WO2022252925A1 - 一种数据传输方法、通信节点及计算机可读存储介质 - Google Patents
一种数据传输方法、通信节点及计算机可读存储介质 Download PDFInfo
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/32—Carrier systems characterised by combinations of two or more of the types covered by groups H04L27/02, H04L27/10, H04L27/18 or H04L27/26
- H04L27/34—Amplitude- and phase-modulated carrier systems, e.g. quadrature-amplitude modulated carrier systems
- H04L27/3405—Modifications of the signal space to increase the efficiency of transmission, e.g. reduction of the bit error rate, bandwidth, or average power
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/18—Phase-modulated carrier systems, i.e. using phase-shift keying
- H04L27/186—Phase-modulated carrier systems, i.e. using phase-shift keying in which the information is carried by both the individual signal points and the subset to which the individual signal points belong, e.g. coset coding or related schemes
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/32—Carrier systems characterised by combinations of two or more of the types covered by groups H04L27/02, H04L27/10, H04L27/18 or H04L27/26
- H04L27/34—Amplitude- and phase-modulated carrier systems, e.g. quadrature-amplitude modulated carrier systems
- H04L27/36—Modulator circuits; Transmitter circuits
Definitions
- Fig. 1 is a schematic flow chart of a data transmission method provided by an embodiment
- Figures 8a-8f are another example provided by an embodiment.
- different Qm, mp Schematic diagram of the modulation map when ma, ⁇ * is selected;
- Figures 10a-10f are another example provided by an embodiment.
- different Qm, mp Schematic diagram of the modulation map when ma, ⁇ * is selected;
- Figures 12a-12c are another example provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits, and ma amplitudes are determined.
- Figures 14a-14c are another method provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits and ma amplitudes are determined.
- Figures 17a-17c are yet another example provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits, and ma amplitudes are determined.
- the performance gap between the QAM constellation signal and the Gaussian signal (hereinafter referred to as Gaussian signal) approaching the capacity, and this gap will exceed 1dB with the increase of transmission spectral efficiency (hereinafter referred to as spectral efficiency).
- the performance difference between QAM constellation signal and Gaussian signal is 1.53dB). Therefore, to achieve the same spectral efficiency, the signal-to-noise ratio (Signal-to-Noise Ratio, SNR) of sending QAM constellation signals needs to be increased by more than 1dB compared with sending Gaussian signals.
- SNR Signal-to-noise Ratio
- bit interleaving bit interleaving
- modulation mapping modulation mapping
- Low density parity check code Low density parity check
- Bit interleaving the bit sequences e 0 , e 1 , e 2 , ..., e E-1 after channel coding and rate matching are interleaved into (interleaved to) bit sequences f 0 , f 1 , f 2 ,..., f E-1 , Qm is the modulation order of the QAM constellation.
- the above interleaving process arranges the bit sequences e 0 , e 1 , e 2 ,..., e E-1 into a matrix of Qm rows and E/Qm columns in the form of first row and second column, and then one-to-one correspondence to the first column and then row comparison
- the special sequences f 0 , f 1 , f 2 , ..., f E-1 are arranged on a matrix of Qm rows and E/Qm columns.
- Bit b(Qm i+1) determines the sign of the imaginary part of the complex modulation symbol d(i);
- Bits b(Qm i+2),..., b(Qm i+Qm-2) determine the absolute value of the real part of the complex modulation symbol d(i);
- bits b(Qm ⁇ i+3), ..., b(Qm ⁇ i+Qm-1) determine the absolute value of the imaginary part of the complex modulation symbol d(i).
- the solution provided by the embodiment of the present application is designed based on the regular amplitude phase shift keying (Regular Amplitude Phase Shift Keying, RAPSK) constellation for bit interleaving and modulation mapping.
- RAPSK regular amplitude phase shift keying
- the RAPSK constellation is closely related to the Gray mapped Amplitude Phase Shift Keying (Gray-APSK) constellation.
- Gray-APSK Gray mapped Amplitude Phase Shift Keying
- the constellation points on the same circle are distributed at equal intervals, that is, the phase difference between two adjacent constellation points is constant.
- the access network device is the access device for the terminal device to access the mobile communication system through wireless means, and can be a base station (base station), an evolved base station (evolved NodeB, eNodeB), a transmission reception point (transmission reception point, TRP) ), the next generation base station (next generation NodeB, gNB) in the 5G mobile communication system, the base station in the future mobile communication system or the access node in the WiFi system, etc.; it can also be a module or unit that completes some functions of the base station, for example, It can be a centralized unit (central unit, CU) or a distributed unit (distributed unit, DU).
- the embodiment of the present application does not limit the specific technology and specific equipment form adopted by the access network equipment.
- access network equipment may be referred to as network equipment for short, and unless otherwise specified, network equipment refers to access network equipment.
- the first bit sequence f 0 , f 1 , f 2 , ..., f E-1 is obtained after the first communication node performs at least one of the following operations on the transmission block: channel coding ( channel coding), rate matching, bit interleaving, code block concatenation, and scrambling.
- the first K bits in the second bit sequence e 0 , e 1 , e 2 , ..., e E-1 are input bits for channel coding, 0 ⁇ K ⁇ E.
- the RAPSK constellation includes at least one of the following features:
- Phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the last mp bits in Qm bits b 0 , b 1 ,...,b Qm-1 ;
- Amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 are the last ma bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- Amplitude map bits c 2,0 , c 2,1 ,...,c 2,ma-1 are the first ma bits of the Qm bits b 0 , b 1 ,...,b Qm-1 ;
- Amplitude map bits c 2,0 , c 2,1 ,...,c 2,ma-1 are in the last Qm-2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 Even-numbered bits.
