Indian Patents. 265854:A METHOD OF UTILIZING AND MANIPULATING WIRELESS RESOURCES FOR EFFICIENT AND EFFECTIVE WIRELESS COMMUNICATION

Title of Invention	A METHOD OF UTILIZING AND MANIPULATING WIRELESS RESOURCES FOR EFFICIENT AND EFFECTIVE WIRELESS COMMUNICATION
Abstract	A method of allocating symbols in a wireless communication system is disclosed. More specifically, the method includes receiving at least one data stream from at least one user, grouping the at least one data streams into at least one group, wherein each group is comprised of at least one data stream, precoding each group of data streams in multiple stages, and allocating the precoded symbols.

Full Text	A METHOD OF UTILIZING AND MANIPULATING WIRELESS RESOURCES FOR EFFICIENT AND EFFECTIVE WIRELESS COMMUNICATION TECHNICAL FIELD The present invention relates to a method of using wireless resources, and more particularly, to a method of utilizing and manipulating wireless resources for efficient and effective wireless communication. BACKGROUND ART In the world of cellular telecommunications, those skilled in the art often use the terms 1G, 2G, and 3G. The terms refer to the generation of the cellular technology used. 1G refers to the first generation, 2G to the second generation, and 3 G to the third generation. 1G refers to the analog phone Systran, known as an AMPS (Advanced Mobile Phone Service) phone systems. 2G is commonly used to refer to the digital cellular systems that are prevalent throughout the world, and include CDMAOne, Global System for Mobile communications (GSM), and Time Division Multiple Access (TDMA). 2G systems can support a greater number of users in a dense area than can 1G systems. 3G commonly refers to the digital cellular systems cutrsatiy being deployed. These 3G communication systems are conceptually similar to each other with some significant differences. In a wireless communication system, an effective transmission of data crucial and at the same time, it is important to improve transmission efficiency. To this end, it is important that more efficient ways of transmitting and receiving data are developed. DISCLOSURE Accordingly, the present invention is directed to a method of utilizing and manipulating wireless resources for efficient and effective wireless communication that substantially obviates one or more problems due to limitations and disadvantages of the related art. TECHNICAL PROBLEM An object of the present invention is to provide a method allocating symbols in a wireless communication system. Another object of the present invention is to provide a method of performing Merarcbical modulation signal constellation in a wireless communication system. A further object of the present invention is to provide a method of transmitting more than one signal in a wireless communication system. TECHNTrAL SOLUTION To achieve these objects and other advantages and in accordance with the purpose of the invention, as embodied and broadly described herein, a method of allocating symbols in a wireless communication system includes receiving at least one data stream from at least one user, grouping the at least one data streams into at least one group, wherein each group is comprised of at least one data stream, precoding each group of data streams in multiple stages, and allocating the precoded symbols- In another aspect of the present invention, a method of performing hierarchical modulation signal constellation in a wireless communication, system includes allocating multiple symbols according to a bits-to-symbol mapping rule representing different signal constellation points with different bits, wherein the mapping rule represents one (1) or less bit difference between closest two symbols. In a further aspect of the present invention, a method of transmitting more than one signal in a wireless communication system includes allocating multiple symbols to a first signal constellation and to a second constellation, wherein the first signal constellation refers to base layer signals and the second signal constellation refers to enhancement layer signals, modulating the multiple symbols of the first signal constellation and the second signal constellation, and transmitting the modulated symbols. ADVANTAGES EFFECTS Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of th.e following or may be learned from practice of the invention. The objectives and other advantages of the invention may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings. It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments) of the invention and together with the description serve to explain the principle of the invention. In the drawings; FIG-1 is an exemplary diagram of a generalized MC-CDM structure; FIG. 2 is another exemplary diagram of a generalized MC-CDM structure; FIG. 3 is an exemplary diagram illustrating a generalized MC-CDM structure in which precoding/rotation is performed on groups; FIG. 4 is an exemplary diagram illustrating a multi-stage rotation; FIG. 5 is another exemplary diagram of a generalized MC-CDM structure; FIG. 6 is an exemplary diagram illustrating frequency-domain interlaced MC-CDM; FIG. 7 is an exemplary diagram illustrating an example of Gray coding; FIG. 8 is an exemplary diagram illustrating mapping for regular QPSK/QPSK hierarchical modulation or 16QAM modulation; FIG. 9 is an exemplary diagram illustrating bits-to-symbol mapping for I6QAM/QPSK; FIG. 10 is another exemplary diagram illustrating bits-to-symbol mapping for 16QAM/QPSK; FIG. 11 is another exemplary diagram illustrating; bits-to-symbol mapping for 16QAM/QPSK; FIG. 12 is another exemplary diagram illustrating bits-to-symbol mapping for 16QAM/QPSK; FIG. 13 is an exemplary diagram illustrating bits-to-symbol mapping for QPSK/QPSK; FIG. 14 is an exemplary diagram illustrating an enhancement layer bits-to-symbol for base layer 0x0; FIG. 15 is an exemplary diagram illustrating an enhancement layer bits-to-symbol for base layer 0x1; FIG. 16 is an exemplary diagram showing the signal constellation of the layered modulator with respect to QPSK/QPSK hierarchical modulation; FIG. 17 is aa exemplary diagram illustrating the signal constellation of the layered modulator with respect to 16QAM/QPSK hierarchical modulation; FIG. 18 is an exemplary diagram showing the signal constellation for the layered modulator with QPSK/QPSK hierarchical modulation; FIG. 19 is an exemplary diagram illustrating the signal constellation of the layered modulator with respect to 16QAM/QPSK hierarchical modulation; FIG. 20 is an exemplary diagram illustrating signal constellation for layered modulation with QPSK base layer and QPSK enhancement layer, FIG. 21 is an exemplary diagram illustrating the signal constellation of the layered modulator with respect to 16QAM/QPSK hierarchical modulation; FIG. 22 is an exemplary diagram illustrating Gray mapping for rotated QPSK/QPSK hierarchical modulation; FIG. 23 is an exemplary diagram illustrating an enhanced QPSK/QPSK hierachical modulation; FIG. 24 is an exemplary diagram illustrating a new QPSK/QPSK hierarchical modulation; FIG. 25 is another exemplary diagram illustrating a new QPSK/QPSK hierarchical modulation; and FIG. 26 is an exemplary diagram illustrating a new bit-to-symbol block. BEST MODE FOR CARRYING OUT THE INVENTION Reference will now be made in detail to the preferred embodiments of the present invention, examples of which ate illustrated in fee accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. An orthogonal frequency division multiplexing (OFDM) is a digital multi-carrier modulation scheme, which uses a large number of closely-spaced orthogonal sub-carriers. Each sub-carrier is usually modulated with a modulation scheme (e.g., quadrature plxase shift keying (QPSK)) at a low symbol rate while maintaining data rates similar to conventional single-carrier modulation schemes in the same bandwidth. The OFDM originally does not have frequency diversity effect, but it can obtain frequency diversity effect by use of forward error correction (FEC) even in a distributed mode. That is, the frequency diversity effect becomes low when the chapel coding rate is high. in view of this, multi-carrier code division multiplexing (MC-CDM) or a multi- carrier code division multiple access (MC-CDMA) with advanced receiver can be used to compensate for low frequency diversity effect due to high channel coding rate. The MC-CDM or MC-CDMA is a multiple access scheme used in OFDM-based system, allowing the system to support multiple users at the same time. In other words, the data can. be spread over a much wider bandwidth, than the data rate, a signal-to-noise and interference ratio can be minimized. For example, with respect to signal processing, a channel response for each OFDM tone (or signal or sub-carrier) can be modeled as identical independent complex Gaussian variable. By doing so and using MC-CDM, diversity gain and processing gain can be attained. Here, interference, such as inter-symbol interference (ISI) or multiples access interference (MAI), is temporarily omitted in part due to the cyclic prefix or zero padding employed by OFDM or MC-CDM. Figure 1 is an exemplary diagram of a generalized MC-CDM structure. Referring to Figure denotes the frequency response of fading channel, where \ is a complex Gaussian variable for the frequency-domain channel response of each sub-carrier. Furthermore, without loss of the generality, denote the unitary symbol precoding matrix with, power constraint \|α\|2 + \|β\|2 = 1. It can be taken a generalization of the classic MC-CDM. The processes of Figure 1 include channel coding followed by spreading and multiplexing (which can be represented by U). Thereafter, the multiplexed data is modulated by using the OFDM modulation scheme. At the receiving end, the OFDM modulated symbols are demodulated using OFDM demodulation scheme. They are then despread and detected, followed by channel decoding. Further to the generalized MC-CDM structure, other structures are available such as rotated MC-CDM, OFDM, rotational OFDM (R-OFDM), or Walsh-Hadamard MC-CDM. With respect to rotated MC-CDM, if α - cos(θ, ) and β = sin(θ ), then a real- value rotation matrix can be available as follows in Equation 1. Furthermore, with respect to OFDM, if αβ = 0 or αβ=0, then U2 becomes I2. In other words, U7 becomes uncoded OFDM or uncoded OFDMA. In addition, with respect to Walsh-Hadamard MC-CDM, if α = cos(/4) = √2/2 and β = sin(/4) = √2/2, U2 = R2 become a classic "Walsh-Hadamard matrix. i Figure 2 is another exemplary diagram of a generalized MC-CDM structure. In Figure 2, a plurality of data are inputted which are then precoded and/or rotated. Here, the precoding or rotation also can signify adjustment of the amplitude and/or phase of incoming data. With respect to precoding/rotation, different tones or sub-carriers may be precoded/rotated independently or jointly. Here, the joint precoding/rotation of the incoming data or data streams can be performed by using a single rotation matrix. Alternatively, different incoming data or data streams can be separated into multiple groups, where each group of data streams can be precoded/rotated independently or jointly. Figure 3 is an exemplary diagram illustrating a generalized MC-CDM structure in which precoding/rotation is performed on groups. Referring to Figure 3, multiple data or data streams are grouped into Data Stream(s) I, 2,..., K groups which, axe then precoded/rotated per group. Here, the precoding/rotation can include amplitude and/or phase adjustment, if necessary. Thereafter, the precoded/rotated symbols are mapped. Further, different rotation/precoding on different groups may lead to a mixture of OFDM, MC-CDM or R-OFDM. In addition, the rotation/precoding of each group may be based on the QoS requirement, the receiver profile, and/or the channel condition. Alternatively, instead of using a big precoding/rotation matrix, a smaller-sized precoding/rotation matrix can be dependency or independently applied to different'groups of incoming data streams. In operation, actual precoding/rotation operation can be performed in multiple stages. Figure 4 is an exemplary diagram illustrating a multi-stage rotation. Referring to Figure 4, multiple data or data streams are inputted which are then precoded/rotated. Here, these processed symbols can be grouped into at least two groups. Each group is represented by at least one symbol. With respect to rotation of the symbols, tile symbol(s) of each group can be spread using a spreading matrix. Here, the spreading matrix that is applied to a group may be different and can be configured. After the symbols are processed through the spreading matrix, then the output(s) can be re-grouped into at least two groups. Here, the re-grouped outputs comprise at least one selected output from each of the at least two groups. Thereafter, these re-grouped outputs can be spread again using