1. Field
The following description relates to a physical layer network coding method and apparatus for correcting errors that are generated in a network.
2. Description of Related Art
Information that is transmitted over a communication network may be coded. For example, a network coding scheme is a scheme in which coding of information is performed in intermediate nodes, as well as in a source and at a destination. A general communication network transfers, to the destination, a payload of a packet that is generated at the source without changing the payload of the packet at a router. Conversely, a communication network using the network coding scheme may allow changing of the payload, such as changing by mixing different packets at a router.
Originally, the network coding scheme was suggested to improve a multi-cast throughput in a wired network. Currently, the use of a network coding scheme that provides tangible effects in a wireless network has drawn attention.
In one general aspect, there is provided a communication method of a relay node, the method including receiving a signal including a first symbol through a kth symbol that are transmitted from a first node through a kth node, respectively, calculating, based on a predetermined criterion, a reliability of the first symbol through the kth symbol, respectively, selecting one or more symbols from among the first through the kth symbol that have a reliability that is greater than or equal to the predetermined criterion, and generating a transmission signal that maintains the reliabilities of the selected symbols and that excludes components of symbols that have reliabilities which are less than the predetermined criterion.
The generating may comprise generating the transmission signal to decrease an expected power of error between the transmission signal and the received signal.
The calculating may comprise calculating the reliabilities of the first symbol through the kth symbol, based on a log likelihood ratio (LLR) with respect to the first symbol through the kth symbol, respectively, each LLR calculated based on the received signal and channel information that is associated with the first node through the kth node, respectively.
The generating may comprise generating the transmission signal in which LLRs of the selected symbols are equivalent to LLRs of the selected symbols in the received signal or are within a predetermined range.
The equivalence or the difference in the predetermined range may be determined based on the Kuliback-Leibler distance.
The method may further comprise estimating channels with respect to the first node through the kth node based on pilots that are transmitted from the first node through the kth node, respectively.
The method may further comprise transmitting the transmission signal to a first destination node through a kth destination node corresponding to the first node through the kth node, respectively.
The transmitting may comprise transmitting the transmission signal by scaling the transmission signal, based on a predetermined transmission power.
The method may further comprise transmitting identification information that is associated with nodes corresponding to the selected symbols.
In another aspect, there is provided a computer-readable storage medium having stored therein program instructions to cause a processor to implement a communication method of a relay node, the method including receiving a signal including a first symbol through a kth symbol that are transmitted from a first node through a kth node, respectively, calculating, based on a predetermined criterion, a reliability of the first symbol through the kth symbol, respectively, selecting one or more symbols from among the first through the kth symbol that have a reliability that is greater than or equal to the predetermined criterion, and generating a transmission signal that maintains the reliabilities of the selected symbols and that excludes components of symbols that have reliabilities which are less than the predetermined criterion.
In another aspect, there is provided a relay node including a receiving unit to receive a signal including a first symbol through a kth symbol that are transmitted from a first node through a kth node, respectively, and a processing unit to calculate, based on a predetermined criterion, reliabilities of the first symbol through the kth symbol, respectively, wherein the processing unit selects one or more symbols that have a reliability that is greater than or equal to the predetermined criterion from among the first symbol through the kth symbol, and generates a transmission signal that maintains the reliabilities of the selected symbols and that excludes components of symbols that have reliabilities which are less than the predetermined criterion.
The processing unit may generate the transmission signal to decrease an expected power of error between the transmission signal and the received signal.
The processing unit may calculate the reliabilities of the first symbol through the kth symbol, based on log likelihood ratio (LLR) with respect to the first symbol through the kth symbol, respectively, each LLR calculated based on the received signal and channel information that is associated with the first node through the kth node, respectively.
The processing unit may generate the transmission signal in which LLRs of the selected symbols are equivalent to LLRs of the selected symbols in the received signal or are within a predetermined range.
The equivalence or the difference in the predetermined range may be determined based on the Kullback-Leibler distance.
The processing unit may estimate channels with respect to the first node through the kth node based on pilots that are transmitted from the first node through the kth node, respectively.
The relay node may further comprise a transmitting unit to transmit the transmission signal to a first destination node through a kth destination node corresponding to the first node through the kth node, respectively.
The transmitting unit may scale the transmission signal based on a predetermined transmission power, and transmit the scaled transmission signal.
The transmitting unit may transmit identification information that is associated with nodes corresponding to the selected symbols.
In another aspect, there is provided a relay node in a wireless network, the relay node including a receiver configured to receive symbols from one or more nodes that are within the wireless network, a processor configured to determine a reliability of each received symbol based on a physical layer network coding method that uses reliability, and a transmitter configured to transmit only those received symbols that are determined to have a reliability above a threshold.
The physical layer network coding method may calculate the reliability of a received symbol based on a log likelihood ratio (LLR) of the received symbol and channel information that is associated with a node that transmitted the received symbol.
The receiver may be further configured to simultaneously receive a first symbol from a first node and a second symbol from a second node, and the processor may be further configured to determine a reliability of the first symbol and the second symbol based on the physical layer network coding method that uses reliability.
In response to the receiver determining that the first symbol has a reliability above the threshold, and that the second symbol has a reliability below the threshold, the transmitter may be further configured to transmit a transmission signal including the first symbol and excluding the second symbol.