- the first part bits d 1,0 and d 1,1 are determined in any of the following ways:
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are determined according to any of the following:
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are the last mp-2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the ma magnitude map bits c 2,0 , c 2,1 , ..., c 2,ma-1 are determined in any of the following ways:
- bits d 1, 0 and d 1, 1 are the first 2 bits in Qm bits b 0 , b 1 ,..., b Qm-1 ;
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are the Qm bits b 0 , b 1 ,...,b in the last Qm-2 bits of Qm -1 Odd-indexed bits.
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the last Qm-2 bits in Qm bits b 0 , b 1 ,...,b Qm-1 Even-indexed bits in .
- Np 2 mp constellation points on each concentric circle of the RAPSK constellation, and the constellation points located on the same circle are equidistantly distributed, that is, the phase difference between two adjacent constellation points is Np is the number of RAPSK modulation phases, mp is the number of phase mapping bits, and mp is a function of Qm and ma.
- RAPSK modulation includes a one-to-one mapping from Qm bits to 2 Qm complex modulation symbols, which is called the modulation mapping of RAPSK modulation.
- the modulation mapping of RAPSK modulation is Gray mapping, and the ma bits in the Qm bits are used to determine the radius of the concentric circle of the constellation point (that is, the amplitude of the constellation point), which is called the amplitude mapping bit (amplitude mapping bits); the other mp bits in the Qm bits are used to determine the phase of the constellation point, which are called phase mapping bits (phase mapping bits).
- the phase mapping bit number mp is a function of the modulation order Qm and the amplitude mapping bit number ma.
- the interval D between adjacent concentric circles is a function of the minimum circle radius r 0 and the number Na of concentric circles modulated by RAPSK.
- the value range of the interval D between adjacent concentric circles is a function of the modulation order Qm.
- mapping bits of RAPSK modulation is provided.
- the mp phase map bits c 1,0 , c 1,1 , ..., c 1,mp-1 can be determined in any of the following ways:
- phase mapping bits c 1 , 0 , c 1 , 1 , ..., c 1, mp-1 are the first mp bits in Qm bits b 0 , b 1 , ..., b Qm-1 ;
- phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the first mp bits in Qm bits b 0 , b 1 ,...,b Qm-1 , and the positions of bit b 0 and bit b 1 are exchanged;
- [c 1,0 , c 1,1 , . . . , c 1 , mp-1 ] [b 1 , b 0 , b 2 , b 3 , .
- phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the first 2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 and the odd-numbered bits in the last Qm-2 bits;
- the ma magnitude map bits c 2,0 , c 2,1 , ..., c 2,ma-1 may be determined in any of the following ways:
- the sign mapping bits d 1,0 are input bits for channel coding.
- the first part bits d 1,0 and d 1,1 are determined in any of the following ways:
- the first part of bits d 1,0 and d 1,1 are the first 2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the first part of bits d 1,0 and d 1,1 are the first 2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 , and the position of bit b 0 and bit b 1 exchanged;
- bits d 1,0 and d 1,1 are Qm bits b 0 , b 1 ,..., b Qm-1 in two bits indexed as ma and ma+1;
- Mode F1 the second part of bits d 2 , 0, d 2 , 1, ..., d 2, mp-3 are Qm bits b 0 , b 1 , ..., b
- the index in Qm-1 is 2 to bits of mp-1;
- Mode F3 the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is Qm bits b 0 , b 1 ,...,b Qm-1 after Qm-2 Bits with an odd index among bits;
- the third part bits d 3, 0 , d 3 , 1 , ..., d 3, ma-1 are the last ma among the Qm bits b 0 , b 1 , ..., b Qm-1 bit;
- the third part bits d 3,0 , d 3,1 ,...,d 3 ,ma-1 are the last Qm- The bit with an even index among the 2 bits;
- Gray mapping mode 1 of 2 bits g 0 and g 1 is shown in column (1) in Table 2, which can be expressed as:
- Gray mapping mode 1 of 3 bits g 0 , g 1 , and g 2 is shown in column (1) in Table 3, and can be expressed as:
- Gray mapping mode 1 of 5 bits g 0 , g 1 , g 2 , g 3 , and g 4 is shown in column (1) in Table 5, and can be expressed as:
- Gray mapping mode 1 of 6 bits g 0 , g 1 , g 2 , g 3 , g 4 , and g 5 is shown in column (1) in Table 6, and can be expressed as:
- Gray mapping mode 2 of 6 bits g 0 , g 1 , g 2 , g 3 , g 4 , and g 5 is shown in column (2) in Table 6, and can be expressed as:
- Gray mapping of column (2) in Table 1 above is the bit-wise inversion of column (1) in Table 1; the Gray mapping of column (2) in Table 2-Table 6 is in Table 2-Table 6 On the basis of column (1), it is obtained according to "keep bit g 0 unchanged, and invert other bits".
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 is the sequence number h obtained by following the 1-bit Gray mapping method 1;
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 is the sequence number h obtained by following the 2-bit Gray mapping method 1;
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 is the sequence number h obtained by following the 3-bit Gray mapping method 1;
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 is the sequence number h obtained by following the 5-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 is the sequence number h obtained by following the 1-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,..., c 2,ma-1 is the sequence number h obtained by following the 2-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 is the sequence number h obtained by following the 3-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 is the sequence number h obtained by following the 4-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 , ..., c 2,ma-1 is the sequence number h obtained by following the 5-bit Gray mapping method 1;
- Figures 3a-3f respectively show a method provided by an embodiment.
- the first example of the fourth exemplary embodiment after determining mp phase mapping bits and ma amplitude mapping bits, different Qm, mp , ma, Schematic diagram of the modulation mapping for the values of ⁇ * .