the spreading matrix. Again, the spreading matrix that is applied to a group may be different and can be configured. After the outputs are processed through another spreading matrix, they are inputted to an. inverse fast Fourier transform (IFFT). A rotation scheme such as the multi-stage rotation can also be employed by a generalized MC-CDM or multi-carrier code division multiple access (MC-CDMA). Figure 5 is an exemplary diagram illustrating a general block of the MC-CDM. Figure 5 is another exemplary diagram of a generalized MC-CDM structure. More specifically, the processes as described with respect to Figure 5 are similar to those of Figure 1 except that Figure 5 is based on generalized MC-CDM or MC-CDMA that uses rotation (e.g., multi-stage rotation). Here, after channel coding, the coded data are rotated and/or multiplexed, followed by modulation using inverse discrete Fourier transform 0DFT)orIFFT. At the receiving end, the modulated symbols are demodulated using discrete Fourier transform (DFT) or fast Fourier transform (FFT). They are then despread and detected, followed by channel decoding. In addition, interlacing is available in the generalized MC-CDM. In Ix evolution data optimized (ixEV-DO) BCMCS and enhanced BCMCS (EBCMCS), the multipath delay spread is about Td = 3.7us and the coherent bandwidth is around Bc =1/Td = 270kHz. Therefore, the maximum frequency diversity order is This means, in order to capture the maximum frequency diversity here, the MC-CDM spreading gain L > 5 is possibly enough- Based on the above analysis, a frequency-domain interlaced MC-CDM can be used. Figure 6 is an exemplary diagram illustrating frequency-domain interlaced MC-CDM. Referring to Figure 6, each slot, indicated by different fills, can be one tone (or sub-carrier) or multiple consecutive tones (or sub-carriers). The tone(s) or sub-carrier(s) or symbol(s) can be rotated differently. In other words, the product distance, which can be defined as the product of Euclidean distances, can be maximized. In detail, a minimum product distance, which is used for optimizing modulation diversity, can be shown by the following equation. The minimum product distance can also be referred to as Euclidean distance tmnimization. Referring to Equation 3, sj EA denotes the transmitted symbols. Furthermore, optimization with maximizing the minimum production distance can be done by solving the following equation. [Equation 4] For example, for the traditional quadrature phase shift keying (QPSK), U1 (eJt ) can. be decided by calculating d(ejt=1/2 Δ2-(ejtΔ2)2 where A12 e{±l,±J,±l±j). As discussed, each tone or symbol pan be rotated differently. For example, a first symbol can be applied QPSK, a second symbol can be applied a binary phase shift keying (BPSK), and nth symbol can be applied 16 quadrature amplitude modulation (16QAM). To put differently, each tone or symbol has different modulation angle. Referring to Equation 3, the diversity can be denoted by , and the interference matrix can be denoted . Here, the interference matrix can be ISI or multiple access interference (MAI). A total diversity of the generalized MC-CDM can be represented as shown in Equation 7. Referring to Equation 4, the total diversity of the generalized MC-CDM is independent on the precoding matrix U. However, for each symbol or user, the diversity gain may be different to each. Further, the interference of the generalized MC-CDM can be represented as shown in Equation 8. Here, there is some self-interference or multi-user interference. In other words, due to frequency-selectivity in OFDM-liked orthogonal modulation, there is possible interference if some preceding or spreading is applied. Furthermore, it can be shown that this interference can be maximized when the rotation angel is 9 = /4. 4 In designing a MC-CDM transceiver, inter alia, an inter-symbol or multiple access signal-to-interference ratio (SIR) can be defined as follows. Referring to Equation 9 denotes the channel fading difference. The SIR can be defined based on channel fading and rotation. Rotation can also be performed based on receiver profile. This can be done through upper layer signaling. More specifically, at least two parameters can be configured, namely, spreading gain and rotation angle. In operation, a receiver can send feedback information containing its optimum rotation angle and/or rotation index. The rotation angle and/or rotation index can be mapped to the proper rotation angle by a transmitter based on a table (or index). This table or index is known by both the transmitter and the receiver. This can be done any time when it is the best time for the transmitter and/or receiver. For example, if the receiver (or access terminal) is registered with the network, it usually sends its profile to the network. This profile includes, inter alia, the rotation angle and/or index. Before the transmitter decides to send signals to the receiver, it may ask the receiver as to the best rotation angle. In response, the receiver can send the best rotation angle to the transmitter. Thereafter, the transmitter can send the signals based on the feedback information and its own decision. During transmission of the signals, the transmitter can periodically request from the receiver to send its updated rotation angle. Alternatively, the transmitter can request an update of the rotation angle from the receiver after the transmitter is finished transmitting. At any time, the receiver can send the update (or updated rotation angle) to the transmitter. The transmission of the update (or feedback information) can be executed through an access channel, traffic channel, control channel, or other possible channels. With respect to channel coding, coding can help minimize demodulation errors and therefore achieve the throughput in addition to signal design for higher spectral efficiency. In reality, most capacity-achieving codes are designed to balance the implementation complexity and achievable performance. Gray code is one of an example of channel coding which is also known as reflective binary code. Gray code or the reflective binary code is a binary numeral system where two successive values differ in only one digit. Figure 7 is an exemplary diagram illustrating an example of Gray coding. Gray code for bits-to-symbol mapping, also called Gray mapping, can be implemented with other channel coding scheme. Gray mapping is generally accepted as the optimal mapping rule for minimizing bit error rate (BER). Gray mapping for regular QPSK/QPSK hierarchical modulation (or 16QAM modulation) is shown in Figure 8 where the codewords with minimtan Euclid distance have minimum Hamming distance as well. In the figures to follow, the Gray mapping rule is described. More specifically, each enhancement layer bits-to-symbol and base layer bits-to-symbol satisfy the Gray mapping requirement where the closest two symbols only have difference of one or the least bit(s). Furthermore, the overall bits-to-symbol mapping rule satisfies the Gray mapping rule. Figure 8 is an exemplary diagram illustrating mapping for regular QPSK/QPSK hierarchical modulation or 16QAM modulation. Referring to Figure 8, the enhancement layer bits and the base layer bits can be arbitrarily combined so that every time when the base layer bits are detected, the enhancement layer bits-to-symbol mapping table/rule can be decided, for example. In addition, both the base layer and the enhancement layer are QPSK. Furthermore, every point (or symbol) is represented and/or mapped by bob1b2b3. More specifically, the circle in the center of the diagram and the lines connecting two (2) points (or symbols) (e.g., point 0011 and point 0001 or point 0110 and point 1110) represent connection with only one bit difference between neighbors. Here, the connected points are from different layers. In other words, every connected points (or symbol) are different base layer bits and enhancement layer bits. Furthermore, every point can be represented by four (4) bits (e.g., bob1b2b3) in which the first bit (bo) and the third bit (fa) represent the base layer bits, and the second bit (bi) and the fourth bit (b3) represent the enhancement bits. That is, two (2) bits from the base layer and the two (2) bits from the enhancement layer are interleaved together to represent every resulted point. By interleaving the bits instead of simple concatenation of the bits from two layers, additional diversity gain can be potentially attained. Figure 9 is an exemplary diagram illustrating bits-to-symbol mapping for 16QAM/QPSK. This figure refers to bits-to-symbol mapping. This mapping can be used by both the transmitter and the receiver. If a transmitter desires to send bits bob1b2b3b4b5s, the transmitter needs to look for a mapped symbol to send.' Hence, if a receiver desires to demodulate the received symbol, the receiver can use this figure to find/locate the demodulated bits. Furthermore, Figure 9 represents 16QAM/QPSK hierarchical modulation. In other words, the base layer is modulated by 16QAM, and the enhancement layer is modulated by QPSK. Moreover, 16QAM/QPSK can be referred to as a special hierarchical modulation. In other words, the base layer signal and the enhancement signal have different initial phase. For example, the base layer signal phase is 0 while the enhancement layer signal phase is theta (0). Every symbol in Figure 9 is represented by bits sequence, S5S4S3S2S1S0, in which bits S3 and So are bits from the enhancement layer while the other bits (e.g., S5, S4, S2, and S1) belong to the base layer. Figure 10 is another exemplary diagram illustrating bits-to-symbol mapping for 16QAM/QPSK. The difference between Figure 10 and previous Figure 9 is that every symbol in Figure 10 is represented by bits sequence, S5S4S3S2S1S0, in which bits S5 and S2 are bits from the enhancement layer while the other bits (e.g., S4, S3, S1, and So) are from the base layer. Figure 11 is another exemplary diagram illustrating bits-to-symbol mapping for 16QAM/QPSK. The difference between Figure 11 and previous Figures 9 and/or 10 is that every symbol in Figure 11 is represented by bits sequence, S5S4S3S2S1S0., in which bits S5 and S4 are bits from the enhancement layer while the other bits (e.g., S3, S2, s1, and so) are from the base layer. Figure 12 is another exemplary diagram illustrating bits-to-symbol mapping for 16QAM/QPSK. The difference between Figure 12 and previous Figures 9, 10, and/or 11 bits S5 and S2 are bits from the enhancement layer while the other bits (e.g., S4, S3, S1, and So) are from the base layer. As before, every symbol in Figure 12 is represented by bits sequence, S5S4S3S2S1S0.. Further to bits sequence combinations as discussed above, the following hierarchical layer and enhancement layer combination possibilities include (1) S5S4S3S2S1S0..= b3b2b1e1boeo, (2) S5S4S3S2S1S0..= b3e1b2b1boeo, (3) S5S4S3S2S1S0.. = b3e1b2b1boeo, (4) S5S4S3S2S1S0. = eoe1b3b2b1bo, (5)S5S4S3S2S1S0 - eob3b2e1b1bo, (6) S5S4S3S2S1S0. = b3b2eob1boe1, (7) s3s2sis0 = e1b1eobo, (8) S3S2S1so= eob1e1bo, (9) s3S2S1s0= e1eob1bOj (10) s3S2S1So= eoe1b1bo, and (11) s3S2S1So = b1boeoe1. In addition to the combinations discussions of above, there are many other possible combinations. However, they all follow the same rule which is the Gray rule or the Gray mapping rule. As discussed, each enhancement layer bits-to-symbol mapping and base layer bits-to-symbol mapping satisfy the Gray mapping rule requirement which is that the closest two symbols only have difference of one bit or less. Moreover, the overall bits-to-symbol mapping rule satisfies the Gray mapping rule as well. Further, the enhancement layer bits and the base layer bits can be arbitrarily combined so that every time the base layer bits are detected, the enhancement layer bits-to- symbol mapping table/rule can be decided. In addition, it is possible, for example, for S3S2S1So=e1eob1b0 QPSK7QPSK, the Gray mapping rule for enhancement layer S3S2I l=eieol 1 to be not the exactly the same as S3S2lO=eieolG. Moreover, for example, it is possible S3S2ll=e1eoll is a rotated version as s3s2l0=e1eol0, S3S211=1 Ill's position is the position of s3s2l 1=1010 or s3s2l 1=0110. Figure 13 is an exemplary diagram illustrating bits-to-symbol mapping for QPSK/QPSK. Referring to Figure 13, the bits-to-symbol mapping can be used by both the transmitter and the receiver. If a transmitter desires to send bits bob1b2b3, the transmitter needs to look for a mapped symbol to send. Hence, if a receiver desires to demodulate the received symbol, the receiver can use ibis figure to find/locate the demodulated bits. Furthermore, Figure 13 represents QPSK/QPSK hierarchical modulation. In other words, the base layer is modulated by QPSK, and the enhancement layer is also modulated by QPSK. Moreover, QPSK/QPSK can be referred to as a special hierarchical modulation. That is, the base layer signal and the enhancement signal