ability to improve efficient modulation code.As a result, can improve packing density.

In addition, when being used in DC and suppressing between the RLL modulation period code word with another type and replace violating the code word of RLL condition, can arrange the code word that is replaced, to keep the DC inhibition ability of code stream.As a result, can realize the effect of the DC inhibition ability raising of code stream.

In addition, in the multi-mode coding method, will import data scramble discontinuously,, thereby remove the DC component so that be multiplexed as pseudo-random data.Like this, can keep DC and suppress ability, and compare, can reduce the possibility of error propagation with the multi-mode coding method that utilizes general scramble method.

Can realize the operation of method of the present invention with the computer executable instructions of computer-readable media.

Though shown and described several embodiments of the present invention,, those skilled in the art will know, can change and do not deviate from principle of the present invention and spirit embodiment, its scope is limited by claim and its equivalents.

Claims (48)

1. one kind is the data modulation method of n-bit word with m-potential source data-modulated, wherein, n 〉=m and m and n are positive integers, and minimum run length is defined as " d " and maximum run length is defined as " k ", " d " and " k " is positive integer, and described data modulation method comprises:

Divide input traffic by predetermined length, and utilize multiplexed information that input traffic is multiplexed, so that multiplexed data stream is provided according to predetermined multichannel multiplexing method;

The DC control routine conversion table that need not comprise the separation of extra order carries out weak no DC restriction run length (RLL) modulation to multiplexed data stream; With

The code stream of DC component minimum is provided in code stream multiplexed, the RLL modulation.

2. data modulation method according to claim 1, wherein, multichannel multiplexing method uses scramble method.

3. data modulation method according to claim 1, wherein, multichannel multiplexing method uses deinterleaving method.

4. data modulation method according to claim 1, wherein, weak no DC RLL modulation is carried out in the following manner: produce the code word that meets predetermined RLL condition, and control the subcode conversion table with main code conversion table and DC and these code words are divided into groups according to the RLL condition that should be scheduled to, arrange code word and make source word stream have DC inhibition ability in described main code conversion table, described DC control subcode conversion table obtains in the following manner: take out the unnecessary code word that meets this predetermined RLL condition from described main code conversion table.

5. data modulation method according to claim 4, wherein, minimum run length restriction " d " is 1, maximum run length restriction " k " is 7.

6. data modulation method according to claim 4, wherein, in weak no DC RLL modulation, the code word of the identical data in primary key group and DC control auxiliary code group has opposite INV value, so that control direct current (DC), wherein, INV is that the figure place according to the value in the streams of code words " 1 " is the parameter that turns that odd number or even number are predicted next code word.

7. data modulation method according to claim 4, wherein, the main code conversion table comprises the code word group of the 0≤EZ that satisfies condition≤5,1≤LZ≤7,0≤LZ≤4 and 0≤LZ≤2, wherein, EZ is the ended zero of continuous 0 number from the least significant bit to the highest significant position in the expression code word, and LZ is the guiding zero of continuous 0 the number of expression from the highest significant position to the least significant bit.

8. data modulation method according to claim 7, wherein, comprising one of the code group that source code is less than the main code conversion table of the minimum number code word that will modulate prepares in the following manner: remove redundant code word from comprising code word greater than one of code group of this minimum number, make to keep code word greater than this minimum number.

9. data modulation method according to claim 4, wherein, DC controls sub-conversion table and comprises:

Comprise the code word that satisfies 6≤EZ≤7 and LZ ≠ 0, the first primary key group's redundant code word and satisfy the group of " 1010xxxxxxxx " code word of 6≤EZ≤7 and LZ=0, wherein, EZ is the ended zero of continuous 0 the number of expression from the least significant bit to the highest significant position, and LZ is the guiding zero of continuous 0 the number of expression from the highest significant position to the least significant bit;

Comprise satisfy 6≤EZ≤7 and≤code word of LZ≤6, satisfy the group of 0≤EZ≤5 and 5≤EZ≤6 and the second primary key group's redundant code word, this group removed " 1010xxxxxxxx " code word of satisfied 6≤EZ≤7 and LZ=0; With

The group who comprises the code word that satisfies 6≤EZ≤7 and 0≤LZ≤3, the code word that satisfies 0≤EZ≤5 and LZ=3 and the 3rd primary key group's redundant code word.