- the mp phase mapping bits in Fig. 3a-Fig. 3f are determined according to the method A1 in the above-mentioned second exemplary embodiment, and the ma amplitude mapping bits are determined according to the method B1 in the above-mentioned second exemplary embodiment definite.
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 is the sequence number h obtained by following the 2-bit Gray mapping method 2;
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 is the sequence number h obtained by following the 4-bit Gray mapping method 2;
- phase sequence number k obtained by mapping the phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 is the sequence number h obtained by following the 5-bit Gray mapping method 2;
- the ma amplitude mapping bits are mapped as:
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 is the sequence number h obtained by following the 1-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 is the sequence number h obtained by following the 2-bit Gray mapping method 2;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 is the sequence number h obtained by following the 3-bit Gray mapping method 2;
- the amplitude sequence number i obtained by mapping the amplitude mapping bits c 2,0 , c 2,1 , ..., c 2,ma-1 is the sequence number h obtained by following the 5-bit Gray mapping method 2;
- Figures 7a-7f respectively show a second example of the fourth exemplary implementation provided by an embodiment, after determining mp phase mapping bits and ma amplitude mapping bits, in different Qm, mp , ma, Schematic diagram of the modulation map for the values of ⁇ * .
- the mp phase mapping bits in Fig. 7a-Fig. 7f are determined according to the method A1 in the above-mentioned second exemplary embodiment, and the ma amplitude mapping bits are determined according to the method B1 in the above-mentioned second exemplary embodiment definite.
- Figures 8a-8f respectively show another method provided by an embodiment.
- the mp phase mapping bits in Figures 8a-8f are determined according to the method A2 in the above-mentioned second exemplary embodiment, and the ma amplitude mapping bits are determined according to the method B1 in the above-mentioned second exemplary embodiment definite.
- Figures 9a-9f respectively show another method provided by an embodiment.
- the second example of the fourth exemplary embodiment after determining mp phase mapping bits and ma amplitude mapping bits, at different Qm, Schematic diagram of modulation mapping for mp, ma, ⁇ * values.
- the mp phase mapping bits in Fig. 9a-9f are determined according to the method A3 in the above-mentioned second exemplary embodiment, and the ma amplitude mapping bits are determined according to the method B2 in the above-mentioned second exemplary embodiment definite.
- Fig. 10a-Fig. 10f respectively show another method provided by an embodiment.
- the second example of the fourth exemplary embodiment after determining mp phase mapping bits and ma amplitude mapping bits, at different Qm, Schematic diagram of modulation mapping for mp, ma, ⁇ * values.
- the mp phase mapping bits in Fig. 10a-Fig. 10f are determined according to the method A4 in the above-mentioned second exemplary embodiment, and the ma amplitude mapping bits are determined according to the method B3 in the above-mentioned second exemplary embodiment definite.
- the numbers next to each constellation point in Fig. 7a-Fig. 7f, Fig. 8a-Fig. 8f, Fig. 9a-Fig. 9f and Fig. 10a-Fig. 10f are b 0 , b 1 ,..., b Qm -1 according to the formula The converted decimal number.
- FIG. 5 In a fifth exemplary implementation manner, another manner of RAPSK constellation modulation mapping is provided.
- This embodiment describes the mapping method of RAPSK modulation on the basis of the third exemplary embodiment above.
- mp-2 bits d 2,0 , d 2,1 ,...,d 2,mp-3 and ma bits d 3,0 , d 3, 1 , . . . , d 3, ma-1 use the same gray mapping method.
- mapping method of mp-2 second part bits is:
- the phase sequence number k obtained by mapping mp-3 is the sequence number h obtained by following the 2-bit Gray mapping method 1 ;
- phase number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 3-bit Gray mapping method 1 ;
- the phase number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 5-bit Gray mapping method 1 ;
- the phase sequence number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 6-bit Gray mapping method 1 .
- the amplitude sequence number i obtained by mapping the third part of bits d 3,0 , d 3,1 ,...,d 3,ma-1 is the sequence number h obtained by following the 2-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the third part of bits d 3,0 , d 3,1 ,...,d 3,ma-1 is the sequence number h obtained by following the 3-bit Gray mapping method 1;
- Figures 13a-13c respectively show yet another method provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits and ma Schematic diagram of modulation mapping for different Qm, mp, ma values after amplitude mapping bits are determined according to the method E3 in the above-mentioned third exemplary embodiment
- the mp-2 phase mapping bits are determined according to the above-mentioned third exemplary embodiment determined in manner F2 in the above-mentioned third exemplary embodiment
- the ma amplitude mapping bits are determined in accordance with manner G2 in the above-mentioned third exemplary embodiment.
- Figures 14a-14c respectively show another method provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits and ma Schematic diagram of modulation mapping for different Qm, mp, ma values after amplitude mapping bits are determined according to the method E1 in the above-mentioned third exemplary embodiment
- the mp-2 phase mapping bits are determined according to the above-mentioned third exemplary embodiment determined in manner F3 in the above-mentioned third exemplary embodiment
- the ma amplitude mapping bits are determined in accordance with manner G3 in the above-mentioned third exemplary embodiment.
- mapping method of mp-2 second part bits is:
- phase sequence number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 1-bit Gray mapping method 1 ;
- the phase sequence number k obtained by mapping mp-3 is the sequence number h obtained by following the 2-bit Gray mapping method 2 ;
- phase number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 3-bit Gray mapping method 2 ;
- phase number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 4-bit Gray mapping method 2 ;
- the phase number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 5-bit Gray mapping method 2 ;
- the phase number k obtained by mapping the second part of bits d 2,0 , d 2,1 ,...,d 2,mp-3 is the sequence number h obtained by following the 6-bit Gray mapping method 2 .