have different initial phase. For example, the base layer signal phase is 0 while the enhancement layer signal phase is theta 0). Every symbol in Figure 13 is represented by bits sequence, s3s2s1s0, in which bits s5 and si are bits from the enhancement layer while the other bits (e.g., s2 and so) belong to the base layer. Further, in the QPSK/QPSK example, the enhancement layer bits-to-symbol mapping rules may be different from the base layer symbol-to-symbol. Figure 14 is an exemplary diagram illustrating an enhancement layer bits-to-symbol for base layer 0x0. In other words, Figure 14 illustrates an example of how the base layer bits are mapped. For example, the symbols indicated in the upper right quadrant denote the base layer symbols of '00'. This means that as long as the base layer bits are '00', whatever the enhancement layer is, Hie corresponding layer modulated symbol is one of the four (4) symbols of this quadrant. Figure 15 is an exemplary diagram illustrating an enhancement layer bits-to-symbol for base layer 0x1. Similarly, this diagram illustrates another example of how the base layer bits are mapped. For example, the symbols of in the upper left quadrant denote the base layer symbols of '01'. This means that as long as the base layer bits are '01', whatever the enhancement layer bits are, the corresponding layer modulated symbols is one of the symbols of the upper left quadrant. As discussed above with respect to Figures 1-3, the inputted data or data stream can be channel coded using the Gray mapping role, for example, followed by other processes including modulation- The modulation discussed here refers to layered (or superposition) modulation. The layered modulation is a type of modulation in which each modulation symbol has bits corresponding to both a base layer and an enhancement layer. In the discussions to follow, the layered modulation will be described in the context of broadcast and multicast services (BCMCS). In general, layered modulation can be a superposition of any two modulation schemes. In BCMCS, a QPSK enhancement layer is superposed on a base QPSK or 16- QAM layer to obtain the resultant signal constellation. The energy ratio r is the power ratio between the base layer and the enhancement. Furthermore, the enhancement layer is rotated by the angle Q in counter-clockwise direction. Figure 16 is an exemplary diagram, showing the signal constellation of the layered modulator with respect to QPSK/QPSK hierarchical modulation. Referring to QPSK/QPSK. hierarchical modulation, which means QPSK base layer and QPSK enhancement layer, each modulation symbol contains four (4) bits, namely, S3, S2, S1, S0. Here, there are two (2) most significant bits (MSBs) which are S3 and S2, and two (2) least significant bits (LSBs) which are S1 and so. The two (2) MSBs are from the base layer and the two LSBs come from the enhancement layer. Given energy ratio r between the base layer and enhancement layer and can be defined such that2 (a2+02) ~ 1. Here, a denotes the amplitude of the base layer, and J3 denotes the amplitude of enhancement layer. Moreover, 2(a2 + β2):=l is a constraint which is also referred to as power constraint and more accurately referred to as normalization. Table 1 illustrates a layered modulation table with QPSK. base layer and QPSK enhancement layer. [Table 1] Here, cos(2nfa t + 0, ) and sin(2nf0 t + a) denote the carrier signal with initial phase $, and carrier frequency f0 . Moreover, φ{t) denotes the pulse-shaping, the shape of a transmit symbol. In the above definition of S(t), except the mt and mQ value, other parameters can usually either be shared between the transmitter and the receiver or be detected by the receiver itself. For correctly demodulating s{t), it is necessary to define and share the possible value information of m7 and mQ. The possible value of ml (k) and mg (k), which denote the m, and mQ value for the kth symbol, are given in Table 1. It shows for representing each group inputs bits s3, s2, su so the symbol shall be modxjlated by corresponding parameters shown in me table. The discussion with respect to the complex modulation symbol can be applied in a similar or same manner to the following discussions of various layered modulations. That is, the above discussion of the complex modulation symbol can be applied to the tables to follow. Figure 17 is an exemplary diagram illustrating the signal constellation of the layered modulator with respect to 16QAM/QPSK hierarchical modulation. Referring to 16QAM/QPSK hierarchical modulation, which means 16QAM base layer and QPSK enhancement layer, each modulation symbol contains six 6 bits - s5, S4, S3, S2, s1, so. The four (4) MSBs, s5, S4, S3 and s2, come from the base layer, and the two (2) LSBs, S\ and so, come from the enhancement layer. Given energy ratio r between the base layer and enhancement layer, and can be defined such that2(ar2+fi2)=1. Here, a denotes the amplitude of the base layer, and fi denotes the amplitude of enhancement layer. Moreover, 2(α2+β2) = l is a constraint which is also referred to as power constraint and more accurately referred to as normalization. Table 2 illustrates a layered modulation table with 16QAM base layer and QPSK enhancement layer. [Table 2] Referring to Table 2, each column defines the symbol position for each six (6) bits, s5, s4, s3, s2, s1, so. Here, the position of each symbol is given in a two-dimensional signal space ( m1, , mQ ). This means that each symbol can be represented by Here, w0 denotes carrier frequency, na denotes an initial phase of the carrier, and 4>(t) denotes the symbol shaping or pulse shaping wave. Here, cos(2nf0 t + o) and sin(2nf t + Q) denote the carrier signal with initial phase 0 and carrier frequency f0 . Moreover, (t) denotes the pulse-shaping, the shape of a transmit symbol. In the above definition of S(t), except the m1, and mQ value, other parameters can usually either be shared between the transmitter and the receiver or be detected by the receiver itself. For correctly demodulating S(i), it is necessary to define and share the possible value information of m1 and mQ, The possible value of m1 (k) and mQ (k), which denote the m1 and mQ value for the kth symbol, are given, in Table 1. It shows for representing each group inputs bits ss, s4, s3, S2, s1, so the symbol shall be modulated by corresponding parameters shown in the table. Further, another application example for BCMCS for hierarchical modulation is discussed below. In general, layered modulation can be a superposition of any two modulation schemes. In BCMCS, a QPSK enhancement layer is superposed on a base QPSK or 16-QAM layer to obtain the resultant signal constellation. The energy ratio r is the power ratio between the base layer and the enhancement. Furthermore, the enhancement layer is rotated by the angle 9 in counter-clockwise direction. Figure 18 is an exemplary diagram showing the signal constellation for the layered modulator with QPSK/QPSK hierarchical modulation. Referring to QPSK/QPSK hierarchical modulation, which means QPSK base layer and QPSK enhancement layer, each modulation symbol contains four (4) bits, namely, S3, S2, S1, So- Here, there are two (2) MSBs which are S3 and S2, and two (2) LSBs which are si and S0. the two (2) MSBs are from the base layer and the two LSBs come from the enhancement layer. Given energy ratio r between the base layer and enhancement layer, and can be defined such that l(a2 + /?2}=1. Here, a denotes the amplitude of the base layer, and β denotes the amplitude of enhancement layer. Moreover, 2(α2+β2)=\ is a constraint which is also referred to as power constraint and more accurately referred to as normalization. Table 3 illustrates a layered modulation table with QPSK base layer and QPSK enhancement layer. [Table 3] Referring to Table 3, each column defines the symbol position for each four (4) bits, S3, S2, S1, S0. Here, the position of each symbol is given in a two-dimensional signal space ( m1 , mQ ). This means that each symbol can be represented by S(t) = [M1 cos(27nfot + 0o)+MQ sia(27f0t + 0)](t). Simply put, the complex modulation symbol S = ( mt , mQ ) for each [S3, S2, S1, So] is specified in S(t) = [M1 cos(27nfot + 0o)+MQ sia(27f0t + 0)](t). Here, cos(2 nfo t+0,) and sin(27zf0 t + 0,) denote the carrier signal with initial phase ,. and carrier frequency f0 . Moreover, φ{t) denotes the pulse-shaping, the shape of a transmit symbol. In the above definition of S(t), except the m, and mQ value, other parameters can usually either be shared between the transmitter and the receiver or be detected by the receiver itself. For correctly demodulating S(t), it is necessary to define and share the possible value information of m, and mQ. The possible value of ml (k) and mQ(K), which denote the m} and mQ value for the k symbol, are given in Table 1. It shows for representing each group inputs bits s3, S2, s1, so the symbol shall be modulated by corresponding parameters shown in the table- Figure 19 is an exemplary diagram illustrating the signal constellation of the layered modulator with respect to 16QAM/QPSK hierarchical modulation. Referring to another 16QAM/QPSK hierarchical modulation, which means 16QAM base layer and QPSK. enhancement layer, each modulation symbol contains six (6) bits - S5, S4, S3, S2, S1, S0. The four (4) MSBs, S5, 54, S3 and S2, come from the base layer, and the two (2) LSBs, S1 and S0, come from the enhancement layer. Given energy ratio r between the base layer and enhancement layer, and can be defined such that2fa1 +JB2) =1. Here, a denotes the amplitude of the base layer, and fi denotes the amplitude of enhancement layer. Moreover, 2(α2 +β2) =l is a constraint which is also referred to as power constraint and more accurately referred to as normalization. Table 4 illustrates a layered modulation table with 16QAM base layer and QPSK enhancement layer. (Table 4] Referring to Table 4, each column defines the symbol position for each six (6) bits, S5, S4, S3, S2, S1, S0. Here, the position of each symbol is given in a two-dimensional signal space ( m, , mQ ).This means that each symbol can be represented by S(t) = [M1, cos(2nf0t +0) + MQ sin(2nf0t + 0))](t). Simply put, the complex modulation symbol S = ( m, , mQ ) for each [S5, S4, S3, S2, S1, so] is specified in 5(t) = [M1, cos(2nf0t + 0t)+MQ sin(2nf0t + 0 )](t') ■ Here, w0 denotes carrier frequency, xQ denotes an initial phase of the carrier, and (t) denotes the symbol shaping or pulse shaping wave. Here, cos(2nf0t +0) and sin(2nf0t +0) denote the carrier signal with initial phase o and carrier frequency fQ . Moreover, p(t) denotes the pulse-shaping, the shape of a transmit symbol. In the above definition of S(/), except the m( and mQ value, other parameters can usually either be shared between the transmitter and the receiver or be detected by the receiver itself. For correctly demodulating Sif), it is necessary to define and share fee possible value information of m, and mQ. The possible value of m, (k) and mQ (k), which denote the my and mQ value for the k* symbol, are given in Table L It shows for representing each group inputs bits S5, S4, s3, S2, S1, S0 the symbol shall be modulated by corresponding parameters shown in the table. With respect to the definitions of m; and mQ in Table 1-4, in additioa to the contents, the show that the rotation angle 0 also needs to be shared along with those tables between transmitter and receiver. Table 5 can be used to address this problem regarding how the receiver and transmitter share the rotation angle information. To this end, Table 5 can be used which defines and/or maps four (4) bits to a rotation angle. If this table is known by fee receiver beforehand, then the transmitter only needs to sent four (4) bits to receiver to indicate to the receiver the initial rotation angle for demodulating next rotated layered modulated symbols. This table is an example of quantizing the rotation angle 9 with four (4) bits and uniform quantization. It is possible to quantize die rotation angle 6 with other number of bits and different quantization rule for different accuracy. More specifically, this table is either shared beforehand by the transmitter and receiver (e.g., access network and access terminal), downloaded to the receiver (e.g., access terminal) over the air, or only used by the transmitter (e.g., access network) when the hierarchical modulation is enabled. The default rotation word for hierarchical modulation is 0000, which corresponds to 0.0. Further, this table can be used by the receiver for demodulating the rotated layered modulation. Compared with the regular or un-rotated layered modulation, the initial rotation angle is essentially zero (0). This information of initial rotation angle of zero (0) indicates an implicit consensus between the transmitter and the receiver. However, for rotated layered modulation, this information may not be implicitly