TH41460B - Improved turbo code based on changed redundancies. - Google Patents

Abstract

DC60 (12/05/46) Improved turbo code based on replaceable redundant sections that will include one (102) phase of the stream penetration for the first transmission to provide a series of segments. Trellis does not pierce at one, the next step (104) will include drilling the stream for the second transmission to provide a set. Of the second trellis part, the next step (106) will include the changed redundant that includes the pass First and second trellis to provide first and second non-stick trellis sections that are not adjacent to each other.The above arrangement results in a uniform distribution of drilled bits and where Do not drill to provide a lower fault. The improved turbo code, based on the redundant redundant sections, will include the first (102) stage of penetrating the stream for the first transmission to provide a set of non-penetrating trellis segments. One next step (104) will include stream penetration for the second transmission to provide a set. The next step (106) will include the changed redundancy that includes the submission. Through the first and second trellis to provide a non-drilling first and second non-stick trellis segments.The above arrangement results in a uniform distribution of drilled bits and That does not penetrate in order to provide a lower error rate

Claims (9)

1. Methods for improving turbo code based on redundant segments changing methods, which consist of the steps of: drilling the stream for the first transmission to provide a set of non-penetrating trellis segments. First, traverse the stream for the second pass to provide a second set of non-penetrating trellis segments, and the redundant, switched segments that combine the first and second pass of the trellis to provide a section The trellis does not penetrate the first and the second that is not adjacent. 2. Claim Method 1, where the amalgamation procedure provides a uniformly patterned composite drilling pattern with non-penetrating trellis sections. 3. The method of claim 1, where each drilling procedure takes place, provides for a set of each Trellis does not penetrate the first and second perpendiculars. 4. Claim 1 method, where each drilling step includes a sub-step of Matching the rate of each bit stream using parameters Matching the rate given by the equation eini(r)={[Xi-( r.eplus/tmix)-1]mod eplus}+1 and eini(r)={[Xi-((s+ 2.r).eplus/( 2.rmax)) -1]mod eplus}+1 where r efsilon{0,....,r max -1} and r max is the total number of redundant sets allowed by r variable, from which e ini is computed. The loop for each twist current according to the variable parameter e ini rs is 0 or 1, depending on whether the transmission is non-self-decoding or self-decoding, respectively e plus and e minus are selected according to the Xi e plus table. e mimus RM S system N sys N sys |N sys -N sys| parity 1 N p1 a.Np1 a |Np1-N p1| RM P1_2 parity 2 Np2 a.Np2 a|Np2-Nt , p2| RM P2_2 where a=2 for parity 1 and a=1 for parity 2 Nsys is the number of system bits, Np1 is the number of parity or odd bits, 1Np2 is the number of parity bits. 2 N sys is the number of system bits sent Nt, p1 is the number of parity bits 1 sent and Nt, p2 is the number of parity bits 2 sent and where the rate matching equation will is chosen from one of the groups consisting of : selecting one of the equations to match the rate for the entire case of penetration (i.e. N data <or= Nsys+ Np1+Np2) and the case of duplication (that is, N data > N sys+Np1+Np2) and selecting one of the equations. to match the rate for penetration and another equation to match the rate for repetition. 5. Claim method 1, where each drilling step includes a sub-step of Match the rate of each bit stream using the rate matching parameters defined by the equation. eini(r)={[Xi-( r.eplus/tmix)-1]mod eplus}+1 in case of drilling, that is N data <or= N sys + Np1+Np2 and eini(r)={[ Xi-((s+ 2.r).eplus/( 2.rmax))-1]mod eplus}+1 for iteration, that is, N data>N sys+Np1+Np2 where r is the eini transformation parameter s. are 0 or 1, depending on whether the pass is self-decoding or self-decoding, respectively, and r is in the range from 0 to r max to vary the initial error variables eini and Xi , e . plus and e maix are selected according to the table. Xi e plus e mimus RM S is system N sys N sys |N sys -N sys| parity 1 N p1 a.Np1 a |Np1-N p1| RM P1_2 parity. or odd 2 Np2 a.Np2 a|Np2-Nt, p2| RM P2_2 where a=2 for parity 1 and a=1 for parity 2 Nsys is the number of bits, as a system, Np1 is the number of bits. Parity 1Np2 is the number of parity bits 2 Nt, sys is the number of system bits sent, Nt, p1 is the number of parity bits 1 sent, and Nt, p2 is the number of parity bits. odd 2 submitted 6. Claims method 5, which is further complemented by the procedure of selecting the redundant scheme, where: If session redundant sections are selected, s=1 and r=1 are defined for all passes. If partial IR redundancy is selected, a sub-step is performed: Calculating the possible number of specific redundant sets as (chemical formula) Where Np_i represents the number of parity or odd bits at the output of the turbo encoder from the stream. i th parity Nt_p_i represents the number of parity currents transmitted by the parity current i th and P is the number of parity currents where if rn>rmax then rn = r max and for the index Passing n from 1,2,.......,rn defines s = 1 and r = n-1 and where if n>rn reassigns n to 1 and repeats this subclass. and, if full IR redundancy is selected, substeps of: a) Calculation of the possible number of specific redundant sets is (chemical formula) where BR is the code-base rate, R is the transmit code rate, and k and i are selected positive integer In such a way that the absolute transmission k is equal to the output block as system and parity i, where if rN > r max then rN = r max b) for the transit index n=1, s=1, r is defined. =0 and Nt =N trans and c)For the transit index n of 2,....., rN repeats the sub-step of: Define Nt = Nt + N trans. Define indicator = 0 if (Nt >or= 1 x N sys), then assign the indicator = 1 and (Nt = N1 -1 x N sys) where N sys is the number of bits BR BR is the system generated by the turbo encoder. Set s = 0 if ((Nt >or= N sys) delta (indicator = 1)), then define s = 1, define r = r + 1 and if n > rN, reassign n to 1 and repeat step b) 7. The method of claim 1, which is further composed by the steps of the hierarchical mapping. The importance of bits is systematic to a position of higher reliability in modulation bundles. 8. Claim method 7, where the mapping procedure includes the provision of an alternator with dimensions Nrow x Ncol when Nrow =log2(M) and Ncol = Ntrans/Nrow where M is the motor size. Dulate and Ntrans are the number of coded and rate-matched bits that are sent and the top of the array has a high priority. than the bottom row of the array and where data is read into the switcher row by row starting in the top row, filling the switcher with all system bits first. This is followed by the parity bit. and read data from the switcher column by column 9. Claim Method 8, where the switcher is 16X30 and where the mapping procedure will Including permutation operations between columns using the following permutation pattern {0,20, 10,5,15,25,3,13,23,8,18,28,1,11,21,6. ,16,26,4,14,24,19,9,29,12,2,7,22,27,17} 1 0. The method of claim 1, which further encompasses the procedure of submitting a set of parameters which controls the sequence of executable redundant sets in the drilling procedure. One of the groups, which includes : Certainly redundant set parameters. Sleep and transmit these parameters using the control channel. and sending a table of set parameters Redundant segments by default and then select the table-entry as a means of specifying the set of redundant segment parameters.