Other features and aspects may be apparent from the following detailed description, the drawings, and the claims.
Throughout the drawings and the detailed description, unless otherwise described, the same drawing reference numerals should be understood to refer to the same elements, features, and structures. The relative size and depiction of these elements may be exaggerated for clarity, illustration, and convenience.
The following detailed description is provided to assist the reader in gaining a comprehensive understanding of the methods, apparatuses, and/or systems described herein. Accordingly, various changes, modifications, and equivalents of the methods, apparatuses, and/or systems described herein may be suggested to those of ordinary skill in the art. Also, descriptions of well-known functions and constructions may be omitted for increased clarity and conciseness.
A network error correcting method based on a physical layer network coding method may be used to correct errors that occur between communication links when a network coding scheme is used in a wireless ad hoc network environment. The network error correcting method that uses the physical layer network coding method may be applied without a significant change regardless of whether a number of nodes increases or decreases, and may be applicable to a wireless sensor network environment.
Referring to
The algebraic network coding scheme may be a packet level network coding scheme. For example, node V1 and node V2 may transmit signal X1(w1) and signal X2(w2) to node V3, respectively. In this example, node V1 and node V2 may stagger the transmission of signal X1 and signal X2. Relay node V3 may decode a received signal to obtain data {tilde over (w)}1 and data {tilde over (w)}2, and may apply the network coding scheme to data {tilde over (w)}1 and data {tilde over (w)}2 to generate a transmission signal {tilde over (w)}1{tilde over (w)}2. Relay node V3 may broadcast the transmission signal.
Node t1 and node t2 are located inside a coverage area 130 of node V3 and may receive the transmission signal of the relay node V3. Accordingly, node t1 may obtain signal X1 by network decoding signal X2 that is received from node V2 and the transmission signal from relay node V3. In the same manner, node t2 may obtain data X2 by network decoding signal X1 that is received from node V1 and the transmission signal from relay node V3.
In the algebraic network coding scheme, a relay node decodes each of signals that are received from transmission nodes, and thus, the relay node has a high complexity. Also, the algebraic network coding scheme may be vulnerable to interference from other transmission nodes.
Referring to
In the analog network coding scheme, node V1 may transmit signal X1 to relay node V3, and simultaneously, node V2 may transmit signal X2 to relay node V3. Relay node V3 may amplify a received signal including signal X1 and signal X2 to broadcast a generated transmission signal, without decoding the received signal.
Node t1 may obtain signal X1 based on signal X2 that is received from node V2 and the transmission signal from relay node V3, and node t2 may obtain signal X2 based on signal X1 that is received from node V1 and the transmission signal from relay node V3.
In the analog network coding scheme, a relay node may merely amplify and transmit a received signal, which also amplifies noise. Accordingly, a destination node may be significantly affected by noise.
Therefore, there is a need for a physical layer network coding method that is robust and scalable to overcome a drawback of the conventional network coding scheme. In various examples herein, a relay node may generate a transmission signal by removing a component that has a low reliability from a received signal, and may broadcast the generated transmission signal.
Various scenarios are provided as examples in the following. For example, node Vj receives packets P1,j, P2,j, . . . , Pk,j from transmission nodes Vi (i=1, 2, . . . , k). Each transmission node Vi may use a transmission power P. In this example, the packet Pi,j is encoded as l constellation symbols Xi,j1Xi,j2 . . . Xi,jl. A signal received by node Vj is Yj1Yj2 . . . Yjl.
A received packet Yjm (m=1, 2, . . . , l) may be modeled as a corrupted version of a scaled versions of Xi,jm by njm that are independent identically distributed (i.i.d.) samples of additive noise nj that have a mean of zero and a variance of σ2 per complex dimension. Yjm may be expressed by equation
(m=1, 2, . . . , and l).
In this equation, αi,j denotes a channel coefficient of channel between node Vi to relay node Vj.
In the conventional network coding scheme, symbols Xi,j1Xi,j2 . . . Xi,jl (i=1, 2, . . . , k) may be selected from the same lattice L. The selected lattice may be an integer lattice Z1 or may be another lattice that has higher shaping gains. Relay node Vj may calculate {tilde over (Y)}jm=Σi=1kbiXi,jm (m=1, 2, . . . , l) and a coefficient (b1, . . . , bk), based on the received packet Yjm. In this example, the coefficient (b1, . . . , bk) may be an integer vector. Relay node Vj may transmit a transmission signal {tilde over (Y)}j1{tilde over (Y)}j2 . . . {tilde over (Y)}jl.
To generate the transmission signal {tilde over (Y)}j1{tilde over (Y)}j2 . . . {tilde over (Y)}jl, relay node Vj may select a factor λ. The factor λ may be a factor that enables (λα1,j, λα2,jj, . . . , λαk,j) to be as close to a point (b1, . . . , bk) of the integer lattice Zk. If the point (b1, . . . , bk) is a point closest to the integer lattice Zk to (λα1,j, λα2,jj, . . . , λαk,j), a signal-to-noise ratio (SNR) of the transmission signal of relay node Vj may be represented by
Therefore, the factor λ that increases the SNR the most may be determined.