shared between the transmitter and/or the receiver. In other words, a mechanism to send or indicate this initial rotation angle to the receiver is necessary. In a further application of the layered or superposition modulation for BCMCS, layered modulation can be a superposition of any two modulation schemes. In BCMCS, a QPSK enhancement layer is superposed on a base QPSK or 16-QAM layer to obtain the resultant signal constellation. The energy ratio r is the power ratio between the base layer and the enhancement. Furthermore, the enhancement layer is rotated by the angle 9 in counter-clockwise direction. Figure 20 is an exemplary diagram illustrating signal constellation for layered modulation with QPSK base layer and QPSK enhancement layer. Referring to Figure 20, each modulation symbol contains four (4) bits, namely, S3, S2 S1, S0. Here, there are two (2) MSBs which are S3 and s1, and two (2) LSBs which are S2 and S0. The two (2) MSBs are from the base layer and the two LSBs come from the enhancement layer Given energy ratio r between the base layer and enhancement layer, and ;an be defined such that2la2 + 01 j = 1. Here, a denotes the amplitude of the base layer, and β denotes the amplitude of enhancement layer. Moreover, 2(α2+β2) = l is a constraint which is also referred to as power constraint and more accurately referred to as normalization. Table 6 illustrates a layered modulation table with QPSK base layer and QPSK enhancement layer. [Table 6] Referring to Table 6, each column defines the symbol position for each four (4) bits, S3, S2, s1, SO. Here, the position of each symbol is given in a two-dimensional signal space ( m, , mQ ). This means that each symbol can be represented by S(t) = [Mr cos(2nfot+0o)+Mg sin(27tfDt + 0)](t)- Simply put, the complex modulation symbol S = ( m, , mQ ) for each [S3, S2, S1, S0] is specified in 5(0 = [M1, cos(2nf0t+0) +MQ sin(2nf0t + 0)](t). Here, COS(2NF0T + 0, ) and sin(2nf0 t + a) denote the carrier signal with initial phase 0 and carrier frequency f0 . Moreover, φ{t) denotes the pulse-shaping, the shape of a transmit symbol. In the above definition of S(t), except the m1 and mg value, other parameters can usually either be shared between the transmitter and the receiver or be detected by the receiver itself. For correctly demodulating S(t), it ia necessary to define and share the possible value information of m1 and/»s. The possible value of m, (k) and mQ{k), which denote Has m, and mQ value for the k* symbol, are given in Table 1, It shows for representing each group inputs bits s3, s2, s1, s0 the symbol shall be modulated by corresponding parameters shown in the table. Figure 21 is an exemplary diagram illustrating (he signal constellation of die layered modulator with respect to 16QAM/QPSK hierarchical modulation. Referring to another 16QAM/QPSK hierarchical modulation, which means 16QAM base layer and QPSK enhancement layer, each modulation symbol contains six (6) bits - s5, S4, s3, S2, s1, s0. The four (4) MSBs, s4, s3, st and s0, come from the base layer, and the two (2) LSBs, s5 and sz,, come from the enhancement layer. Given energy ratio r between the base layer and enhancement layer, and ;aa be defined such that2(α2 + β2)=1. Here, α denotes the amplitude of the base layer, and β denotes the amplitude of enhancement layer. Moreover, 22(α2 + β2)=l is a constraint which is also referred to as power constraint and more accurately referred to as normalization. Table 7 illustrates a layered modulation table with 16QAM base layer and QPSK enhancement layer. [Table 7] Referring to Table 4, each column defines the symbol position for each six (6) bits, S5, S4, S3, S2, S1, So. Here, the position of each symbol is given in a two-dimensional signal space ( m, , mQ ). This means that each symbol can be represented by S(t) = [M1,COS(2NF0T + 0, ) and sin(2nf0 t + a). Simply put, the complex modulation symbol S = ( m, , m6 ) for each [s5, s4> S3, s2, s,, so] is specified in S(t) = [M, COS(2NF0T + 0, ) and sin(2nf0 t + a). Here, W0 denotes carrier frequency, 0 denotes ail initial phase of the carrier, and #(0 denotes the symbol shaping or pulse shaping wave. Here, cos(2nf0t + 0) and sin(2nf0 t +0) denote the carrier signal with initial phase 0 and carrier frequency 0 , Moreover, φ(t) denotes the pulse-shaping, the shape of a transmit symbol. In the above definition of s(t), except the m7 and mQ value, other parameters can usually either be shared between the transmitter and the receiver or be detected by the receiver itself. For correctly demodulating S(t), it is necessary to define and share the possible value information of mf and mQ. The possible value of ml (k) and mB (k), which denote the m1 and mQ value for the ktb symbol, are given in Table 1. It shows for representing each group inputs bits S5, S4, S3, S2, S1, So the symbol shall be modulated by corresponding parameters shown in the table. However, the Euclid distance profile can change when the enhancement layer signal constellation is rotated and the power-splitting ratio is changed. This means the original Gray mapping in Fig. 21, for example, may not always be optimal. In this case, it may be necessary to perform bits-to-symbols remapping based on each Euclidean distance file instance. Figure 22 is an exemplary diagram illustrating Gray mapping for rotated QPSK/QPSK hierarchical modulation. The BER performance of a signal constellation can be dominated by symbol pairs with minimum Euclidean distance, especially when SNR is high. Therefore it is interesting to find optimal bits-to-synibol mapping rules, in which the codes for the closest two signals have minimum difference. in general, Gray mapping in two-dimensional signals worked with channel coding can be accepted as optimal for minimizing BER for equally likely signals. Gray mapping for regular hierarchical signal constellations is shown in Figure 21, where the codes for the closest two signals are different in only one bit. However, this kind of Euclidean distance profile may not be fixed in hierarchical modulation. An example of the minimum Euclidean distance of 16QAM/QPSK hierarchical modulation with different rotation angles is shown in Figure 23. Figure 23 is an exemplary diagram illustrating an enhanced QPSK/QPSK hierarchical modulation. Referring to Figure 23, the base layered is modulated with QPSK and the enhancement layer is modulated with rotated QPSK. If the hierarchical modulation is applied, a new QPSK/QPSK hierarchical modulation can be attained as shown in this figure. Further, the inter-layer Euclidean distance may become shortest when the power splitting ratio increases in a two-layer hierarchical modulation. This can occur if the enhancement layer is rotated. In order to minimize BER when Euclidean distance profile is changed in hierarchical modulation, the bits-to-symbol mapping can be re-done or performed again, as shown in Figures 24 and 25. Figure 24 is an exemplary diagram illustrating a new QPSK/QPSK hierarchical modulation. Moreover, Figure 25 is another exemplary diagram illustrating a new QPSK/QPSK hierarchical modulation. In view of the discussions of above, a new bit-to-symbol generation structure can be introduced. According to the conventional structure, a symbol mapping mode selection was not available. Figure 26 is an exemplary diagram illustrating a new bit-to-symbol block. Here, the symbol mapping mode can be selected when the bits-to-symbol mapping is performed. More specifically, a new symbol mapping mode selection block can be added for controlling and/or selecting bits-to-symbol mapping rule based on the signal constellation of hierarchical modulation and channel coding used It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. Thus, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. CLAIMS 1. A method of allocating symbols in a wireless communication system, the method comprising: receiving at least one data stream from at least one user; grouping the at least one data streams into at least one group, wherein each group is comprised of at least one data stream; precoding each group of data streams in multiple stages; and allocating the precoded symbols. 2. The method of claim 1, wherein the each group of data streams is precoded independently. 3. The method of claim 2, wherein the each group of data stream is precoded independently using independent rotation matrix. 4. The method of claim 1, wherein the each group of data streams is precoded jointly. 5. The method of claim 4, wherein the each group of data streams is precoded jointly using a single rotation matrix. 6. The method of claim 1, wherein the precoding in multiple stages include applying independent spreading matrix to each group. 7. The method of claim 1, wherein the precoding includes at least one of phase adjustment or amplitude adjustment. 8. The method of claim 1, wherein the wireless communication system is any one of orthogonal frequency division multiplexing (OFDM) system, orthogonal frequency division multiple access (OFDMA) system, multi-carrier code division multiplexing (MC- CDM), or multi-carrier code division multiple access (MC-CDMA). 9. The method of claim 1, further comprising modulating the allocated symbols using an inverse fast Fourier transform (IFFT) or an inverse discrete Fourier transform (IDFT). 10. A method of performing hierarchical modulation signal constellation in a wireless communication system, the method comprising allocating multiple symbols according to a bits-to-symbol mapping rule representing different signal constellation points with different bits, wherein the mapping rule represents one (1) or less bit difference between closest two symbols. 11. The method of claim 10, wherein the multiple symbols have different initial modulation phase. 12. The method of claim 10, wherein the hierarchical modulation signal constellation includes one base layer signal constellation and at least one enhancement layer signal constellation. 13. The method of claim 12, wherein the mapping rule applied to the enhancement layer is selected from a pool of all possible enhancement layer mapping rules which is based on each base layer symbol position. 14. The method of claim 10, wherein the hierarchical modulation signal constellation includes one base layer signal constellation and at least one enhancement layer signal constellation and the mapping rule represented by a bit-to-symbol mapping rule. 15. The method of claim 10, further comprising multiplexing the bits for base layer symbol and the bits for enhancement layer symbol using interleaving or concatenating techniques. 16. The method of claim 10, further comprising: grouping the symbols, each group having the same signal strength; and selecting the each group from a pool of mapping rules according to the bits- to-symbol mapping rule applied to other groups. 17. The method of claim 10, wherein the modulation schemes include phase shift keying (PSK), rotated-PSK, quadrature phase shift keying (QPSK), rotated-QPSK, 8-PSK, rotated 8-PSK, 16 quadrature amplitude modulation (16QAM), and rotated-l6QAM. 18. The method of claim 10, wherein the bits-to-symbol mapping rule is Gray mapping rule. 19. A method of transmitting more than one signal in a wireless communication system, the method comprising: allocating multiple symbols to a first signal constellation and to a second constellation, wherein the first signal constellation refers to base layer signals and the second signal constellation refers to enhancement layer signals; modulating the multiple symbols of the first signal constellation and the second signal constellation; and transmitting the modulated symbols. 20. The method of claim 19, wherein the base layer signals and the enhancement layer signals have initial modulation and transmission phase that are the same. 21. The method of claim 19, wherein the base layer signals and the enhancement layer signals have initial modulation and transmission phase that are different 22. The method of claim 19, wherein the base layer signals and the enhancement layer signals have the same bits-to-symbol mapping rules. 23. The method of claim 19, wherein the base layer signals and the enhancement layer signals have different bits-to-symbol mapping rules. 24. The method of claim 19, wherein the transmitted modulated symbols apply bits-to-symbol mapping rule where each enhancement layer signal constellation is based on bits-to-symbol mapping rule for the base layer bits-to-symbol mapping rule and other enhancement bits-to-symbol mapping rule. A method of allocating symbols in a wireless communication system is disclosed. More specifically, the method includes receiving at least one data stream from at least one user, grouping the at least one data streams into at least one group, wherein each group is comprised of at least one data stream, precoding each group of data streams in multiple stages, and allocating the precoded symbols.