- mapping method of the ma third part bits is:
- the amplitude sequence number i obtained by mapping the third part of bits d 3,0 , d 3,1 ,...,d 3,ma-1 is the sequence number h obtained by following the 1-bit Gray mapping method 1;
- the amplitude sequence number i obtained by mapping the third part of bits d 3,0 , d 3,1 ,...,d 3,ma-1 is the sequence number h obtained by following the 2-bit Gray mapping method 2;
- the amplitude sequence number i obtained by mapping the third part of bits d 3,0 , d 3,1 ,...,d 3,ma-1 is the sequence number h obtained by following the 3-bit Gray mapping method 2;
- the amplitude sequence number i obtained by mapping the third part of bits d 3,0 , d 3,1 ,...,d 3,ma-1 is the sequence number h obtained by following the 4-bit Gray mapping method 2;
- Figures 15a-15c respectively show a method provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits and ma Schematic diagram of modulation mapping at different Qm, mp, ma values after amplitude mapping bits are determined according to the method E1 in the above-mentioned third exemplary embodiment
- the mp-2 phase mapping bits are determined according to the above-mentioned third exemplary embodiment determined in the manner F1 in the above-mentioned third exemplary embodiment
- the ma amplitude mapping bits are determined in accordance with the manner G1 in the above-mentioned third exemplary embodiment.
- Figures 16a-16c respectively show another method provided by an embodiment.
- 2 sign mapping bits, mp-2 phase mapping bits and ma Schematic diagram of modulation mapping for different Qm, mp, ma values after amplitude mapping bits are determined according to the method E2 in the third exemplary embodiment above
- the mp-2 phase mapping bits are determined according to the third exemplary embodiment above determined in the manner F1 in the above-mentioned third exemplary embodiment
- the ma amplitude mapping bits are determined in accordance with the manner G1 in the above-mentioned third exemplary embodiment.
- Figures 17a-17c respectively show yet another method provided by an embodiment.
- determining 2 sign mapping bits, mp-2 phase mapping bits and ma Schematic diagram of modulation mapping for different Qm, mp, ma values after amplitude mapping bits Specifically, the 2 sign mapping bits in Fig. 17a-Fig. 17c are determined according to the method E3 in the above-mentioned third exemplary embodiment, and the mp-2 phase mapping bits are determined according to the above-mentioned third exemplary embodiment determined in manner F2 in the above-mentioned third exemplary embodiment, and the ma amplitude mapping bits are determined in accordance with manner G2 in the above-mentioned third exemplary embodiment.
- a characterization of a bit sequence to be modulated is provided.
- a series of bit sequences e 0 , e 1 , e 2 , ..., e E-1 of the transport block are interleaved into bit sequences f 0 , f 1 , f 2 , ... according to the following method , f E-1 .
- the above interleaving process arranges the bit sequences e 0 , e 1 , e 2 ,..., e E-1 into a matrix of Qm rows and E/Qm columns in the form of first row and second column, and then one-to-one correspondence to the first column and then row comparison
- the special sequences f 0 , f 1 , f 2 , ..., f E-1 are arranged on a matrix of Qm rows and E/Qm columns.
- the embodiment of the present application provides a data transmission method, including: obtaining the first bit sequence f 0 , f 1 , f 2 , ..., f E-1 ; based on the regular amplitude phase shift keying RAPSK constellation, the first Each Qm bit in the bit sequence f 0 , f 1 , f 2 ,..., f E-1 is mapped to a complex modulation symbol, and the symbol sequence x 0 , x 1 , x 2 ,..., x E /Qm-1 , E is the length of the first bit sequence, and E is a positive integer, Qm is the modulation order of RAPSK modulation, and the RAPSK constellation has 2 Qm constellation points; send the symbol sequence x 0 to the second communication node, x 1 , x 2 , .
- the processing module 10 is configured to obtain the first bit sequence f 0 , f 1 , f 2 , ..., f E-1 ; and based on the regular amplitude phase shift keying RAPSK constellation, the first bit sequence f 0 , f 1 , f 2 ,..., every Qm bits in f E-1 are mapped to a complex modulation symbol, and the symbol sequence x 0 , x 1 , x 2 ,..., x E/Qm-1 is obtained, and E is The length of the first bit sequence, and E is a positive integer, Qm is the modulation order of RAPSK modulation, and the RAPSK constellation has 2 Qm constellation points;
- the data transmission device provided in this embodiment implements the data transmission method in the embodiment shown in FIG. 1 .
- the implementation principle and technical effect of the data transmission device provided in this embodiment are similar to those of the above-mentioned embodiments, and will not be repeated here.
- the RAPSK constellation includes at least one of the following features:
- the mp phase map bits c 1,0 , c 1,1 , ..., c 1,mp-1 are determined in any of the following ways:
- Phase map bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the first mp bits of Qm bits b 0 , b 1 ,...,b Qm-1 , and bits The positions of b 0 and bit b 1 are exchanged;
- the ma magnitude map bits c 2,0 , c 2,1 , ..., c 2,ma-1 are determined in any of the following ways:
- Amplitude map bits c 2,0 , c 2,1 ,...,c 2,ma-1 are the first ma bits of the Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the Qm bits of a complex modulation symbol x include a first part of bits, a second part of bits and a third part of bits;
- the first part of bits d 1,0 and d 1,1 are determined according to any of the following methods:
- bits d 1, 0 and d 1, 1 are the first 2 bits in Qm bits b 0 , b 1 ,..., b Qm-1 ;
- Bits d 1,0 and d 1,1 of the first part are the first 2 bits in Qm bits b 0 , b 1 ,...,b Qm-1 , and the positions of bit b 0 and bit b 1 are exchanged ;
- the first part of bits d 1,0 and d 1,1 are the two bits with indexes ma and ma+1 among the Qm bits b 0 , b 1 , . . . , b Qm-1 .