The conventional schemes assume that receiver nodes are informed of a channel coefficient αi,j. However, if a relay node Vj is not completely aware of the channel coefficient αi,j and a high αi,j is requested, an actual SNR of the transmission signal {tilde over (Y)}j1{tilde over (Y)}j2 . . . {tilde over (Y)}jl may be lowered. According to the conventional schemes, performance may be based on αi,j when the receiver nodes are not completely aware of the channel coefficient αi,j.
Therefore, a robust physical layer network coding method may be requested. A wireless sensor network that has a large change in topology based on access of member nodes may have robustness, scalability, and locality. Therefore, there is a need for a physical layer network coding method in which each node does not need a large amount of information associated with a network topology, an algorithm does not need to be significantly changed based on a change in a number of nodes, and in which performance is high.
Various examples herein are directed towards a physical layer network coding method that enhances the robustness by removing components of signals that have low reliabilities at each node. Hereinafter, an example of the physical layer network coding method is described with reference to a system model of
Referring to
r=α1,3x1+α2,3x2+n
In this example, xi(−1)b
In this example, a log likelihood ratio (b1) (LLR (b1)) is greater than a predetermined threshold and an LLR (b2) is not. Here, LLR (b)=ln {p(b=0|r)/p(b=1|r)}. Also in this example, the bit b1 transmitted from node V1 is greater than a predetermined criterion, and the bit b2 transmitted from node V2 is less than the predetermined criterion.
Node V3 may generate a transmission signal ({tilde over (r)}) as expressed by
{tilde over (r)}=α1,3x1+ñ
In this example, ñ is an additive white Gaussian noise (AWGN) that has a mean of zero and a variance of σ2 per real dimension. Also, σ2 is a value to be optimized.
In this example, {tilde over (r)} may be generated to have a distribution of an LLR that is approximately the same as the LLR (b1), based on the Kullback-Leibler distance. Also, {tilde over (r)} may be generated to include minimum noise. Accordingly, {tilde over (r)} may be generated to minimize or otherwise reduce an expected power of error. {tilde over (r)} may be generated to decrease the expected power of error and to remove an effect of the bit b2 of which a reliability is lowered by Gaussian noise.
The physical layer network coding method may consume power for transmitting a bit that has a high reliability, as opposed to transmitting a bit that has a low reliability, and thus, may improve performance in transmission.
Hereinafter, an example of a method of node V3 that generates {tilde over (r)} is described. If a signal transmitted from node Vi has a high reliability, and a signal transmitted from node V2 has a low reliability, node V3 may generate {tilde over (r)} as given in Equation 1. As another example, if the signal from node V1 has a low reliability and a signal from node V2 has a high reliability, the transmission signal {tilde over (r)} generated by node V3 may be α2,3x+ñ. If both the signal from node V1 and the signal from node V2 have high reliabilities, {tilde over (r)} generated by node V3 may be α1,3x+α2,3x+ñ. If both the signal from node V1 and the signal from node V2 have low reliabilities, node V3 may not generate {tilde over (r)}.
{tilde over (r)}=α1,3x+ñ [Equation 1]
In Equation 1, x is selected from signal constellation A1={c1, c2, . . . , cr1} and ñ is an AWGN having a mean of zero and a variance of σ2 per complex dimension.
Assuming that pi(=p(xi=ci|r)) p(x=ci|{tilde over (r)}) with respect to all i=1, 2, . . . , r1, an expected power of error may be expressed by Equation 2.
Node V3 may generate {tilde over (r)} that minimizes the expected power of error.
For example, assuming that di=|{tilde over (r)}−ci|, i=1, 2, . . . , r1, Equation 3 may be obtained without loss of generality by re-labeling.
p1≧p2≧p3≧ . . . ≧pr
Equation 4 may be obtained by assuming that noise ñ is the Gaussian model.
(for i=1, 2, . . . , r1)
In this example,
may be obtained by modifying Equation 4, and Equation 5 may be obtained by modifying Equation 2 that is associated with the expected power of error.
Assuming that H(P)=−Σi=1r
In this example, if pj is substituted for p1, Equation 7 may be obtained with respect to an optimal {tilde over (r)}.
(for all J=1, 2, . . . r1)
In Equation 7, Ko denotes a constant. Accordingly, Ko and σ2 that minimize Equation 8 representing the expected power may be selected.
For simplicity, assuming that
<Scheme for a Constellation Having Two Elements>
A method of calculating an optimal {tilde over (r)} when signal constellation A1 has two elements, namely, when r1=2, is described.
First, an objective function such as the expected power of error d12+σ22(ln(pl)+H(P)), may be minimized with respect to a fixed σ2 by decreasing d1. When d1 decreases based on Equation 7, d2 may also decrease. However, d1+d2≧|c1−c2|, based on a triangle inequality.
Therefore, d1 and d2 that minimize the expected power of error with respect to the fixed σ2 may be obtained by Equation 9.
d1d2=|c1−c2| [Equation 9]
When d=|c1−c2|, Equation 10 may be obtained from
d
2
2
−d
1
2=σ22(a1−a2) [Equation 10]
Therefore, a difference between d2 and d1 may be given by Equation 11.
d2 and d1 may be expressed by Equation 12.
The expected power of error may be expressed by Equation 13, based on Equation 12.
When Equation 13 is differentiated with respect to σ22, σ22 that minimizes the expected power of error may be obtained as expressed by Equation 14.