Full Text

A METHOD OF UTILIZING AND MANIPULATING WIRELESS RESOURCES
FOR EFFICIENT AND EFFECTIVE WIRELESS COMMUNICATION
TECHNICAL FIELD
The present invention relates to a method of using wireless resources, and more
particularly, to a method of utilizing and manipulating wireless resources for efficient and
effective wireless communication.
BACKGROUND ART
In the world of cellular telecommunications, those skilled in the art often use the
terms 1G, 2G, and 3G. The terms refer to the generation of the cellular technology used. 1G
refers to the first generation, 2G to the second generation, and 3 G to the third generation.
1G refers to the analog phone Systran, known as an AMPS (Advanced Mobile Phone
Service) phone systems. 2G is commonly used to refer to the digital cellular systems that
are prevalent throughout the world, and include CDMAOne, Global System for Mobile
communications (GSM), and Time Division Multiple Access (TDMA). 2G systems can
support a greater number of users in a dense area than can 1G systems.
3G commonly refers to the digital cellular systems cutrsatiy being deployed. These
3G communication systems are conceptually similar to each other with some significant
differences.

In a wireless communication system, an effective transmission of data crucial and at
the same time, it is important to improve transmission efficiency. To this end, it is important
that more efficient ways of transmitting and receiving data are developed.
DISCLOSURE
Accordingly, the present invention is directed to a method of utilizing and
manipulating wireless resources for efficient and effective wireless communication that
substantially obviates one or more problems due to limitations and disadvantages of the
related art.
TECHNICAL PROBLEM
An object of the present invention is to provide a method allocating symbols in a
wireless communication system.
Another object of the present invention is to provide a method of performing
Merarcbical modulation signal constellation in a wireless communication system.
A further object of the present invention is to provide a method of transmitting more
than one signal in a wireless communication system.
TECHNTrAL SOLUTION

To achieve these objects and other advantages and in accordance with the purpose of
the invention, as embodied and broadly described herein, a method of allocating symbols in
a wireless communication system includes receiving at least one data stream from at least
one user, grouping the at least one data streams into at least one group, wherein each group
is comprised of at least one data stream, precoding each group of data streams in multiple
stages, and allocating the precoded symbols-
In another aspect of the present invention, a method of performing hierarchical
modulation signal constellation in a wireless communication, system includes allocating
multiple symbols according to a bits-to-symbol mapping rule representing different signal
constellation points with different bits, wherein the mapping rule represents one (1) or less
bit difference between closest two symbols.
In a further aspect of the present invention, a method of transmitting more than one
signal in a wireless communication system includes allocating multiple symbols to a first
signal constellation and to a second constellation, wherein the first signal constellation
refers to base layer signals and the second signal constellation refers to enhancement layer
signals, modulating the multiple symbols of the first signal constellation and the second
signal constellation, and transmitting the modulated symbols.
ADVANTAGES EFFECTS

Additional advantages, objects, and features of the invention will be set forth in part
in the description which follows and in part will become apparent to those having ordinary
skill in the art upon examination of th.e following or may be learned from practice of the
invention. The objectives and other advantages of the invention may be realized and
attained by the structure particularly pointed out in the written description and claims hereof
as well as the appended drawings.
It is to be understood that both the foregoing general description and the following
detailed description of the present invention are exemplary and explanatory and are
intended to provide further explanation of the invention as claimed.
DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are included to provide a further understanding
of the invention and are incorporated in and constitute a part of this application, illustrate
embodiments) of the invention and together with the description serve to explain the
principle of the invention. In the drawings;
FIG-1 is an exemplary diagram of a generalized MC-CDM structure;
FIG. 2 is another exemplary diagram of a generalized MC-CDM structure;
FIG. 3 is an exemplary diagram illustrating a generalized MC-CDM structure in
which precoding/rotation is performed on groups;
FIG. 4 is an exemplary diagram illustrating a multi-stage rotation;

FIG. 5 is another exemplary diagram of a generalized MC-CDM structure;
FIG. 6 is an exemplary diagram illustrating frequency-domain interlaced MC-CDM;
FIG. 7 is an exemplary diagram illustrating an example of Gray coding;
FIG. 8 is an exemplary diagram illustrating mapping for regular QPSK/QPSK
hierarchical modulation or 16QAM modulation;
FIG. 9 is an exemplary diagram illustrating bits-to-symbol mapping for
I6QAM/QPSK;
FIG. 10 is another exemplary diagram illustrating bits-to-symbol mapping for
16QAM/QPSK;
FIG. 11 is another exemplary diagram illustrating; bits-to-symbol mapping for
16QAM/QPSK;
FIG. 12 is another exemplary diagram illustrating bits-to-symbol mapping for
16QAM/QPSK;
FIG. 13 is an exemplary diagram illustrating bits-to-symbol mapping for
QPSK/QPSK;
FIG. 14 is an exemplary diagram illustrating an enhancement layer bits-to-symbol
for base layer 0x0;
FIG. 15 is an exemplary diagram illustrating an enhancement layer bits-to-symbol
for base layer 0x1;

FIG. 16 is an exemplary diagram showing the signal constellation of the layered
modulator with respect to QPSK/QPSK hierarchical modulation;
FIG. 17 is aa exemplary diagram illustrating the signal constellation of the layered
modulator with respect to 16QAM/QPSK hierarchical modulation;
FIG. 18 is an exemplary diagram showing the signal constellation for the layered
modulator with QPSK/QPSK hierarchical modulation;
FIG. 19 is an exemplary diagram illustrating the signal constellation of the layered
modulator with respect to 16QAM/QPSK hierarchical modulation;
FIG. 20 is an exemplary diagram illustrating signal constellation for layered
modulation with QPSK base layer and QPSK enhancement layer,
FIG. 21 is an exemplary diagram illustrating the signal constellation of the layered
modulator with respect to 16QAM/QPSK hierarchical modulation;
FIG. 22 is an exemplary diagram illustrating Gray mapping for rotated QPSK/QPSK
hierarchical modulation;
FIG. 23 is an exemplary diagram illustrating an enhanced QPSK/QPSK hierachical
modulation;
FIG. 24 is an exemplary diagram illustrating a new QPSK/QPSK hierarchical
modulation;
FIG. 25 is another exemplary diagram illustrating a new QPSK/QPSK hierarchical
modulation; and

FIG. 26 is an exemplary diagram illustrating a new bit-to-symbol block.
BEST MODE FOR CARRYING OUT THE INVENTION
Reference will now be made in detail to the preferred embodiments of the present
invention, examples of which ate illustrated in fee accompanying drawings. Wherever
possible, the same reference numbers will be used throughout the drawings to refer to the
same or like parts.
An orthogonal frequency division multiplexing (OFDM) is a digital multi-carrier
modulation scheme, which uses a large number of closely-spaced orthogonal sub-carriers.
Each sub-carrier is usually modulated with a modulation scheme (e.g., quadrature plxase
shift keying (QPSK)) at a low symbol rate while maintaining data rates similar to
conventional single-carrier modulation schemes in the same bandwidth.
The OFDM originally does not have frequency diversity effect, but it can obtain
frequency diversity effect by use of forward error correction (FEC) even in a distributed
mode. That is, the frequency diversity effect becomes low when the chapel coding rate is
high.
in view of this, multi-carrier code division multiplexing (MC-CDM) or a multi-
carrier code division multiple access (MC-CDMA) with advanced receiver can be used to
compensate for low frequency diversity effect due to high channel coding rate.

The MC-CDM or MC-CDMA is a multiple access scheme used in OFDM-based
system, allowing the system to support multiple users at the same time. In other words, the
data can. be spread over a much wider bandwidth, than the data rate, a signal-to-noise and
interference ratio can be minimized.
For example, with respect to signal processing, a channel response for each OFDM
tone (or signal or sub-carrier) can be modeled as identical independent complex Gaussian
variable. By doing so and using MC-CDM, diversity gain and processing gain can be
attained. Here, interference, such as inter-symbol interference (ISI) or multiples access
interference (MAI), is temporarily omitted in part due to the cyclic prefix or zero padding
employed by OFDM or MC-CDM.
Figure 1 is an exemplary diagram of a generalized MC-CDM structure. Referring to
Figure denotes the frequency response of fading channel, where \ is a
complex Gaussian variable for the frequency-domain channel response of each sub-carrier.
Furthermore, without loss of the generality, denote the unitary symbol
precoding matrix with, power constraint |α|2 + |β|2 = 1. It can be taken a generalization of
the classic MC-CDM.
The processes of Figure 1 include channel coding followed by spreading and
multiplexing (which can be represented by U). Thereafter, the multiplexed data is
modulated by using the OFDM modulation scheme.

At the receiving end, the OFDM modulated symbols are demodulated using OFDM
demodulation scheme. They are then despread and detected, followed by channel decoding.
Further to the generalized MC-CDM structure, other structures are available such as
rotated MC-CDM, OFDM, rotational OFDM (R-OFDM), or Walsh-Hadamard MC-CDM.
With respect to rotated MC-CDM, if α - cos(θ, ) and β = sin(θ ), then a real-
value rotation matrix can be available as follows in Equation 1.

Furthermore, with respect to OFDM, if αβ = 0 or αβ*=0, then U2 becomes I2.
In other words, U7 becomes uncoded OFDM or uncoded OFDMA. In addition, with respect
to Walsh-Hadamard MC-CDM, if α = cos(/4) = √2/2 and β = sin(/4) = √2/2, U2 = R2 become
a classic "Walsh-Hadamard matrix.
i Figure 2 is another exemplary diagram of a generalized MC-CDM structure. In
Figure 2, a plurality of data are inputted which are then precoded and/or rotated. Here, the
precoding or rotation also can signify adjustment of the amplitude and/or phase of incoming
data.

With respect to precoding/rotation, different tones or sub-carriers may be
precoded/rotated independently or jointly. Here, the joint precoding/rotation of the
incoming data or data streams can be performed by using a single rotation matrix.
Alternatively, different incoming data or data streams can be separated into multiple groups,
where each group of data streams can be precoded/rotated independently or jointly.
Figure 3 is an exemplary diagram illustrating a generalized MC-CDM structure in
which precoding/rotation is performed on groups. Referring to Figure 3, multiple data or
data streams are grouped into Data Stream(s) I, 2,..., K groups which, axe then
precoded/rotated per group. Here, the precoding/rotation can include amplitude and/or
phase adjustment, if necessary. Thereafter, the precoded/rotated symbols are mapped.
Further, different rotation/precoding on different groups may lead to a mixture of
OFDM, MC-CDM or R-OFDM. In addition, the rotation/precoding of each group may be
based on the QoS requirement, the receiver profile, and/or the channel condition.
Alternatively, instead of using a big precoding/rotation matrix, a smaller-sized
precoding/rotation matrix can be dependency or independently applied to different'groups
of incoming data streams.
In operation, actual precoding/rotation operation can be performed in multiple stages.
Figure 4 is an exemplary diagram illustrating a multi-stage rotation. Referring to Figure 4,
multiple data or data streams are inputted which are then precoded/rotated. Here, these

processed symbols can be grouped into at least two groups. Each group is represented by at
least one symbol.
With respect to rotation of the symbols, tile symbol(s) of each group can be spread
using a spreading matrix. Here, the spreading matrix that is applied to a group may be
different and can be configured. After the symbols are processed through the spreading
matrix, then the output(s) can be re-grouped into at least two groups. Here, the re-grouped
outputs comprise at least one selected output from each of the at least two groups.
Thereafter, these re-grouped outputs can be spread again using the spreading matrix.
Again, the spreading matrix that is applied to a group may be different and can be
configured. After the outputs are processed through another spreading matrix, they are
inputted to an. inverse fast Fourier transform (IFFT).
A rotation scheme such as the multi-stage rotation can also be employed by a
generalized MC-CDM or multi-carrier code division multiple access (MC-CDMA). Figure
5 is an exemplary diagram illustrating a general block of the MC-CDM.
Figure 5 is another exemplary diagram of a generalized MC-CDM structure. More
specifically, the processes as described with respect to Figure 5 are similar to those of
Figure 1 except that Figure 5 is based on generalized MC-CDM or MC-CDMA that uses
rotation (e.g., multi-stage rotation). Here, after channel coding, the coded data are rotated
and/or multiplexed, followed by modulation using inverse discrete Fourier transform
0DFT)orIFFT.

At the receiving end, the modulated symbols are demodulated using discrete Fourier
transform (DFT) or fast Fourier transform (FFT). They are then despread and detected,
followed by channel decoding.
In addition, interlacing is available in the generalized MC-CDM. In Ix evolution
data optimized (ixEV-DO) BCMCS and enhanced BCMCS (EBCMCS), the multipath
delay spread is about Td = 3.7us and the coherent bandwidth is around Bc =1/Td = 270kHz.
Therefore, the maximum frequency diversity order is This means, in
order to capture the maximum frequency diversity here, the MC-CDM spreading gain L > 5
is possibly enough-
Based on the above analysis, a frequency-domain interlaced MC-CDM can be used.
Figure 6 is an exemplary diagram illustrating frequency-domain interlaced MC-CDM.
Referring to Figure 6, each slot, indicated by different fills, can be one tone (or sub-carrier)
or multiple consecutive tones (or sub-carriers).
The tone(s) or sub-carrier(s) or symbol(s) can be rotated differently. In other words,
the product distance, which can be defined as the product of Euclidean distances, can be
maximized. In detail, a minimum product distance, which is used for optimizing modulation
diversity, can be shown by the following equation. The minimum product distance can also
be referred to as Euclidean distance tmnimization.

Referring to Equation 3, sj EA denotes the transmitted symbols. Furthermore,
optimization with maximizing the minimum production distance can be done by solving the
following equation.
[Equation 4]

For example, for the traditional quadrature phase shift keying (QPSK), U1 (eJt ) can.
be decided by calculating d(ejt=1/2 Δ2-(ejtΔ2)2 where A12 e{±l,±J,±l±j).
As discussed, each tone or symbol pan be rotated differently. For example, a first
symbol can be applied QPSK, a second symbol can be applied a binary phase shift keying
(BPSK), and nth symbol can be applied 16 quadrature amplitude modulation (16QAM). To
put differently, each tone or symbol has different modulation angle.

Referring to Equation 3, the diversity can be denoted by
, and the interference matrix can be denoted
. Here, the interference matrix can be ISI or
multiple access interference (MAI).
A total diversity of the generalized MC-CDM can be represented as shown in
Equation 7.

Referring to Equation 4, the total diversity of the generalized MC-CDM is
independent on the precoding matrix U. However, for each symbol or user, the diversity
gain may be different to each.
Further, the interference of the generalized MC-CDM can be represented as shown
in Equation 8.