10. data modulation method according to claim 9, wherein, as code word a, the stream of b1 and c and code word a, the stream of b2 and c in pairs and code word b1 and b2 be when having the code word of opposite INV characteristic in the DC control subcode conversion table, though owing to violate code word a, the stream of b1 and b2 is with code word b1, the predetermined run-length restriction between the stream of b2 and c (border rule) and conversion code word a, b1, b2 or c, but, in main code conversion table and DC control subcode conversion table, arrange code word, make code word a, stream and code word a after the modulation of b1 and c, stream has opposite INV characteristic after the modulation of b2 and c.

11. data modulation method according to claim 4, wherein, minimum run length restriction " d " is 2, and maximum run length restriction " k " is 10.

12. data modulation method according to claim 1 also comprises synchronous mode is inserted the multiplexed data stream that has added multiplexed information, and this multiplexed information is converted to multiplexed ID.

13. data modulation method according to claim 12, wherein, multiplexed ID satisfies minimum run length restriction " d " 2 and maximum run length restriction " k " 10, thereby increases minimum mark length, so that reduce the interference noise of signal.

14. one kind is the data modulation method of n-bit word with m-potential source data-modulated, wherein, n 〉=m and m and n are positive integers, and minimum run length is defined as " d " and maximum run length is defined as " k ", " d " and " k " is positive integer, and described data modulation method comprises:

By predetermined multichannel multiplexing method is applied to each pseudo-random data stream,, will be multiplexed as polytype pseudo-random data stream by the input traffic that predetermined length is divided with the multiplexed information of pre-determined bit; With

These polytype pseudo-random data stream are carried out RLL modulation, carried out code stream after the modulation that best DC suppresses so that produce.

15. data modulation method according to claim 14 wherein, by with multiplexed information scramble input traffic discontinuously, produces random data stream.

16. data modulation method according to claim 15 wherein, is worked as s _tBe when being used for the multiplexed information of the multiplexed input traffic that is divided into v the data flow that all has the u byte long, multiplexed information s _tFigure place a be less than or equal the figure place m of input source data, wherein, u and v are positive integers.

17. data modulation method according to claim 16, wherein, the generation of random data stream comprises:

To multiplexed information s _tModulate a m bit data of unit with the first code of polytype random data stream and carry out nonequivalence operation, to produce modulation back data;

From second code modulation unit to q-1 code modulated unit data are exported without change and do not carried out nonequivalence operation;

First code modulation unit and q code modulated unit are carried out nonequivalence operation, so that produce next modulation back data; With

Repeat input traffic from the nonequivalence operation of code modulated unit to the end of q code modulated unit.

18. data modulation method according to claim 17, wherein, when the nonequivalence operation cycle was q, here, q was a positive integer, and the possibility of error propagation is reduced to 1/q.

19. data modulation method according to claim 14 also comprises:

Input traffic is divided into predetermined length;

When producing pseudo-random data stream, synchronous mode is inserted the multiplexed pseudo-random data stream of having added multiplexed information, and multiplexed information is converted to multiplexed ID; With

More polytype RLL modulation back code stream is so that select to comprise the code stream of minimum DC component.

20. one kind is the data modulation method of n-bit word with m-potential source data-modulated, wherein, n 〉=m and m and n are positive integers, and minimum run length is defined as " d " and maximum run length is defined as " k ", " d " and " k " is positive integer, and described data modulation method comprises:

By predetermined multichannel multiplexing method is applied to each pseudo-random data stream,, will be multiplexed as polytype pseudo-random data stream according to stream by the input data that predetermined length is divided with the multiplexed information of pre-determined bit; With

The DC control routine conversion table that need not comprise extra order carries out weak no DC RLL modulation to these multiplexed data streams, and is provided at the code stream that comprises minimum DC component in the code stream multiplexed, the RLL modulation.

21. data modulation method according to claim 20 wherein, by with multiplexed information scramble input traffic discontinuously, produces pseudo-random data stream.

22. data modulation method according to claim 21 wherein, is worked as s _tBe when being used for the multiplexed information of the multiplexed input traffic that is divided into v the data flow that all has the u byte long, multiplexed information s _tFigure place a be less than or equal the figure place m of input source data, wherein, u and v are positive integers.