- the second part bits d 2,0 , d 2,1 , ..., d 2,mp-3 are determined according to any of the following methods:
- the second part bits d 2,0 ,d 2,1 ,...,d 2,mp-3 are Qm bits b 0 ,b 1 ,...,b indexed 2 to mp-1 in Qm-1 bit;
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are the last mp-2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are the Qm bits b 0 , b 1 ,...,b in the last Qm-2 bits of Qm -1 Odd-indexed bits.
- the third part bits d 3,0 , d 3,1 , . . . , d 3,ma-1 are determined according to any of the following methods:
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the last ma bits in Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the first ma bits in Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the last Qm-2 bits in Qm bits b 0 , b 1 ,...,b Qm-1 Even-indexed bits in .
- mp phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 and ma amplitude mapping bits c 2,0 , c 2, 1 , . . . , c 2, ma-1 use the same Gray mapping method.
- mp-2 bits d 2,0 , d 2,1 , . . . , d 2,mp-3 and ma bits d 3,0 , d 3, 1 , . . . , d 3, ma-1 use the same gray mapping method.
- the first K bits in the second bit sequence e 0 , e 1 , e 2 , ..., e E-1 are input bits of channel coding, 0 ⁇ K ⁇ E.
- FIG. 20 shows a schematic structural diagram of another data transmission device provided by an embodiment.
- the device may be configured in a UE or a base station. As shown in FIG. 20 , it includes: a communication module 20 .
- the communication module 20 is configured to receive the symbol sequence x 0 , x 1 , x 2 , ..., x E/Qm-1 sent by the first communication node, the symbol sequence x 0 , x 1 , x 2 , ..., x E/Qm-1 is the first communication node based on the regular amplitude phase shift keying RAPSK constellation, mapping every Qm bits in the first bit sequence f 0 , f 1 , f 2 ,..., f E-1 is obtained after one complex modulation symbol, E is the length of the first bit sequence, and E is a positive integer, Qm is the modulation order of RAPSK modulation, and the RAPSK constellation has 2 Qm constellation points.
- the data transmission device provided in this embodiment implements the data transmission method in the embodiment shown in FIG. 2 .
- the implementation principle and technical effect of the data transmission device provided in this embodiment are similar to those of the above-mentioned embodiments, and will not be repeated here.
- the RAPSK constellation includes at least one of the following features:
- the mp phase map bits c 1,0 , c 1,1 , ..., c 1,mp-1 are determined in any of the following ways:
- Phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the first mp bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- Phase map bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the first mp bits of Qm bits b 0 , b 1 ,...,b Qm-1 , and bits The positions of b 0 and bit b 1 are exchanged;
- Phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the last mp bits in Qm bits b 0 , b 1 ,...,b Qm-1 ;
- Phase mapping bits c 1,0 , c 1,1 ,...,c 1,mp-1 are the first 2 bits and the last Qm of Qm bits b 0 , b 1 ,...,b Qm-1 - Odd-indexed bits among the 2 bits.
- the ma magnitude map bits c 2,0 , c 2,1 , ..., c 2,ma-1 are determined in any of the following ways:
- Amplitude mapping bits c 2,0 , c 2,1 ,...,c 2,ma-1 are the last ma bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- Amplitude map bits c 2,0 , c 2,1 ,...,c 2,ma-1 are the first ma bits of the Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the Qm bits of a complex modulation symbol x include a first part of bits, a second part of bits and a third part of bits;
- bits d 1, 0 and d 1, 1 are the first 2 bits in Qm bits b 0 , b 1 ,..., b Qm-1 ;
- Bits d 1,0 and d 1,1 of the first part are the first 2 bits in Qm bits b 0 , b 1 ,...,b Qm-1 , and the positions of bit b 0 and bit b 1 are exchanged ;
- the second part bits d 2,0 , d 2,1 , ..., d 2,mp-3 are determined according to any of the following methods:
- the second part bits d 2,0 ,d 2,1 ,...,d 2,mp-3 are Qm bits b 0 ,b 1 ,...,b indexed 2 to mp-1 in Qm-1 bit;
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are the last mp-2 bits of Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the second part bits d 2,0 , d 2,1 ,...,d 2,mp-3 are the Qm bits b 0 , b 1 ,...,b in the last Qm-2 bits of Qm -1 Odd-indexed bits.
- the third part bits d 3,0 , d 3,1 , . . . , d 3,ma-1 are determined according to any of the following methods:
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the last ma bits in Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the first ma bits in Qm bits b 0 , b 1 ,...,b Qm-1 ;
- the third part bits d 3,0 , d 3,1 ,...,d 3,ma-1 are the last Qm-2 bits in Qm bits b 0 , b 1 ,...,b Qm-1 Even-indexed bits in .
- mp phase mapping bits c 1,0 , c 1,1 , ..., c 1,mp-1 and ma amplitude mapping bits c 2,0 , c 2, 1 , . . . , c 2, ma-1 use the same Gray mapping method.
- mp-2 bits d 2,0 , d 2,1 , . . . , d 2,mp-3 and ma bits d 3,0 , d 3, 1 , . . . , d 3, ma-1 use the same gray mapping method.
- An embodiment of the present application further provides a communication node, including: a processor, configured to implement the method provided in any embodiment of the present application when executing a computer program.
- the device may be the first communication node (such as a base station or UE) provided in any embodiment of the present application, or it may be the second communication node (such as a UE or a base station) provided in any embodiment of the present application. There is no specific limitation on this.
- the following embodiments provide a schematic structural diagram in which communication nodes are a base station and a UE.
- Figure 21 shows a schematic structural diagram of a base station provided by an embodiment, as shown in Figure 21, the base station includes a processor 60, a memory 61 and a communication interface 62; the number of processors 60 in the base station can be one or more
- a processor 60 is taken as an example; the processor 60, memory 61, and communication interface 62 in the base station can be connected through a bus or in other ways.