Here, there is some self-interference or multi-user
interference. In other words, due to frequency-selectivity in OFDM-liked orthogonal
modulation, there is possible interference if some preceding or spreading is applied.
Furthermore, it can be shown that this interference can be maximized when the rotation
angel is 9 = /4.
4
In designing a MC-CDM transceiver, inter alia, an inter-symbol or multiple access
signal-to-interference ratio (SIR) can be defined as follows.

Referring to Equation 9 denotes the channel fading difference. The SIR can
be defined based on channel fading and rotation.
Rotation can also be performed based on receiver profile. This can be done through
upper layer signaling. More specifically, at least two parameters can be configured, namely,
spreading gain and rotation angle.
In operation, a receiver can send feedback information containing its optimum
rotation angle and/or rotation index. The rotation angle and/or rotation index can be mapped
to the proper rotation angle by a transmitter based on a table (or index). This table or index
is known by both the transmitter and the receiver. This can be done any time when it is the
best time for the transmitter and/or receiver.
For example, if the receiver (or access terminal) is registered with the network, it
usually sends its profile to the network. This profile includes, inter alia, the rotation angle
and/or index.
Before the transmitter decides to send signals to the receiver, it may ask the receiver
as to the best rotation angle. In response, the receiver can send the best rotation angle to the
transmitter. Thereafter, the transmitter can send the signals based on the feedback
information and its own decision.

During transmission of the signals, the transmitter can periodically request from the
receiver to send its updated rotation angle. Alternatively, the transmitter can request an
update of the rotation angle from the receiver after the transmitter is finished transmitting.
At any time, the receiver can send the update (or updated rotation angle) to the
transmitter. The transmission of the update (or feedback information) can be executed
through an access channel, traffic channel, control channel, or other possible channels.
With respect to channel coding, coding can help minimize demodulation errors and
therefore achieve the throughput in addition to signal design for higher spectral efficiency.
In reality, most capacity-achieving codes are designed to balance the implementation
complexity and achievable performance.
Gray code is one of an example of channel coding which is also known as reflective
binary code. Gray code or the reflective binary code is a binary numeral system where two
successive values differ in only one digit. Figure 7 is an exemplary diagram illustrating an
example of Gray coding.
Gray code for bits-to-symbol mapping, also called Gray mapping, can be
implemented with other channel coding scheme. Gray mapping is generally accepted as the
optimal mapping rule for minimizing bit error rate (BER). Gray mapping for regular
QPSK/QPSK hierarchical modulation (or 16QAM modulation) is shown in Figure 8 where
the codewords with minimtan Euclid distance have minimum Hamming distance as well.

In the figures to follow, the Gray mapping rule is described. More specifically, each
enhancement layer bits-to-symbol and base layer bits-to-symbol satisfy the Gray mapping
requirement where the closest two symbols only have difference of one or the least bit(s).
Furthermore, the overall bits-to-symbol mapping rule satisfies the Gray mapping rule.
Figure 8 is an exemplary diagram illustrating mapping for regular QPSK/QPSK
hierarchical modulation or 16QAM modulation. Referring to Figure 8, the enhancement
layer bits and the base layer bits can be arbitrarily combined so that every time when the
base layer bits are detected, the enhancement layer bits-to-symbol mapping table/rule can be
decided, for example. In addition, both the base layer and the enhancement layer are QPSK.
Furthermore, every point (or symbol) is represented and/or mapped by bob1b2b3.
More specifically, the circle in the center of the diagram and the lines connecting
two (2) points (or symbols) (e.g., point 0011 and point 0001 or point 0110 and point 1110)
represent connection with only one bit difference between neighbors. Here, the connected
points are from different layers. In other words, every connected points (or symbol) are
different base layer bits and enhancement layer bits.
Furthermore, every point can be represented by four (4) bits (e.g., bob1b2b3) in which
the first bit (bo) and the third bit (fa) represent the base layer bits, and the second bit (bi)
and the fourth bit (b3) represent the enhancement bits. That is, two (2) bits from the base
layer and the two (2) bits from the enhancement layer are interleaved together to represent

every resulted point. By interleaving the bits instead of simple concatenation of the bits
from two layers, additional diversity gain can be potentially attained.
Figure 9 is an exemplary diagram illustrating bits-to-symbol mapping for
16QAM/QPSK. This figure refers to bits-to-symbol mapping. This mapping can be used by
both the transmitter and the receiver.
If a transmitter desires to send bits bob1b2b3b4b5s, the transmitter needs to look for a
mapped symbol to send.' Hence, if a receiver desires to demodulate the received symbol, the
receiver can use this figure to find/locate the demodulated bits.
Furthermore, Figure 9 represents 16QAM/QPSK hierarchical modulation. In other
words, the base layer is modulated by 16QAM, and the enhancement layer is modulated by
QPSK. Moreover, 16QAM/QPSK can be referred to as a special hierarchical modulation. In
other words, the base layer signal and the enhancement signal have different initial phase.
For example, the base layer signal phase is 0 while the enhancement layer signal phase is
theta (0).
Every symbol in Figure 9 is represented by bits sequence, S5S4S3S2S1S0, in which bits
S3 and So are bits from the enhancement layer while the other bits (e.g., S5, S4, S2, and S1)
belong to the base layer.
Figure 10 is another exemplary diagram illustrating bits-to-symbol mapping for
16QAM/QPSK. The difference between Figure 10 and previous Figure 9 is that every
symbol in Figure 10 is represented by bits sequence, S5S4S3S2S1S0, in which bits S5 and S2 are

bits from the enhancement layer while the other bits (e.g., S4, S3, S1, and So) are from the base
layer.
Figure 11 is another exemplary diagram illustrating bits-to-symbol mapping for
16QAM/QPSK. The difference between Figure 11 and previous Figures 9 and/or 10 is that
every symbol in Figure 11 is represented by bits sequence, S5S4S3S2S1S0., in which bits S5 and
S4 are bits from the enhancement layer while the other bits (e.g., S3, S2, s1, and so) are from
the base layer.
Figure 12 is another exemplary diagram illustrating bits-to-symbol mapping for
16QAM/QPSK. The difference between Figure 12 and previous Figures 9, 10, and/or 11
bits S5 and S2 are bits from the enhancement layer while the other bits (e.g., S4, S3, S1, and So)
are from the base layer. As before, every symbol in Figure 12 is represented by bits
sequence, S5S4S3S2S1S0..
Further to bits sequence combinations as discussed above, the following hierarchical
layer and enhancement layer combination possibilities include (1) S5S4S3S2S1S0..= b3b2b1e1boeo,
(2) S5S4S3S2S1S0..= b3e1b2b1boeo, (3) S5S4S3S2S1S0.. = b3e1b2b1boeo, (4) S5S4S3S2S1S0. = eoe1b3b2b1bo,
(5)S5S4S3S2S1S0 - eob3b2e1b1bo, (6) S5S4S3S2S1S0. = b3b2eob1boe1, (7) s3s2sis0 = e1b1eobo, (8)
S3S2S1so= eob1e1bo, (9) s3S2S1s0= e1eob1bOj (10) s3S2S1So= eoe1b1bo, and (11) s3S2S1So = b1boeoe1.
In addition to the combinations discussions of above, there are many other possible
combinations. However, they all follow the same rule which is the Gray rule or the Gray
mapping rule. As discussed, each enhancement layer bits-to-symbol mapping and base layer

bits-to-symbol mapping satisfy the Gray mapping rule requirement which is that the closest
two symbols only have difference of one bit or less. Moreover, the overall bits-to-symbol
mapping rule satisfies the Gray mapping rule as well.
Further, the enhancement layer bits and the base layer bits can be arbitrarily
combined so that every time the base layer bits are detected, the enhancement layer bits-to-
symbol mapping table/rule can be decided. In addition, it is possible, for example, for
S3S2S1So=e1eob1b0 QPSK7QPSK, the Gray mapping rule for enhancement layer
S3S2I l=eieol 1 to be not the exactly the same as S3S2lO=eieolG. Moreover, for example, it is
possible S3S2ll=e1eoll is a rotated version as s3s2l0=e1eol0, S3S211=1 Ill's position is the
position of s3s2l 1=1010 or s3s2l 1=0110.
Figure 13 is an exemplary diagram illustrating bits-to-symbol mapping for
QPSK/QPSK. Referring to Figure 13, the bits-to-symbol mapping can be used by both the
transmitter and the receiver. If a transmitter desires to send bits bob1b2b3, the transmitter
needs to look for a mapped symbol to send. Hence, if a receiver desires to demodulate the
received symbol, the receiver can use ibis figure to find/locate the demodulated bits.
Furthermore, Figure 13 represents QPSK/QPSK hierarchical modulation. In other
words, the base layer is modulated by QPSK, and the enhancement layer is also modulated
by QPSK. Moreover, QPSK/QPSK can be referred to as a special hierarchical modulation.
That is, the base layer signal and the enhancement signal have different initial phase. For

example, the base layer signal phase is 0 while the enhancement layer signal phase is theta
0).
Every symbol in Figure 13 is represented by bits sequence, s3s2s1s0, in which bits s5
and si are bits from the enhancement layer while the other bits (e.g., s2 and so) belong to the
base layer.
Further, in the QPSK/QPSK example, the enhancement layer bits-to-symbol
mapping rules may be different from the base layer symbol-to-symbol. Figure 14 is an
exemplary diagram illustrating an enhancement layer bits-to-symbol for base layer 0x0. In
other words, Figure 14 illustrates an example of how the base layer bits are mapped.
For example, the symbols indicated in the upper right quadrant denote the base layer
symbols of '00'. This means that as long as the base layer bits are '00', whatever the
enhancement layer is, Hie corresponding layer modulated symbol is one of the four (4)
symbols of this quadrant.
Figure 15 is an exemplary diagram illustrating an enhancement layer bits-to-symbol
for base layer 0x1. Similarly, this diagram illustrates another example of how the base layer
bits are mapped. For example, the symbols of in the upper left quadrant denote the base
layer symbols of '01'. This means that as long as the base layer bits are '01', whatever the
enhancement layer bits are, the corresponding layer modulated symbols is one of the
symbols of the upper left quadrant.

As discussed above with respect to Figures 1-3, the inputted data or data stream can
be channel coded using the Gray mapping role, for example, followed by other processes
including modulation- The modulation discussed here refers to layered (or superposition)
modulation. The layered modulation is a type of modulation in which each modulation
symbol has bits corresponding to both a base layer and an enhancement layer. In the
discussions to follow, the layered modulation will be described in the context of broadcast
and multicast services (BCMCS).
In general, layered modulation can be a superposition of any two modulation
schemes. In BCMCS, a QPSK enhancement layer is superposed on a base QPSK or 16-
QAM layer to obtain the resultant signal constellation. The energy ratio r is the power ratio
between the base layer and the enhancement. Furthermore, the enhancement layer is rotated
by the angle Q in counter-clockwise direction.
Figure 16 is an exemplary diagram, showing the signal constellation of the layered
modulator with respect to QPSK/QPSK hierarchical modulation. Referring to QPSK/QPSK.
hierarchical modulation, which means QPSK base layer and QPSK enhancement layer, each
modulation symbol contains four (4) bits, namely, S3, S2, S1, S0. Here, there are two (2) most
significant bits (MSBs) which are S3 and S2, and two (2) least significant bits (LSBs) which
are S1 and so. The two (2) MSBs are from the base layer and the two LSBs come from the
enhancement layer.

Given energy ratio r between the base layer and enhancement layer
and can be defined such that2 (a2+02) ~ 1. Here, a denotes the amplitude of
the base layer, and J3 denotes the amplitude of enhancement layer. Moreover,
2(a2 + β2):=l is a constraint which is also referred to as power constraint and more
accurately referred to as normalization.
Table 1 illustrates a layered modulation table with QPSK. base layer and QPSK
enhancement layer.
[Table 1]

Here, cos(2nfa t + 0, ) and sin(2nf0 t + a) denote the carrier signal with initial phase
$, and carrier frequency f0 . Moreover, φ{t) denotes the pulse-shaping, the shape of a
transmit symbol.
In the above definition of S(t), except the mt and mQ value, other parameters can
usually either be shared between the transmitter and the receiver or be detected by the
receiver itself. For correctly demodulating s{t), it is necessary to define and share the
possible value information of m7 and mQ.
The possible value of ml (k) and mg (k), which denote the m, and mQ value for the
kth symbol, are given in Table 1. It shows for representing each group inputs bits s3, s2, su
so the symbol shall be modxjlated by corresponding parameters shown in me table.
The discussion with respect to the complex modulation symbol can be applied in a
similar or same manner to the following discussions of various layered modulations. That is,
the above discussion of the complex modulation symbol can be applied to the tables to
follow.
Figure 17 is an exemplary diagram illustrating the signal constellation of the layered
modulator with respect to 16QAM/QPSK hierarchical modulation. Referring to
16QAM/QPSK hierarchical modulation, which means 16QAM base layer and QPSK
enhancement layer, each modulation symbol contains six 6 bits - s5, S4, S3, S2, s1, so. The
four (4) MSBs, s5, S4, S3 and s2, come from the base layer, and the two (2) LSBs, S\ and so,
come from the enhancement layer.