23. data modulation method according to claim 22, wherein, the generation of pseudo-random data stream comprises:

To multiplexed information s _tModulate a m bit data of unit with the first code of polytype random data stream and carry out nonequivalence operation, to produce modulation back data;

From second code modulation unit to q-1 code modulated unit data are exported without change and do not carried out nonequivalence operation;

First code modulation unit and q code modulated unit are carried out nonequivalence operation, so that produce next modulation back data; With

Repeat input traffic from the nonequivalence operation of code modulated unit to the end of q code modulated unit.

24. data modulation method according to claim 23, wherein, when the nonequivalence operation cycle was q, here, q was a positive integer, and the possibility of error propagation is reduced to 1/q.

25. data modulation method according to claim 20 also comprises:

Input traffic is divided into predetermined length;

When producing pseudo-random data stream, synchronous mode is inserted the multiplexed pseudo-random data stream of having added multiplexed information, and multiplexed information is converted to multiplexed ID; With

More polytype RLL modulation back code stream is so that select to comprise the code stream of minimum DC component.

26. data modulation method according to claim 20, wherein, weak no DC RLL modulation is carried out in the following manner: produce the code word that meets predetermined RLL condition, and with the main code conversion table and with DC control subcode conversion table according to RLL condition that should be predetermined with these code words groupings, arrange code word and make source word stream have DC inhibition ability in described main code conversion table, described DC control subcode conversion table obtains in the following manner: take out the unnecessary code word that meets this predetermined RLL condition from described main code conversion table.

27. data modulation method according to claim 26, wherein, minimum run length restriction " d " is 1, and maximum run length restriction " k " is 7.

28. data modulation method according to claim 26, wherein, in weak no DC RLL modulation, the code word of identical data has opposite INV value in primary key group and DC control auxiliary code group, so that control DC, and INV is that figure place according to the value in the streams of code words " 1 " is the parameter that turns that odd number or even number are predicted next code word.

29. data modulation method according to claim 26, wherein, the main code conversion table comprises the code word group of the 0≤EZ that satisfies condition≤5,1≤LZ≤7,0≤LZ≤4 and 0≤LZ≤2, wherein, EZ is the ended zero of continuous 0 number from the least significant bit to the highest significant position in the expression code word, and LZ is the guiding zero of continuous 0 the number of expression from the highest significant position to the least significant bit.

30. data modulation method according to claim 29, wherein, comprising one of the code group that source code is less than the main code conversion table of the minimum number code word that will modulate prepares in the following manner: remove redundant code word from comprising code word greater than one of code group of this minimum number, make to keep code word greater than this minimum number.

31. data modulation method according to claim 26, wherein, DC controls sub-conversion table and comprises:

Comprise the code word that satisfies 6≤EZ≤7 and LZ ≠ 0, the first primary key group's redundant code word and satisfy the group of " 1010xxxxxxxx " code word of 6≤EZ≤7 and LZ=0;

Comprise satisfy 6≤EZ≤7 and≤code word of LZ≤6, satisfy the group of 0≤EZ≤5 and 5≤EZ≤6 and the second primary key group's redundant code word, this group removed " 1010xxxxxxxx " code word that satisfies 6≤EZ≤7 and LZ=0, wherein, EZ is the ended zero of continuous 0 the number of expression from the least significant bit to the highest significant position, and LZ is the guiding zero of continuous 0 the number of expression from the highest significant position to the least significant bit; With

The group who comprises the code word that satisfies 6≤EZ≤7 and 0≤LZ≤3, the code word that satisfies 0≤EZ≤5 and LZ=3 and the 3rd primary key group's redundant code word.

32. data modulation method according to claim 31, wherein, as code word a, the stream of b1 and c and code word a, the stream of b2 and c in pairs and code word b1 and b2 be when having the code word of opposite INV characteristic in the DC control subcode conversion table, though owing to violate code word a, the stream of b1 and b2 is with code word b1, the predetermined run-length restriction between the stream of b2 and c/border rule and conversion code word a, b1, b2 or c, but, in main code conversion table and DC control subcode conversion table, arrange code word, make code word a, stream and code word a after the modulation of b1 and c, stream has opposite INV characteristic after the modulation of b2 and c.

33. data modulation method according to claim 26, wherein, minimum run length restriction " d " is 2, and maximum run length restriction " k " is 10.

34. data modulation method according to claim 25, wherein, it is 2 that multiplexed ID satisfies minimum run length " d ", and maximum run length " k " is 7, thereby increases minimum mark length, so that reduce the interference noise of signal.