In this example, d1 and d2 may be expressed by Equation 15, based on Equation 14.
Equation 15 may be simplified as given in Equation 16.
d1=p2d
d2=p1d [Equation 16]
The optimal {tilde over (r)} may be expressed by Equation 17.
{tilde over (r)}=p1c1+p2c2 [Equation 17]
<Scheme for a Constellation Having Two or More Elements>
For a given pi(=p(xi=ci|r)), i=1, 2, . . . , r1, a value for {tilde over (r)} that always satisfies Equation 18 may not exist.
pi=p(x=ci|{tilde over (r)}), i=1,2, . . . ,r1 [Equation 18]
When {tilde over (r)} that satisfies Equation 18 exist, Equation 19 may be satisfied for all i≠j.
The equations in Equation 19 may correspond to lines that are perpendicular to a line segment between ci and cj.
The lines may not always meet at the same {tilde over (r)}. If the lines meet at the same {tilde over (r)}, pi (i=1, 2, . . . , r1) may be a geometrically consistent probability distribution function (PDF).
In this example, complete matching may be difficult, and thus, there is a need for an {tilde over (r)} that enables an a posteriori PDF, that is, p(x=ci|{tilde over (r)}) to be as close to pi based on the Kullback-Leibler distance, and that minimizes the expected power of error corresponding to Σi=1r
The a posteriori PDF induced by {tilde over (r)} may be expressed by Equation 20.
The Kullback-Leibler distance between a distribution P and an a posteriori distribution may be expressed by Equation 21.
In this example, Σj=1r
Therefore, Equation 21 may be modified as Equation 23.
At a high SNR, a correct {tilde over (r)} and a most adjacent point to the correct {tilde over (r)} may have non-negligible posterior probabilities p1 and p2. In this example, d12≅p22d2 as described herein, and thus, the minimization of the Kullback-Leibler distance may be equivalent to the minimization of the expected power of error corresponding to Σj=1r
Various examples are further provided herein. A first example describes BPSK transmission by two source nodes V1=S1 and V2=S2, and reception by an intermediate node V3. A second example describes a case in which a higher order constellation and three or more transmission nodes exist. A third example describes transmission from arbitrary nodes, for example, relay nodes or source nodes, to arbitrary nodes.
<BPSK Transmission Example>
Node V3 corresponding to a relay node receives source packets P1,3 and P2,3 from node Vi (i=1,2) at an average transmission power P per node. In this example, packet Pi,j is encoded as 1 constellation symbols as shown in Equation 25.
Xi,31Xi,32 . . . Xi,3l [Equation 25]
A signal received by node V3 is expressed by Equation 26.
Y31Y32 . . . Y3l [Equation 26]
The received signal (Y3m) (m=1, 2, . . . , |) may be modeled as a corrupted version of a scaled version of Xi,jm by n3m. In this example, n3m is an i.i.d. sample of complex additive noise that has a mean of zero and a variance of σ2/2 per real dimension. Y3m may be expressed by Equation 27.
(for m=1, 2, . . . , l)
In Equation 27, αi,3 is a channel coefficient of a channel from node Vi (i=1, 2) to the node V3.
In various examples, a potentially coded signal may be used, and thus, node V3 may perform symbol-by-symbol transmission to reduce a complexity of node V3. Node V3 may regard BPSK symbols Xi,31Xi,32 . . . Xi,3l (i=1, 2) as uncoded symbols and may calculate LLRs of symbols Xi,3m (i=1, 2) from Yjm (m=1, 2, . . . , l). Node V3 may also calculate an average function of the LLRs as expressed by Equation 28.
Other functions may be applicable. However, an LLR that is obtained from transmission of a BPSK uncoded signal may show that the LLR may be closely related to an average virtual SNR of each symbol stream. Node V3 may select thresholds (T31 and T32), in advance. In this example, T31 and T32 denote LLR qualities of data streams, appropriated for decoding, which are from node V1 and node V2, respectively.
On the assumptions set forth in the forgoing, three cases may be possible based on a reliability of Y3m of node V3.
Case 1: LLR1>T31 and LLR2<T32 or LLR1<T31 and LLR2>T32
Case 2: all LLRi>T31 for i=1, 2
Case 3: all LLRi≦T3i for i=1, 2
Case 1 describes an example in which LLR1>T31 and LLR2<T32 without loss of generality.
In this example, node V3 may generate a transmission signal ({tilde over (Y)}3m) (m=1, 2, . . . , l) that has that p(X1,3m|{tilde over (Y)}3m) has the same a posteriori probability distribution as p(X1,3m|Y3m), and that minimizes an expected power of error. A method of generating {tilde over (Y)}3m has been previously described and is given in Equation 29.