Given energy ratio r between the base layer and enhancement layer,
and can be defined such that2(ar2+fi2)=1. Here, a denotes the amplitude of
the base layer, and fi denotes the amplitude of enhancement layer. Moreover,
2(α2+β2) = l is a constraint which is also referred to as power constraint and more
accurately referred to as normalization.
Table 2 illustrates a layered modulation table with 16QAM base layer and QPSK
enhancement layer.
[Table 2]

Referring to Table 2, each column defines the symbol position for each six (6) bits,
s5, s4, s3, s2, s1, so. Here, the position of each symbol is given in a two-dimensional signal
space ( m1, , mQ ). This means that each symbol can be represented by

Here, w0 denotes carrier frequency, na denotes an initial phase of the carrier, and
4>(t) denotes the symbol shaping or pulse shaping wave. Here, cos(2nf0 t + o) and
sin(2nf t + Q) denote the carrier signal with initial phase 0 and carrier frequency f0 .
Moreover, (t) denotes the pulse-shaping, the shape of a transmit symbol.
In the above definition of S(t), except the m1, and mQ value, other parameters can
usually either be shared between the transmitter and the receiver or be detected by the
receiver itself. For correctly demodulating S(i), it is necessary to define and share the
possible value information of m1 and mQ,
The possible value of m1 (k) and mQ (k), which denote the m1 and mQ value for the
kth symbol, are given, in Table 1. It shows for representing each group inputs bits ss, s4, s3,
S2, s1, so the symbol shall be modulated by corresponding parameters shown in the table.
Further, another application example for BCMCS for hierarchical modulation is
discussed below. In general, layered modulation can be a superposition of any two
modulation schemes. In BCMCS, a QPSK enhancement layer is superposed on a base
QPSK or 16-QAM layer to obtain the resultant signal constellation. The energy ratio r is
the power ratio between the base layer and the enhancement. Furthermore, the enhancement
layer is rotated by the angle 9 in counter-clockwise direction.

Figure 18 is an exemplary diagram showing the signal constellation for the layered
modulator with QPSK/QPSK hierarchical modulation. Referring to QPSK/QPSK
hierarchical modulation, which means QPSK base layer and QPSK enhancement layer, each
modulation symbol contains four (4) bits, namely, S3, S2, S1, So- Here, there are two (2)
MSBs which are S3 and S2, and two (2) LSBs which are si and S0. the two (2) MSBs are
from the base layer and the two LSBs come from the enhancement layer.
Given energy ratio r between the base layer and enhancement layer,
and can be defined such that l(a2 + /?2}=1. Here, a denotes the amplitude of
the base layer, and β denotes the amplitude of enhancement layer. Moreover,
2(α2+β2)=\ is a constraint which is also referred to as power constraint and more
accurately referred to as normalization.
Table 3 illustrates a layered modulation table with QPSK base layer and QPSK
enhancement layer.
[Table 3]

Referring to Table 3, each column defines the symbol position for each four (4) bits,
S3, S2, S1, S0. Here, the position of each symbol is given in a two-dimensional signal space
( m1 , mQ ). This means that each symbol can be represented by
S(t) = [M1 cos(27nfot + 0o)+MQ *sia(27f0t + 0)](t). Simply put, the complex modulation
symbol S = ( mt , mQ ) for each [S3, S2, S1, So] is specified in
S(t) = [M1 cos(27nfot + 0o)+MQ *sia(27f0t + 0)](t).

Here, cos(2 nfo t+0,) and sin(27zf0 t + 0,) denote the carrier signal with initial phase
,. and carrier frequency f0 . Moreover, φ{t) denotes the pulse-shaping, the shape of a
transmit symbol.
In the above definition of S(t), except the m, and mQ value, other parameters can
usually either be shared between the transmitter and the receiver or be detected by the
receiver itself. For correctly demodulating S(t), it is necessary to define and share the
possible value information of m, and mQ.
The possible value of ml (k) and mQ(K), which denote the m} and mQ value for the
k* symbol, are given in Table 1. It shows for representing each group inputs bits s3, S2, s1,
so the symbol shall be modulated by corresponding parameters shown in the table-
Figure 19 is an exemplary diagram illustrating the signal constellation of the layered
modulator with respect to 16QAM/QPSK hierarchical modulation. Referring to another
16QAM/QPSK hierarchical modulation, which means 16QAM base layer and QPSK.
enhancement layer, each modulation symbol contains six (6) bits - S5, S4, S3, S2, S1, S0. The
four (4) MSBs, S5, 54, S3 and S2, come from the base layer, and the two (2) LSBs, S1 and S0,
come from the enhancement layer.
Given energy ratio r between the base layer and enhancement layer,
and can be defined such that2fa1 +JB2) =1. Here, a denotes the amplitude of
the base layer, and fi denotes the amplitude of enhancement layer. Moreover,

2(α2 +β2) =l is a constraint which is also referred to as power constraint and more
accurately referred to as normalization.
Table 4 illustrates a layered modulation table with 16QAM base layer and QPSK
enhancement layer.
(Table 4]

Referring to Table 4, each column defines the symbol position for each six (6) bits,
S5, S4, S3, S2, S1, S0. Here, the position of each symbol is given in a two-dimensional signal
space ( m, , mQ ).This means that each symbol can be represented by

S(t) = [M1, cos(2nf0t +0) + MQ *sin(2nf0t + 0))](t). Simply put, the complex modulation
symbol S = ( m, , mQ ) for each [S5, S4, S3, S2, S1, so] is specified in
5(t) = [M1, cos(2nf0t + 0t)+MQ* sin(2nf0t + 0 )](t') ■
Here, w0 denotes carrier frequency, xQ denotes an initial phase of the carrier, and
(t) denotes the symbol shaping or pulse shaping wave. Here, cos(2nf0t +0) and
sin(2nf0t +0) denote the carrier signal with initial phase o and carrier frequency fQ .
Moreover, p(t) denotes the pulse-shaping, the shape of a transmit symbol.
In the above definition of S(/), except the m( and mQ value, other parameters can
usually either be shared between the transmitter and the receiver or be detected by the
receiver itself. For correctly demodulating Sif), it is necessary to define and share fee
possible value information of m, and mQ.
The possible value of m, (k) and mQ (k), which denote the my and mQ value for the
k* symbol, are given in Table L It shows for representing each group inputs bits S5, S4, s3,
S2, S1, S0 the symbol shall be modulated by corresponding parameters shown in the table.
With respect to the definitions of m; and mQ in Table 1-4, in additioa to the
contents, the show that the rotation angle 0 also needs to be shared along with those tables
between transmitter and receiver. Table 5 can be used to address this problem regarding
how the receiver and transmitter share the rotation angle information.
To this end, Table 5 can be used which defines and/or maps four (4) bits to a
rotation angle. If this table is known by fee receiver beforehand, then the transmitter only

needs to sent four (4) bits to receiver to indicate to the receiver the initial rotation angle for
demodulating next rotated layered modulated symbols. This table is an example of
quantizing the rotation angle 9 with four (4) bits and uniform quantization. It is possible to
quantize die rotation angle 6 with other number of bits and different quantization rule for
different accuracy.
More specifically, this table is either shared beforehand by the transmitter and
receiver (e.g., access network and access terminal), downloaded to the receiver (e.g., access
terminal) over the air, or only used by the transmitter (e.g., access network) when the
hierarchical modulation is enabled. The default rotation word for hierarchical modulation is
0000, which corresponds to 0.0.
Further, this table can be used by the receiver for demodulating the rotated layered
modulation. Compared with the regular or un-rotated layered modulation, the initial rotation
angle is essentially zero (0). This information of initial rotation angle of zero (0) indicates
an implicit consensus between the transmitter and the receiver. However, for rotated layered
modulation, this information may not be implicitly shared between the transmitter and/or
the receiver. In other words, a mechanism to send or indicate this initial rotation angle to the
receiver is necessary.

In a further application of the layered or superposition modulation for BCMCS,
layered modulation can be a superposition of any two modulation schemes. In BCMCS, a
QPSK enhancement layer is superposed on a base QPSK or 16-QAM layer to obtain the
resultant signal constellation. The energy ratio r is the power ratio between the base layer
and the enhancement. Furthermore, the enhancement layer is rotated by the angle 9 in
counter-clockwise direction.
Figure 20 is an exemplary diagram illustrating signal constellation for layered
modulation with QPSK base layer and QPSK enhancement layer. Referring to Figure 20,

each modulation symbol contains four (4) bits, namely, S3, S2 S1, S0. Here, there are two (2)
MSBs which are S3 and s1, and two (2) LSBs which are S2 and S0. The two (2) MSBs are
from the base layer and the two LSBs come from the enhancement layer
Given energy ratio r between the base layer and enhancement layer,
and ;an be defined such that2la2 + 01 j = 1. Here, a denotes the amplitude of
the base layer, and β denotes the amplitude of enhancement layer. Moreover,
2(α2+β2) = l is a constraint which is also referred to as power constraint and more
accurately referred to as normalization.
Table 6 illustrates a layered modulation table with QPSK base layer and QPSK
enhancement layer.
[Table 6]

Referring to Table 6, each column defines the symbol position for each four (4) bits,
S3, S2, s1, SO. Here, the position of each symbol is given in a two-dimensional signal space
( m, , mQ ). This means that each symbol can be represented by
S(t) = [Mr cos(2nfot+0o)+Mg *sin(27tfDt + 0)](t)- Simply put, the complex modulation
symbol S = ( m, , mQ ) for each [S3, S2, S1, S0] is specified in
5(0 = [M1, cos(2nf0t+0) +MQ *sin(2nf0t + 0)](t).