- the connection through a bus is taken as an example.
- Bus refers to one or more of several types of bus structures, including a memory bus or memory controller, a peripheral bus, an accelerated graphics port, a processor, or a local bus using any of a variety of bus structures.
- the communication interface 62 can be configured to receive and send data.
- FIG. 22 shows a schematic structural diagram of a UE provided by an embodiment.
- the UE can be implemented in various forms.
- the UE in this application can include but not limited to mobile phones, smart phones, notebook computers, and digital broadcast receivers. , personal digital assistant (Personal Digital Assistant, PDA), tablet computer (Portable Device, PAD), portable multimedia player (Portable Media Player, PMP), navigation device, vehicle-mounted terminal equipment, vehicle-mounted display terminal, vehicle-mounted electronic rearview mirror, etc. and mobile terminal equipment such as digital television (television, TV), desktop computers, and other fixed terminal equipment.
- PDA Personal Digital Assistant
- PAD Portable Device
- PMP portable multimedia player
- navigation device vehicle-mounted terminal equipment
- vehicle-mounted display terminal vehicle-mounted display terminal
- vehicle-mounted electronic rearview mirror etc.
- mobile terminal equipment such as digital television (television, TV), desktop computers, and other fixed terminal equipment.
- the wireless communication unit 51 allows radio communication between the UE 50 and a base station or a network.
- A/V input unit 52 is configured to receive audio or video signals.
- the user input unit 53 can generate key input data to control various operations of the UE 50 according to commands input by the user.
- the sensing unit 54 detects the current state of the UE 50, the position of the UE 50, the presence or absence of the user's touch input to the UE 50, the orientation of the UE 50, the acceleration or deceleration movement and direction of the UE 50, etc., and generates 50 commands or signals for operation.
- the interface unit 57 serves as an interface through which at least one external device can be connected with the UE 50.
- the output unit 55 is configured to provide output signals in a visual, audio and/or tactile manner.
- the memory 56 may store software programs and the like for processing and control operations executed by the processor 58, or may temporarily store data that has been output or will be output.
- the memory 56 may include at least one type of storage media.
- the UE 50 may cooperate with a network storage device performing a storage function of the memory 56 through a network connection.
- Processor 58 generally controls the overall operation of UE 50.
- the power supply unit 59 receives external power or internal power and supplies appropriate power required to operate various elements and components under the control of the processor 58 .
- the embodiment of the present application also provides a computer-readable storage medium, on which a computer program is stored, and when the computer program is executed by a processor, the method provided in any embodiment of the present application is implemented.
- Computer-readable storage media include (non-exhaustive list): electrical connections with one or more conductors, portable computer disks, hard disks, Random Access Memory (RAM), Read-Only Memory (Read-Only Memory) , ROM), erasable programmable read-only memory (electrically erasable, programmable Read-Only Memory, EPROM), flash memory, optical fiber, portable compact disk read-only memory (Compact Disc Read-Only Memory, CD-ROM), optical storage components, magnetic storage devices, or any suitable combination of the above.
- a computer-readable storage medium may be any tangible medium that contains or stores a program that can be used by or in conjunction with an instruction execution system, apparatus, or device.
- a computer readable signal medium may include a data signal carrying computer readable program code in baseband or as part of a carrier wave. Such propagated data signals may take many forms, including but not limited to electromagnetic signals, optical signals, or any suitable combination of the foregoing.
- a computer-readable signal medium may also be any computer-readable medium other than a computer-readable storage medium, which can send, propagate, or transmit a program for use by or in conjunction with an instruction execution system, apparatus, or device. .
- Computer program code for performing the operations of the present disclosure may be written in one or more programming languages, or a combination of programming languages, including object-oriented programming languages such as Java, Smalltalk, C++, Ruby, Go), also includes conventional procedural programming languages (such as the "C" language or similar programming languages).
- the program code may execute entirely on the user's computer, partly on the user's computer, as a stand-alone software package, partly on the user's computer and partly on a remote computer or entirely on the remote computer or server.
- the remote computer can be connected to the user's computer through any kind of network, including a Local Area Network (LAN) or a Wide Area Network (WAN), or it can be connected to an external computer such as use an Internet service provider to connect via the Internet).
- LAN Local Area Network
- WAN Wide Area Network
- Computer program instructions may be assembly instructions, Instruction Set Architecture (ISA) instructions, machine instructions, machine-related instructions, microcode, firmware instructions, state setting data, or written in any combination of one or more programming languages source or object code.
- ISA Instruction Set Architecture
- Any logic flow block diagrams in the drawings of the present application may represent program steps, or may represent interconnected logic circuits, modules and functions, or may represent a combination of program steps and logic circuits, modules and functions.
- Computer programs can be stored on memory.
- the memory may be of any type suitable to the local technical environment and may be implemented using any suitable data storage technology, such as, but not limited to, read-only memory (ROM), random-access memory (RAM), optical memory devices and systems (digital versatile disc DVD or CD), etc.
- Computer readable media may include non-transitory storage media.
- Data processors can be of any type suitable for the local technical environment, such as but not limited to general purpose computers, special purpose computers, microprocessors, digital signal processors (Digital Signal Processing, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC ), programmable logic devices (Field-Programmable Gate Array, FGPA), and processors based on multi-core processor architectures.
- DSP Digital Signal Processing
- ASIC Application Specific Integrated Circuit
- FGPA programmable logic devices
- processors based on multi-core processor architectures such as but not limited to general purpose computers, special purpose computers, microprocessors, digital signal processors (Digital Signal Processing, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC ), programmable logic devices (Field-Programmable Gate Array, FGPA), and processors based on multi-core processor architectures.