35. a data demodulation method comprises:

The input digital data of each n position is demodulated into the demodulation code unit of m position, and here, n 〉=m and m and n are positive integers, have the data flow of not inverting of predetermined length so that produce; With

Separate this data flow of not inverting of scramble discontinuously with multiplexed information, so that produce the data flow of inverting.

36. demodulation method according to claim 35, wherein, the scramble of separating of the data flow of not inverting comprises:

Separate scramble code element and carry out nonequivalence operation first, so that produce first data of inverting as the primary data of multiplexed information;

The second demodulation code unit is exported to q-1 demodulation code unit, and do not carry out nonequivalence operation;

Q demodulation code unit to the first demodulation code unit and discontinuous q demodulation code unit carries out nonequivalence operation, so that produce next data of inverting; With

Repeat nonequivalence operation, up to last of all the other q demodulation code units of the data flow of not inverting, so that the data flow of inverting is provided.

37. one kind by being defined as minimum run length restriction " d " 1 and maximum run length restriction " k " is defined as 7, m-potential source data arrangement is become the method for n-bit word, n 〉=m here, n and m are positive integers, " d " and " k " is positive integer, and described method comprises:

When code word a is connected to code word b, code word a is the code word of front, select code word b from code word b1 and b2, the code stream that wherein code word a is connected to code word b1 is X1, the code stream that wherein code word a is connected to code word b2 is X2, arrange code word b1 and b2, with have figure place according to the value in the code word " 1 " be very or idol predict the reverse link parameter INV of the transformation of next code; With

When code word a is connected to code word b1 or b2, though according to the border rule with code word a, b1 or b2 are modulated into the code word of another type,, arrange code stream X1 and X2 to have reverse link parameter INV.

38. according to the described method of claim 37, wherein, when the figure place of the value " 0 " between code word a and the code word b1 and between code word a and the code word b2 is less than minimum run length restriction " d "=1, revise code word a according to the border rule, b1 or b2, so that arrange code word a, b1 and b2, between the code word a that make to revise and the code word b1 of modification and the figure place of the value " 0 " between the code word b2 of code word a that revises and modification more than or equal to minimum run length restriction " d ", and be less than or equal to maximum run length restriction " k "=7.

39. according to the described method of claim 37, wherein, code stream a among code word a among the code stream X1 and the code stream X2 all is converted to the code word of another type according to the border rule, so that have identical INV value, make code stream X1 and X2 owing to the INV value of code word b1 and b2 has opposite INV value.

40. one kind by being defined as minimum run length restriction " d " 1 and maximum run length restriction " k " is defined as 7, m-potential source data arrangement is become the method for n-bit word, n 〉=m here, n and m are positive integers, " d " and " k " is positive integer, and described method comprises:

When code word b is connected to code word c, code word b is the code word of front, select code word b from code word b1 and b2, wherein to be connected to the code stream of code word c be Y1 to code word b1, wherein to be connected to the code stream of code word c be Y2 to code word b2, arrange code word b1 and b2, with have figure place according to the value in the code word " 1 " be very or idol predict the reverse link parameter INV of the transformation of next code; With

When code word b1 or b2 are connected to code word c, though according to the border rule with code word b1, b2 or c are modulated into the code word of another type,, arrange code stream Y1 and Y2 to have reverse link parameter INV.

41. computer-readable media, has the executable instruction of computer, being used to carry out with m-potential source data-modulated is the operation of the data modulation method of n-bit word, wherein, n 〉=m and m and n are positive integers, here, minimum run length is defined as " d " and maximum run length is defined as " k ", wherein, " d " and " k " is positive integer, and described operation comprises:

Divide input traffic by predetermined length, and according to predetermined multichannel multiplexing method, with multiplexed information that input traffic is multiplexed, so that multiplexed data stream is provided;

The DC control routine conversion table that need not comprise the separation of extra order just carries out weak no DC restriction run length (RLL) modulation to multiplexed data stream; With

Be provided at the code stream in the code stream multiplexed, the RLL modulation with minimum DC component.