Here, COS(2NF0T + 0, ) and sin(2nf0 t + a) denote the carrier signal with initial phase
0 and carrier frequency f0 . Moreover, φ{t) denotes the pulse-shaping, the shape of a
transmit symbol.
In the above definition of S(t), except the m1 and mg value, other parameters can
usually either be shared between the transmitter and the receiver or be detected by the
receiver itself. For correctly demodulating S(t), it ia necessary to define and share the
possible value information of m1 and/»s.
The possible value of m, (k) and mQ{k), which denote Has m, and mQ value for the
k* symbol, are given in Table 1, It shows for representing each group inputs bits s3, s2, s1,
s0 the symbol shall be modulated by corresponding parameters shown in the table.
Figure 21 is an exemplary diagram illustrating (he signal constellation of die layered
modulator with respect to 16QAM/QPSK hierarchical modulation. Referring to another
16QAM/QPSK hierarchical modulation, which means 16QAM base layer and QPSK
enhancement layer, each modulation symbol contains six (6) bits - s5, S4, s3, S2, s1, s0. The
four (4) MSBs, s4, s3, st and s0, come from the base layer, and the two (2) LSBs, s5 and sz,,
come from the enhancement layer.
Given energy ratio r between the base layer and enhancement layer,
and ;aa be defined such that2(α2 + β2)=1. Here, α denotes the amplitude of
the base layer, and β denotes the amplitude of enhancement layer. Moreover,

22(α2 + β2)=l is a constraint which is also referred to as power constraint and more
accurately referred to as normalization.
Table 7 illustrates a layered modulation table with 16QAM base layer and QPSK
enhancement layer.
[Table 7]

Referring to Table 4, each column defines the symbol position for each six (6) bits,
S5, S4, S3, S2, S1, So. Here, the position of each symbol is given in a two-dimensional signal
space ( m, , mQ ). This means that each symbol can be represented by

S(t) = [M1,COS(2NF0T + 0, ) and sin(2nf0 t + a). Simply put, the complex modulation
symbol S = ( m, , m6 ) for each [s5, s4> S3, s2, s,, so] is specified in
S(t) = [M, COS(2NF0T + 0, ) and sin(2nf0 t + a).
Here, W0 denotes carrier frequency, 0 denotes ail initial phase of the carrier, and
#(0 denotes the symbol shaping or pulse shaping wave. Here, cos(2nf0t + 0) and
sin(2nf0 t +0) denote the carrier signal with initial phase 0 and carrier frequency 0 ,
Moreover, φ(t) denotes the pulse-shaping, the shape of a transmit symbol.
In the above definition of s(t), except the m7 and mQ value, other parameters can
usually either be shared between the transmitter and the receiver or be detected by the
receiver itself. For correctly demodulating S(t), it is necessary to define and share the
possible value information of mf and mQ.
The possible value of ml (k) and mB (k), which denote the m1 and mQ value for the
ktb symbol, are given in Table 1. It shows for representing each group inputs bits S5, S4, S3,
S2, S1, So the symbol shall be modulated by corresponding parameters shown in the table.
However, the Euclid distance profile can change when the enhancement layer signal
constellation is rotated and the power-splitting ratio is changed. This means the original
Gray mapping in Fig. 21, for example, may not always be optimal. In this case, it may be
necessary to perform bits-to-symbols remapping based on each Euclidean distance file
instance. Figure 22 is an exemplary diagram illustrating Gray mapping for rotated
QPSK/QPSK hierarchical modulation.

The BER performance of a signal constellation can be dominated by symbol pairs
with minimum Euclidean distance, especially when SNR is high. Therefore it is interesting
to find optimal bits-to-synibol mapping rules, in which the codes for the closest two signals
have minimum difference.
in general, Gray mapping in two-dimensional signals worked with channel coding
can be accepted as optimal for minimizing BER for equally likely signals. Gray mapping
for regular hierarchical signal constellations is shown in Figure 21, where the codes for the
closest two signals are different in only one bit. However, this kind of Euclidean distance
profile may not be fixed in hierarchical modulation. An example of the minimum Euclidean
distance of 16QAM/QPSK hierarchical modulation with different rotation angles is shown
in Figure 23.
Figure 23 is an exemplary diagram illustrating an enhanced QPSK/QPSK
hierarchical modulation. Referring to Figure 23, the base layered is modulated with QPSK
and the enhancement layer is modulated with rotated QPSK. If the hierarchical modulation
is applied, a new QPSK/QPSK hierarchical modulation can be attained as shown in this
figure.
Further, the inter-layer Euclidean distance may become shortest when the power
splitting ratio increases in a two-layer hierarchical modulation. This can occur if the
enhancement layer is rotated. In order to minimize BER when Euclidean distance profile is

changed in hierarchical modulation, the bits-to-symbol mapping can be re-done or
performed again, as shown in Figures 24 and 25.
Figure 24 is an exemplary diagram illustrating a new QPSK/QPSK hierarchical
modulation. Moreover, Figure 25 is another exemplary diagram illustrating a new
QPSK/QPSK hierarchical modulation.
In view of the discussions of above, a new bit-to-symbol generation structure can be
introduced. According to the conventional structure, a symbol mapping mode selection was
not available. Figure 26 is an exemplary diagram illustrating a new bit-to-symbol block.
Here, the symbol mapping mode can be selected when the bits-to-symbol mapping is
performed. More specifically, a new symbol mapping mode selection block can be added
for controlling and/or selecting bits-to-symbol mapping rule based on the signal
constellation of hierarchical modulation and channel coding used
It will be apparent to those skilled in the art that various modifications and variations
can be made in the present invention without departing from the spirit or scope of the
inventions. Thus, it is intended that the present invention covers the modifications and
variations of this invention provided they come within the scope of the appended claims and
their equivalents.

CLAIMS
1. A method of allocating symbols in a wireless communication system, the
method comprising:
receiving at least one data stream from at least one user;
grouping the at least one data streams into at least one group, wherein each
group is comprised of at least one data stream;
precoding each group of data streams in multiple stages; and
allocating the precoded symbols.
2. The method of claim 1, wherein the each group of data streams is precoded
independently.
3. The method of claim 2, wherein the each group of data stream is precoded
independently using independent rotation matrix.
4. The method of claim 1, wherein the each group of data streams is precoded
jointly.

5. The method of claim 4, wherein the each group of data streams is precoded
jointly using a single rotation matrix.
6. The method of claim 1, wherein the precoding in multiple stages include
applying independent spreading matrix to each group.
7. The method of claim 1, wherein the precoding includes at least one of phase
adjustment or amplitude adjustment.
8. The method of claim 1, wherein the wireless communication system is any
one of orthogonal frequency division multiplexing (OFDM) system, orthogonal frequency
division multiple access (OFDMA) system, multi-carrier code division multiplexing (MC-
CDM), or multi-carrier code division multiple access (MC-CDMA).
9. The method of claim 1, further comprising modulating the allocated symbols
using an inverse fast Fourier transform (IFFT) or an inverse discrete Fourier transform
(IDFT).
10. A method of performing hierarchical modulation signal constellation in a
wireless communication system, the method comprising allocating multiple symbols

according to a bits-to-symbol mapping rule representing different signal constellation points
with different bits, wherein the mapping rule represents one (1) or less bit difference
between closest two symbols.
11. The method of claim 10, wherein the multiple symbols have different initial
modulation phase.
12. The method of claim 10, wherein the hierarchical modulation signal
constellation includes one base layer signal constellation and at least one enhancement layer
signal constellation.
13. The method of claim 12, wherein the mapping rule applied to the
enhancement layer is selected from a pool of all possible enhancement layer mapping rules
which is based on each base layer symbol position.
14. The method of claim 10, wherein the hierarchical modulation signal
constellation includes one base layer signal constellation and at least one enhancement layer
signal constellation and the mapping rule represented by a bit-to-symbol mapping rule.

15. The method of claim 10, further comprising multiplexing the bits for base
layer symbol and the bits for enhancement layer symbol using interleaving or concatenating
techniques.
16. The method of claim 10, further comprising:
grouping the symbols, each group having the same signal strength; and
selecting the each group from a pool of mapping rules according to the bits-
to-symbol mapping rule applied to other groups.
17. The method of claim 10, wherein the modulation schemes include phase shift
keying (PSK), rotated-PSK, quadrature phase shift keying (QPSK), rotated-QPSK, 8-PSK,
rotated 8-PSK, 16 quadrature amplitude modulation (16QAM), and rotated-l6QAM.
18. The method of claim 10, wherein the bits-to-symbol mapping rule is Gray
mapping rule.
19. A method of transmitting more than one signal in a wireless communication
system, the method comprising:

allocating multiple symbols to a first signal constellation and to a second
constellation, wherein the first signal constellation refers to base layer signals and the
second signal constellation refers to enhancement layer signals;
modulating the multiple symbols of the first signal constellation and the
second signal constellation; and
transmitting the modulated symbols.
20. The method of claim 19, wherein the base layer signals and the enhancement
layer signals have initial modulation and transmission phase that are the same.
21. The method of claim 19, wherein the base layer signals and the enhancement
layer signals have initial modulation and transmission phase that are different
22. The method of claim 19, wherein the base layer signals and the enhancement
layer signals have the same bits-to-symbol mapping rules.
23. The method of claim 19, wherein the base layer signals and the enhancement
layer signals have different bits-to-symbol mapping rules.

24. The method of claim 19, wherein the transmitted modulated symbols apply
bits-to-symbol mapping rule where each enhancement layer signal constellation is based on
bits-to-symbol mapping rule for the base layer bits-to-symbol mapping rule and other
enhancement bits-to-symbol mapping rule.

A method of allocating symbols in a wireless communication system is disclosed. More specifically, the method
includes receiving at least one data stream from at least one user, grouping the at least one data streams into at least one group,
wherein each group is comprised of at least one data stream, precoding each group of data streams in multiple stages, and allocating
the precoded symbols.

Documents:

03052-kolnp-2008-abstract.pdf

03052-kolnp-2008-claims.pdf

03052-kolnp-2008-correspondence others.pdf

03052-kolnp-2008-description complete.pdf

03052-kolnp-2008-drawings.pdf

03052-kolnp-2008-form 1.pdf

03052-kolnp-2008-form 3.pdf

03052-kolnp-2008-form 5.pdf

03052-kolnp-2008-gpa.pdf

03052-kolnp-2008-international publication.pdf

03052-kolnp-2008-pct priority document notification.pdf

3052-KOLNP-2008-(07-04-2014)-CORRESPONDENCE.pdf

3052-KOLNP-2008-(08-04-2014)-ABSTRACT.pdf

3052-KOLNP-2008-(08-04-2014)-CLAIMS.pdf

3052-KOLNP-2008-(08-04-2014)-CORRESPONDENCE.pdf

3052-KOLNP-2008-(08-04-2014)-DRAWINGS.pdf

3052-KOLNP-2008-(08-04-2014)-FORM-13.pdf

3052-KOLNP-2008-(08-04-2014)-FORM-2.pdf

3052-KOLNP-2008-(08-04-2014)-FORM-3.pdf

3052-KOLNP-2008-(08-04-2014)-FORM-5.pdf

3052-KOLNP-2008-(08-04-2014)-OTHERS.pdf

3052-KOLNP-2008-(08-04-2014)-PA.pdf

3052-KOLNP-2008-(08-04-2014)-PETITION UNDER RULE 137.pdf

3052-KOLNP-2008-(09-10-2014)-ABSTRACT.pdf

3052-KOLNP-2008-(09-10-2014)-CORRESPONDENCE.pdf

3052-KOLNP-2008-(09-10-2014)-FORM-1.pdf

3052-KOLNP-2008-(09-10-2014)-FORM-2.pdf

3052-KOLNP-2008-(09-10-2014)-OTHERS.pdf

3052-KOLNP-2008-ASSIGNMENT.pdf

3052-KOLNP-2008-CORRESPONDENCE-1.1.pdf

3052-kolnp-2008-form 18.pdf

abstract-03052-kolnp-2008.jpg

« Previous Patent

Next Patent »

Patent Number

265854

Indian Patent Application Number

3052/KOLNP/2008

PG Journal Number

13/2015

Publication Date

27-Mar-2015

Grant Date

19-Mar-2015

Date of Filing

28-Jul-2008

Name of Patentee

LG ELECTRONICS INC.

Applicant Address

20, YOIDO-DONG, YOUNGDUNGPO-GU, SEOUL

Inventors:

#	Inventor's Name	Inventor's Address
1	WANG, SHU	4311 CORTE DE SAUSALITO, SAN DIEGO, CALIFORNIA 92122
2	SUN, LI-HSIANG	9505 GOLD COAST DR. #142, SAN DIEGO, CA 92126
3	KWON, SOON YIL	12329 CREEKVIEW DR. #42, SAN DIEGO, CA 92128
4	LEE, SOOK WOO	11733 BOULTON AVE., SAN DIEGO, CA 92128
5	KIM, HO BIN	9605 GENESEE AVE., #JI, SAN DIEGO, CA 92121
6	KIM, SANG GOOK	12333 CREEKVIEW DRIVE #46, SAN DIEGO, CA 92128
7	YI, BYUNG KWAN	12772 JORDAN RIDGE COURT 1, SAN DIEGO, CA 92130
8	YOON, YOUNG CHEUL	7214 SHORELINE DR. #179, SAN DIEGO, CALIFORNIA 92122

PCT International Classification Number

H04L 27/26

PCT International Application Number

PCT/KR2007/002461

PCT International Filing date

2007-05-21

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	60/909,906	2007-04-03	U.S.A.
2	60/910,420	2007-04-05	U.S.A.
3	60/896,831	2007-03-23	U.S.A.
4	60/801,689	2006-05-19	U.S.A.