{tilde over (Y)}3m=α1,3X1,3m+ñ3m [Equation 29]
In this example, {tilde over (Y)}3m may have the same LLR as LLR1 with respect to X1,3m, and thus, from a point of view of receiver node t1, {tilde over (Y)}3m may be equivalent to X1,3m and {tilde over (Y)}3m may not carry information that is associated with X2,3m. Node V3 may scale {tilde over (Y)}31{tilde over (Y)}32 . . . {tilde over (Y)}3l using a constant factor β so that a sequence (β{tilde over (Y)}3m) (m=1, 2, . . . , l) may have an average power P. Node V3 may perform scaling to satisfy another predetermined power constraint, such as a peak power. Node V3 may transmit β{tilde over (Y)}3m. In this example, the information that is associated with X2,3m may be removed from a header of the transmitted sequence. That is, identification information associated with node V1 corresponding to X1,3m may be included in a header of β{tilde over (Y)}3m. Accordingly, information that is associated with transmission nodes corresponding to symbols that have high reliabilities may be included in a header of a sequence.
Case 2 describes an example in which Xi,31Xi,32 . . . Xi,3l, i=1,2 have high reliabilities, respectively. Node V3 may generate a transmission signal that satisfies a condition of Case 2 and minimizes an expected power of error. In this example, a set of four possible values of Σi=12αi,3Xi,3m, given by A={±α1,3±α2,3}, may be used.
Here, Y3m of node V3 may be expressed by Equation 30.
Y3m=X3m+n3m (m=1,2, . . . ,l) [Equation 30]
Also, X3m=α1,3X1,3m+α2,3X2,3mεA. Node V3 may calculate {tilde over (Y)}3m that has p(X3m|{tilde over (Y)}3m) that has the same posterior distribution as p(X3m|Y3m) based on the Kullback-Leibler distance, and that minimizes an expected power of error with respect to all m=1, 2, . . . , l.
{tilde over (Y)}3m=X3m+ñ3m [Equation 31]
The method of generating {tilde over (Y)}3m has previously been described herein. Node V3 may scale {tilde over (Y)}31{tilde over (Y)}32 . . . {tilde over (Y)}3l using a constant factor β so that β{tilde over (Y)}3m (m=1, 2, . . . , l) may have an average power P. Also, the scaling may be performed to satisfy another predetermined power constraint, such as a peak power. Node V3 may transmit β{tilde over (Y)}3m. That is, information that is associated with transmission nodes corresponding to symbols that have high reliabilities may be included in a sequence header. Accordingly, information that is associated with all the nodes in Case 2 may be included in a header of β{tilde over (Y)}3m.
Case 3 describes an example in which Xi,31Xi,32 . . . Xi,3l, i=1,2 have reliabilities that are less than or equal to a predetermined criterion, respectively. Accordingly, node V3 may not transmit a stream that is associated with Xi,31Xi,32 . . . Xi,3l, i=1,2. Any further amplification or re-transmission may decrease a quality of an underlying stream in a transmission signal. Accordingly, node V3 may cease transmission and may consume energy.
<Transmission Method for a Higher Order Constellation>
The descriptions herein may be extended to a case in which underlying signals use a higher order constellation, for example, quadrature phase-shift keying (QPSK), 8-phase-shift keying (PSK), and 16-Quadrature Amplitude Modulation (16-QAM). In this example, signal constellations in node V1=S1 and node V2=S2 are referred to as A1 and A2, respectively. A received signal (Y3m) of node V3 may be expressed by Equation 32.
(m=1, 2, . . . , l)
In Equation 32, αi,3 is a channel coefficient of a channel between node Vi (i=1, 2) and node V3.
For each of i=1, 2, m=1, 2, . . . , l and cεAi, an LLR may be calculated as expressed by Equation 33.
In this example,
(i=1, 2, m=1, 2, . . . , l).
Node V3 may calculate an average LLR as expressed by Equation 34.
In this example, node V3 may select thresholds (T31 and T32) in advance. T31 and T32 denote LLR qualities of data streams from node V1 and node V2.
Based on the assumptions set forth herein, three cases may be possible based on a reliability of Y3m of node V3.
Case 1: LLR1>T31 and LLR2<T32 or LLR1<T31 and LLR2>T32
Case 2: all LLRi>T3i for i=1, 2
Case 3: all LLRi≦T3i for i=1, 2
In Case 3, node V3 may not perform transmission in the same manner as the BPSK case.
Case 1 describes an example in which LLR1>T31 and LLR2<T32 without loss of generality. In this example, node V3 may generate a transmission signal ({tilde over (Y)}3m) (m=1, 2, . . . , l) that has p(X1,3m|{tilde over (Y)}3m) that has the same a posteriori probability distribution as p(X1,3m|Y3m), and that minimizes an expected power of error, as given in Equation 35. A method of generating {tilde over (Y)}3m has been described herein.
{tilde over (Y)}3m=α1,3X1,3m+ñ3m [Equation 35]
In this example, {tilde over (Y)}3m may have the same LLR as LLR1 with respect to X1,3m, and thus, from a point of view of receiver node t1, {tilde over (Y)}3m may be equivalent to X1,3m and {tilde over (Y)}3m may not carry information that is associated with X2,3m. Node V3 may scale {tilde over (Y)}31{tilde over (Y)}32 . . . {tilde over (Y)}3l using a constant factor β so that a sequence (β{tilde over (Y)}3m) (m=1, 2, . . . , l) may have an average power P. Node V3 may perform scaling to satisfy another predetermined power constraint, such as a peak power. Node V3 may transmit β{tilde over (Y)}3m. In this example, all information that is associated with X2,3m may be removed from a header of β{tilde over (Y)}3m That is, identification information that is associated with node V1 corresponding to X1,3m may be included in the header of β{tilde over (Y)}3m. Accordingly, information that is associated with transmission nodes corresponding to symbols that have high reliabilities may be included in a header of a sequence.