42. computer-readable media, has the executable instruction of computer, being used to carry out with m-potential source data-modulated is the operation of the data modulation method of n-bit word, wherein, n 〉=m and m and n are positive integers, here, minimum run length is defined as " d " and maximum run length is defined as " k ", wherein, " d " and " k " is positive integer, and described operation comprises:

By predetermined multichannel multiplexing method is applied to each pseudo-random data stream,, will be multiplexed as polytype pseudo-random data stream by the input traffic that predetermined length is divided with the multiplexed information of pre-determined bit; With

These polytype pseudo-random data stream are carried out RLL modulation, carried out code stream after the modulation that best DC suppresses so that produce.

43. computer-readable media, has the executable instruction of computer, being used to carry out with m-potential source data-modulated is the operation of the data modulation method of n-bit word, wherein, n 〉=m and m and n are positive integers, here, minimum run length is defined as " d " and maximum run length is defined as " k ", wherein, " d " and " k " is positive integer, and described operation comprises:

By predetermined multichannel multiplexing method is applied to each pseudo-random data stream,, will be multiplexed as polytype pseudo-random data stream by the input traffic that predetermined length is divided with the multiplexed information of pre-determined bit; With

The DC control routine conversion table that need not comprise extra order carries out weak no DC RLL modulation to these multiplexed data streams, and is provided at the code stream that comprises minimum DC component in the code stream multiplexed, the RLL modulation.

44. a computer-readable media has the executable instruction of computer, is used to carry out the operation of data demodulation method, described operation comprises:

The input digital data of each n position is demodulated into the demodulation code unit of m position, and here, n 〉=m and m and n are positive integers, so that produce the data flow of not inverting with predetermined length; With

Separate this data flow of not inverting of scramble discontinuously with multiplexed information, so that produce the data flow of inverting.

45. computer-readable media, has the executable instruction of computer, be used for by minimum run length restriction " d " being defined as 1 and maximum run length restriction " k " is defined as 7, carrying out m-potential source data arrangement is the operation of the method for n-bit word, wherein, n 〉=m and m and n are positive integers, and " d " and " k " is positive integer, and described operation comprises:

When code word a is connected to code word b, code word a is the code word of front, select code word b from code word b1 and b2, the code stream that wherein code word a is connected to code word b1 is X1, the code stream that wherein code word a is connected to code word b2 is X2, arrange code word b1 and b2, with have figure place according to the value in the code word " 1 " be very or idol predict the reverse link parameter INV of the transformation of next code; With

When code word a is connected to code word b1 or b2, though according to the border rule with code word a, b1 or b2 are modulated into the code word of another type,, arrange code stream X1 and X2 to have reverse link parameter INV.

46. computer-readable media, has the executable instruction of computer, be used for by minimum run length restriction " d " being defined as 1 and maximum run length restriction " k " is defined as 7, carrying out m-potential source data arrangement is the operation of the method for n-bit word, wherein, n 〉=m and m and n are positive integers, and " d " and " k " is positive integer, and described operation comprises:

When code word b is connected to code word c, code word b is the code word of front, select code word b from code word b1 and b2, wherein to be connected to the code stream of code word c be Y1 to code word b1, wherein to be connected to the code stream of code word c be Y2 to code word b2, arrange code word b1 and b2, with have figure place according to the value in the code word " 1 " be very or idol predict the reverse link parameter INV of the transformation of next code; With

When code word b1 or b2 are connected to code word c, though according to the border rule with code word b1, b2 or c are modulated into the code word of another type,, arrange code stream Y1 and Y2 to have reverse link parameter INV.

47, a kind of data modulation method comprises:

Source data is modulated to code word, and this moment, minimum run length was defined as " d " and maximum run length is defined as " k ", and " d " and " k " are positive integers,

Wherein said modulation step comprises: code word a is changed into other code words, make the guiding zero of the ended zero of code word a and code word b and less than minimum run length restriction or situation greater than the maximum run length restriction under, the guiding of the ended zero of code word a and code word b zero and more than or equal to the minimum run length restriction and be less than or equal to the maximum run length restriction, wherein code word b is connected to code word a, code word a is the code word of front, ended zero is continuous 0 a number from the least significant bit of code word a to highest significant position, and guiding zero is continuous 0 a number from the highest significant position of code word b to least significant bit.

48, according to the described data modulation method of claim 47, wherein, minimum run length restriction " d " is 1, maximum run length restriction " k " is 7, the ended zero that described change is included in code word a is under the situation of " 0 " for the guiding of " 0 " and code word b is zero, and code word a is changed into the code word of least significant bit for " 0 ".

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