- DSP Digital Signal Processing
- ASIC Application Specific Integrated Circuit
- FGPA programmable logic devices
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Abstract
Description
序号 | (1) | (2) |
h | g 0 | g 0 |
0 | 0 | 1 |
1 | 1 | 0 |
Claims (24)
- 一种数据传输方法,应用于第一通信节点,包括:获取第一比特序列f 0,f 1,f 2,...,f E-1;基于规则幅度相移键控RAPSK星座,将所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特映射为一个复数调制符号,得到符号序列x 0,x 1,x 2,...,x E/Qm-1,E为所述第一比特序列的长度、且E为正整数,Qm为RAPSK调制的调制阶数,所述RAPSK星座具有2 Qm个星座点;向第二通信节点发送所述符号序列x 0,x 1,x 2,...,x E/Qm-1。
- 根据权利要求1所述的方法,其中,所述RAPSK星座包括以下特征中的至少之一:所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上,ma为幅度映射比特数,ma=Qm/2-1;所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上、且每个同心圆上具有Np=2 mp个星座点,ma为幅度映射比特数,mp为相位映射比特数,mp=Qm-ma;所述RAPSK星座的每个同心圆上具有Np=2 mp个星座点,mp为相位映射比特数,mp=Qm/2+1;所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上、且编号为i的同心圆的半径r i=r 0+i·D,i=0,1,...,Na-1,ma为幅度映射比特数,r 0为最小圆半径,D为相邻同心圆之间的间隔,r 0的取值范围是Qm的函数;所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上、且编号为i的同心圆的半径r i=r 0+i·D,i=0,1,...,Na-1,ma为幅度映射比特数,r 0为最小圆半径,D为相邻同心圆之间的间隔,D的取值范围是Qm的函数。
- 根据权利要求2所述的方法,其中,所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特[f k·Qm,f 1+k·Qm,f 2+k·Qm,...,f Qm-1+k·Qm]=[b 0,b 1,...,b Qm-1]映射为一个复数调制符号x k=x,k=0,1,...,E/Qm-1;mp个相位映射比特c 1,0,c 1,1,...,c 1,mp-1根据以下任一方式确定:相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前mp个比特;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前mp个比特,且比特b 0和比特b 1的位置进行了交换;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的后mp个比特;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特和后Qm-2个比特中索引为奇数的比特。
- 根据权利要求2所述的方法,其中,所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特[f k·Qm,f 1+k·Qm,f 2+k·Qm,...,f Qm-1+k·Qm]=[b 0,b 1,...,b Qm-1]映射为一个复数调制符号x k=x,k=0,1,...,E/Qm-1;ma个幅度映射比特c 2,0,c 2,1,...,c 2,ma-1根据以下任一方式确定:幅度映射比特c 2,0,c 2,1,...,c 2,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的后ma个比特;幅度映射比特c 2,0,c 2,1,...,c 2,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的前ma个比特;幅度映射比特c 2,0,c 2,1,...,c 2,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的后Qm-2个比特中索引为偶数的比特。
- 根据权利要求2所述的方法,其中,所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特[f k·Qm,f 1+k·Qm,f 2+k·Qm,...,f Qm-1+k·Qm]=[b 0,b 1,...,b Qm-1]映射为一个复数调制符号x k=x,k=0,1,...,E/Qm-1;一个复数调制符号x的Qm个比特包括第一部分比特、第二部分比特和第三部分比特;所述第一部分比特包括两个正负号映射比特d 1,0和d 1,1;所述第二部分比特包括mp-2个比特d 2,0,d 2,1,...,d 2,mp-3;所述第三部分比特包括ma=Qm-mp个比特d 3,0,d 3,1,...,d 3,ma-1;其中,2≤mp<Qm。
- 根据权利要求5所述的方法,其中,所述第一部分比特d 1,0和d 1,1根据以下任一方式确 定:所述第一部分比特d 1,0和d 1,1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特;所述第一部分比特d 1,0和d 1,1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特,且比特b 0和比特b 1的位置进行了交换;所述第一部分比特d 1,0和d 1,1为Qm个比特b 0,b 1,...,b Qm-1中索引为ma和ma+1的两个比特。
- 根据权利要求5所述的方法,其中,所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3根据以下任一方式确定:所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3为Qm个比特b 0,b 1,...,b Qm-1中索引为2到mp-1的比特;所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3为Qm个比特b 0,b 1,...,b Qm-1中的后mp-2个比特;所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3为Qm个比特b 0,b 1,...,b Qm-1中后Qm-2个比特中索引为奇数的比特。
- 根据权利要求5所述的方法,其中,所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1根据以下任一方式确定:所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的后ma个比特;所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的前ma个比特;所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的后Qm-2个比特中索引为偶数的比特。
- 根据权利要求2所述的方法,其中,当mp或ma大于1时,mp个相位映射比特c 1,0,c 1,1,...,c 1,mp-1和ma个幅度映射比特c 2,0,c 2,1,...,c 2,ma-1使用相同的格雷映射方式。
- 根据权利要求2所述的方法,其中,当mp-2或ma大于1时,mp-2个比特d 2,0,d 2,1,...,d 2,mp-3和ma个比特d 3,0,d 3,1,...,d 3,ma-1使用相同的格雷映射方式。