Case 2 describes an example in which all symbols have high reliabilities, respectively.
Here, a set of r1r2 possible values of Σi=12αi,3Xi,3m, given by A={α1,3c1+α2,3c2|c1εA1,c2εA2}, may be used. In this example, Y3m of node V3 may be expressed by Equation 36.
Y3m=X3m+n3m (m=1,2, . . . ,l) [Equation 36]
Also, X3m=α1,3X1,3m+α2,3X2,3mεA. Node V3 may calculate {tilde over (Y)}3m that has p(X3m|{tilde over (Y)}3m) that has the same a posteriori distribution as p(X3m|Y3m) based on the Kullback-Leibler distance, and that minimizes an expected power of error with respect to all m=1, 2, . . . , l.
{tilde over (Y)}3m=X3m+ñ3m [Equation 37]
Node V3 may scale {tilde over (Y)}31{tilde over (Y)}32 . . . {tilde over (Y)}3l using a constant factor β so that β{tilde over (Y)}3m (m=1, 2, . . . , l) may have an average power P Also, the scaling may be performed to satisfy another predetermined power constraint, such as a peak power. Node V3 may transmit β{tilde over (Y)}3m. In this example, information that is associated with transmission nodes corresponding to symbols that have high reliabilities may be included in a sequence header. Accordingly, information that is associated with all the nodes in Case 2 may be included in a header β{tilde over (Y)}3m.
<Three or More Transmission Nodes>
The descriptions herein may be extended to a case in which three or more transmission nodes corresponding to source nodes perform transmission to a single relay node. Assuming that K transmission nodes exist, a signal constellation of a node Vi=Si (i=1, 2, . . . , k) is referred to as Ai (i=1, 2, . . . , k). In this example, Ai, includes ri (i=1, 2, . . . , k) elements. A received signal of node Vj is expressed by Equation 38.
(m=1, 2, . . . , l)
In Equation 38, αi,j is a channel coefficient of a channel between node Vi (i=1, 2, . . . , k) and node V3.
For each of i=1, 2, m=1, 2, . . . , l and cεAi, an LLR may be calculated as expressed by Equation 39.
Here,
(i=1, 2, . . . , k and m=1, 2, . . . , l)
Node Vj may calculate an average LLR as expressed by Equation 40.
(for i=1, 2, . . . , k)
In this example, node Vj may select thresholds (Tji) (i=1, 2, . . . , k), in advance. Tji denotes LLR qualities of data streams, appropriate for decoding, which are from node Vi. Node Vj may select all of the nodes satisfying LLRi>Tji, that is, all of the nodes that have high reliabilities. If a node satisfying LLRi>Tji does not exist, node Vj may determine that none of symbols in the stream Xi,j1Xi,j2 . . . Xi,jl (i=1, 2, k) have a high reliability and may not transmit a stream associated with Xi,j1Xi,j2 . . . Xi,jl. Any further amplification or re-transmission may decrease a quality of underlying stream in a transmission signal. Accordingly, node V3 may cease transmission and may consume energy.
In this example, LLRi>(i=1, 2, . . . , kl) and LLRi≦Tji (k1<i≦k), for k1 satisfying 1≦k1≦k, without loss of generality. A=A1×A2× . . . ×Ak
are used. For each m=1, 2, . . . , l, node Vj may calculate Equation 41.
Node Vj may generate a transmission signal ({tilde over (Y)}jm) that is modeled as given in Equation 42.
{tilde over (Y)}jm=X+ñ [Equation 42]
XεA is a signal that is transmitted from each transmission node. ñ complex Gaussian noise that has a mean of zero and a variance of σ2 per complex dimension. Node Vj may generate {tilde over (Y)}jm that has p(Xjm|{tilde over (Y)}jm) the same a posterior probability distribution as p(Xjm|Yjm) based on the Kullback-Leibler distance, and that minimizes an expected power of error with respect to all m=1, 2, . . . , l.
Node Vj may scale {tilde over (Y)}j1{tilde over (Y)}j2 . . . {tilde over (Y)}jl using a constant factor β so that a sequence (β{tilde over (Y)}jm) (m=1, 2, . . . , l) may have an average power P. Also, the scaling may be performed to satisfy another predetermined power constraint, such as a peak power. Node Vj may transmit the scaled sequence to receiver nodes. For example, node Vj may transmit a scaled sequence to receiver nodes.
<Transmission from Arbitrary Nodes to Arbitrary Nodes>
A case in which node Vi (i=1, 2, . . . , k) is not necessarily a source node is described. A transmission signal transmitted from each node may have a structure including a linear sum of source signals and noise. The structure is true for nodes in a layer 0 of a network, that is, source nodes. It should also be appreciated that a transmission signal in a layer 1 may have the same structure.
In this example, it is inductively assumed that node V, (i=1, 2, . . . , k) in a layer q (q>1) transmits a signal corresponding to a linear sum of source signals that are influenced by noise. A support of the signal transmitted by node Vi is referred to as supp(vi). In this example, supp(vi) may be a set of all source nodes S1, S2, . . . , SN that appear in the linear summation part of the signal transmitted by node Vi. Also, supp(vi, i=1, 2, . . . , k)=∪i=1ksupp(Vi). A signal at node Vj may be a linear sum of signals of source nodes appear in supp(vi, i=1, 2, . . . , k). In relation to node Vj, it is similar to a case in which sources nodes in ∪i=1ksupp(vi) directly perform transmission to node Vj, with selected channel coefficients.
Accordingly, node Vj may apply the network coding method described herein. Similarly, a signal transmitted from node Vj may also be a signal corresponding to a linear sum of signals, influenced by noise, which are transmitted from source nodes. Accordingly, it is inductively verified that an arbitrary node may transmit a signal corresponding to a linear sum of source signals influenced by noise. Therefore, the physical layer network coding method may be applicable to an arbitrary network such as another relay node.
<Network Coding Header>
An example of a header for the network coding method is described. According to the physical layer network coding method, a header of a signal transmitted by node Vj may include only information supp(vj). For example, the header may include indices of only source nodes included in the support.
In this example, pilot sequences that an intermediate node is aware of, in advance, may be included in respective packets that are transmitted from source nodes so that an intermediate node corresponding to a relay node or a receiver node corresponding to a destination node may estimate effective channel coefficients. The pilot sequences may not be regarded as overhead because the pilot sequences may be used for channel estimation in a communication system that does not use a network coding scheme.
<Decoding in Destination Node>
An example of a reception process in each destination node is described. Based on a transmission strategy of a prior layer, each destination node (Tj) (j=1, 2, . . . , M) may receive Mj linear sums of source packets that include noise, from Nj≦N source nodes S1, . . . , SN. This process is similar to a wireless multi-user transmission that includes N, transmitters and Mj reception antennas. This process is also similar to an Nj×Mj multiple-input multiple-output (MIMO) transmission scenario in which transmission antennas transmit independent coded signals. Therefore, various MIMO receivers, for example, a BLAST receiver, a full maximum likelihood receiver, and the like, may be applied to Tj to decode source packets. For example, if Nj=Mj, a MIMO channel inversion may be applicable to separation of signals transmitted from various source nodes.
<Method of Enhancing Robustness and Scalability>
Each node may use a multilevel structure to determine a constellation to obtain more enhanced robustness and scalability. For example, a QPSK constellation may be a scaled sum of a BPSK constellation, as given by Equation 43.
A 16-QAM constellation may be given by Equation 44.
In the same manner, 32-QAM, and 64-QAM may be expressed by scaled versions of BPSK and QPSK constellations. For example, a source node Si that performs transmission based on the 16-QAM constellation may be a sum of virtual sources Si1 and Si2 that transmits QPSK symbols at channel gains of
Although one of the virtual sources transmits a signal that has a low reliability, the robustness may be enhanced because the other virtual source may transmit a signal.
Referring to
A channel gain αi,j between node Vi in each layer k (k=0, 1) and node in a layer k+1 may be modeled as i.i.d. samples of a circularly symmetric complex Gaussian N(0,1) that have a variance of 0.5 per real dimension, with respect to all i and j. In this example, a received signal of node Vj is corrupted by i.i.d. samples of a circularly symmetric complex Gaussian N(0, σj2) that have a variance of σj2/2 per real dimension. Also, an average transmission power for each transmission node is assumed to be 1. Accordingly, an SNR may be defined as
The transmission from V0=S1 and V1=S2 may be simultaneously received by node V2 and node V3 which correspond to relay nodes, and transmission from node V2 and node V3 may be simultaneously received by node V4 and node V5 which correspond to relay nodes. Transmission from node N4 and transmission from node V5 may be performed at different times, and may be separately received by nodes V6=T1 and V7=T2 corresponding to destination nodes. The source nodes may perform transmission using an uncoded QPSK. For simplicity, all thresholds for reliability are assumed to be zero. Each receiver may perform maximum likelihood (ML) decoding. Hereinafter, results of simulation based on scenarios described herein are provided with reference to
and a result based on a conventional analog-and-forward scheme. The physical layer network coding method that uses reliability may enhance performance by about 2 dB when compared to the conventional scheme. As can be seen, the SNR is improved in the physical network coding method that uses reliability.
In this example, a gain may be enhanced by about 1 dB in
The example simulation results from
Referring to
The relay node respectively calculates the reliabilities of the first symbol through the kth symbol based on a predetermined criterion, in 820. For example, the relay node may calculate reliabilities of the first symbol through the kth symbol, based on corresponding LLRs of the first symbol through the kth symbol. Each LLR may be calculated based on the received signal and corresponding channel information that is associated with the first node through the kth node.
The relay node selects symbols that have reliabilities that are greater than or equal to the predetermined criterion from the first symbol through the kth symbol, in 830.
The relay node generates a transmission signal that maintains the reliabilities of selected symbols and that excludes components that are associated with symbols that have reliabilities that are less than the predetermined criterion, in 840. In this example, the relay node may generate the transmission signal to decrease an expected power of error between the transmission signal of the relay node and a signal corresponding to the received signal excluding noise. For example, the relay node may generate the transmission signal of which LLRs of the selected symbols that are equivalent to LLRs of the selected symbols in the received signal or that are different in a predetermined range. As an example, the equivalency or the difference may be determined based on the Kullback-Leibler distance, or may be based on a different standard.