- 根据权利要求1所述的方法,其中,所述获取第一比特序列f 0,f 1,f 2,...,f E-1,包括:从传输块中获取第二比特序列e 0,e 1,e 2,...,e E-1;对所述第二比特序列e 0,e 1,e 2,...,e E-1进行比特交织,得到所述第一比特序列f 0,f 1,f 2,...,f E-1。
- 根据权利要求11所述的方法,其中,所述第二比特序列e 0,e 1,e 2,...,e E-1中的前K个比特是信道编码的输入比特,0<K<E。
- 一种数据传输方法,应用于第二通信节点,包括:接收第一通信节点发送的符号序列x 0,x 1,x 2,...,x E/Qm-1,所述符号序列x 0,x 1,x 2,...,x E/Qm-1是所述第一通信节点基于规则幅度相移键控RAPSK星座,将所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特映射为一个复数调制符号后得到的,E为所述第一比特序列的长度、且E为正整数,Qm为RAPSK调制的调制阶数,所述RAPSK星座具有2 Qm个星座点。
- 根据权利要求13所述的方法,其中,所述RAPSK星座包括以下特征中的至少之一:所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上,ma为幅度映射比特数,ma=Qm/2-1;所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上、且每个同心圆上具有Np=2 mp个星座点,ma为幅度映射比特数,mp为相位映射比特数,mp=Qm-ma;所述RAPSK星座的每个同心圆上具有Np=2 mp个星座点,mp为相位映射比特数,mp=Qm/2+1;所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上、且编号为i的同心圆的半径r i=r 0+i·D,i=0,1,...,Na-1,ma为幅度映射比特数,r 0为最小圆半径,D为相邻同心圆之间的间隔,r 0的取值范围是Qm的函数;所述RAPSK星座中的所有星座点位于Na=2 ma个同心圆上、且编号为i的同心圆的半径r i=r 0+i·D,i=0,1,...,Na-1,ma为幅度映射比特数,r 0为最小圆半径,D为相邻同心圆之间的间隔,D的取值范围是Qm的函数。
- 根据权利要求14所述的方法,其中,所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特[f k·Qm,f 1+k·Qm,f 2+k·Qm,...,f Qm-1+k·Qm]=[b 0,b 1,...,b Qm-1]映射为一个复数调制符号x k=x,k=0,1,...,E/Qm-1;mp个相位映射比特c 1,0,c 1,1,...,c 1,mp-1根据以下任一方式确定:相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前mp个比特;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前mp个比特,且比特b 0和比特b 1的位置进行了交换;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的后mp个比特;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特和后Qm-2个比特中索引为奇数的比特。
- 根据权利要求14所述的方法,其中,所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特[f k·Qm,f 1+k·Qm,f 2+k·Qm,...,f Qm-1+k·Qm]=[b 0,b 1,...,b Qm-1]映射为一个复数调制符号x k=x,k=0,1,...,E/Qm-1;mp个相位映射比特c 1,0,c 1,1,...,c 1,mp-1根据以下任一方式确定:相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前mp个比特;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前mp个比特,且比特b 0和比特b 1的位置进行了交换;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的后mp个比特;相位映射比特c 1,0,c 1,1,...,c 1,mp-1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特和后Qm-2个比特中索引为奇数的比特。
- 根据权利要求14所述的方法,其中,所述第一比特序列f 0,f 1,f 2,...,f E-1中的每Qm个比特[f k·Qm,f 1+k·Qm,f 2+k·Qm,...,f Qm-1+k·Qm]=[b 0,b 1,...,b Qm-1]映射为一个复数调制符号x k=x,k=0,1,...,E/Qm-1;一个复数调制符号x的Qm个比特包括第一部分比特、第二部分比特和第三部分比特;所述第一部分比特包括两个正负号映射比特d 1,0和d 1,1;所述第二部分比特包括mp-2个比特d 2,0,d 2,1,...,d 2,mp-3;所述第三部分比特包括ma=Qm-mp个比特d 3,0,d 3,1,...,d 3,ma-1;其中,2≤mp<Qm。
- 根据权利要求17所述的方法,其中,所述第一部分比特d 1,0和d 1,1根据以下任一方式确定:所述第一部分比特d 1,0和d 1,1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特;所述第一部分比特d 1,0和d 1,1为Qm个比特b 0,b 1,...,b Qm-1中的前2个比特,且比特b 0和比特b 1的位置进行了交换;所述第一部分比特d 1,0和d 1,1为Qm个比特b 0,b 1,...,b Qm-1中索引为ma和ma+1的两个比特。
- 根据权利要求17所述的方法,其中,所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3根据以下任一方式确定:所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3为Qm个比特b 0,b 1,...,b Qm-1中索引为2到mp-1的比特;所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3为Qm个比特b 0,b 1,...,b Qm-1中的后mp-2个比特;所述第二部分比特d 2,0,d 2,1,...,d 2,mp-3为Qm个比特b 0,b 1,...,b Qm-1中后Qm-2个比特中索引为奇数的比特。
- 根据权利要求17所述的方法,其中,所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1根据以下任一方式确定:所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的后ma个比特;所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的前ma个比特;所述第三部分比特d 3,0,d 3,1,...,d 3,ma-1为Qm个比特b 0,b 1,...,b Qm-1中的后Qm-2个比特中索引为偶数的比特。
- 根据权利要求14所述的方法,其中,当mp或ma大于1时,mp个相位映射比特c 1,0,c 1,1,...,c 1,mp-1和ma个幅度映射比特c 2,0,c 2,1,...,c 2,ma-1使用相同的格雷映射方式。
- 根据权利要求14所述的方法,其中,当mp-2或ma大于1时,mp-2个比特d 2,0,d 2,1,...,d 2,mp-3和ma个比特d 3,0,d 3,1,...,d 3,ma-1使用相同的格雷映射方式。
- 一种通信节点,包括:处理器;所述处理器用于在执行计算机程序时实现如权利要求1-12中任一所述的数据传输方法,或 者,所述处理器用于在执行计算机程序时实现如权利要求13-22中任一所述的数据传输方法。
- 一种计算机可读存储介质,存储有计算机程序,所述计算机程序被处理器执行时实现如权利要求1-12中任一所述的数据传输方法,或者实现如权利要求13-22中任一所述的数据传输方法。
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