In 850, a relay node transmits the transmission signal to receiver nodes, that is, a first destination node through a kth destination node that correspond to the first transmission node through the kth transmission node, in 850. The relay node may broadcast the transmission signal. The relay node may scale the transmission signal based on a predetermined transmission power and may transmit the scaled transmission signal. The relay node may transmit identification information that is associated with nodes corresponding to the selected symbols, that is, symbols that have high reliabilities.
Referring to
The receiving unit 910 may receive a signal that includes a first symbol through a kth symbol that is transmitted from a first node through a kth node.
The processing unit 920 may calculate the reliabilities of the first symbol through the kth symbol, respectively, based on a predetermined criterion. The processing unit 920 may select symbols that have reliabilities that are greater than or equal to the predetermined criterion from the first symbol through the kth symbol. The processing unit 920 may generate, based on the received signal, a transmission signal that maintains the reliabilities of the selected symbols and that excludes components that are associated with symbols that have reliabilities that are less than the predetermined criterion.
The transmitting unit 930 may transmit the transmission signal.
A relay node and a communication method of the relay node have been previously described. That is, the examples described herein with reference to
Various examples are directed towards a relay node that determines the reliability of symbols corresponding to a plurality of nodes, based on a signal received from the plurality of nodes. The relay node may generate a transmission signal to maintain the reliability of symbols having high reliabilities and to exclude components of symbols that have low reliabilities. Accordingly, the relay node may reduce an amount of power consumed for transmitting symbols that have low reliabilities and may consume a greater amount of power for transmitting symbols that have high reliabilities. Accordingly, transmission efficiency may increase.
In various examples, the relay node may generate a transmission signal that reduces an expected power of error based on a signal that is received from a plurality of nodes, and thus, may reduce the effect of noise.
In various examples, a transmission signal generating method of a relay node may have a high scalability because the method may be performed regardless of a change in a number of nodes.
Program instructions to perform a method described herein, or one or more operations thereof, may be recorded, stored, or fixed in one or more computer-readable storage media. The program instructions may be implemented by a computer. For example, the computer may cause a processor to execute the program instructions. The media may include, alone or in combination with the program instructions, data files, data structures, and the like. Examples of computer-readable storage media include magnetic media, such as hard disks, floppy disks, and magnetic tape; optical media such as CD ROM disks and DVDs; magneto-optical media, such as optical disks; and hardware devices that are specially configured to store and perform program instructions, such as read-only memory (ROM), random access memory (RAM), flash memory, and the like. Examples of program instructions include machine code, such as produced by a compiler, and files containing higher level code that may be executed by the computer using an interpreter. The program instructions, that is, software, may be distributed over network coupled computer systems so that the software is stored and executed in a distributed fashion. For example, the software and data may be stored by one or more computer readable storage mediums. Also, functional programs, codes, and code segments for accomplishing the example embodiments disclosed herein can be easily construed by programmers skilled in the art to which the embodiments pertain based on and using the flow diagrams and block diagrams of the figures and their corresponding descriptions as provided herein. Also, the described unit to perform an operation or a method may be hardware, software, or some combination of hardware and software. For example, the unit may be a software package running on a computer or the computer on which that software is running.
As a non-exhaustive illustration only, a terminal/node described herein may refer to mobile devices such as a cellular phone, a personal digital assistant (PDA), a digital camera, a portable game console, and an MP3 player, a portable/personal multimedia player (PMP), a handheld e-book, a portable lab-top PC, a global positioning system (GPS) navigation, a tablet, a sensor, and devices such as a desktop PC, a high definition television (HDTV), an optical disc player, a setup box, a home appliance, and the like that are capable of wireless communication or network communication consistent with that which is disclosed herein.
A computing system or a computer may include a microprocessor that is electrically connected with a bus, a user interface, and a memory controller. It may further include a flash memory device. The flash memory device may store N-bit data via the memory controller. The N-bit data is processed or will be processed by the microprocessor and N may be 1 or an integer greater than 1. Where the computing system or computer is a mobile apparatus, a battery may be additionally provided to supply operation voltage of the computing system or computer. It will be apparent to those of ordinary skill in the art that the computing system or computer may further include an application chipset, a camera image processor (CIS), a mobile Dynamic Random Access Memory (DRAM), and the like. The memory controller and the flash memory device may constitute a solid state drive/disk (SSD) that uses a non-volatile memory to store data.
A number of examples have been described above. Nevertheless, it should be understood that various modifications may be made. For example, suitable results may be achieved if the described techniques are performed in a different order and/or if components in a described system, architecture, device, or circuit are combined in a different manner and/or replaced or supplemented by other components or their equivalents. Accordingly, other implementations are within the scope of the following claims.
Number | Date | Country | Kind |
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10-2011-0013553 | Feb 2011 | KR | national |
10-2011-0042565 | May 2011 | KR | national |
This application claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application No. 61/443,290, filed on Feb. 16, 2011, in the U.S. Patent and Trademark Office, and the benefit under 35 U.S.C. §119(a) of Korean Patent Application No. 10-2011-0013553 filed on Feb. 16, 2011, and Korean Patent Application No. 10-2011-0042565 filed on May 4, 2011, in the Korean Intellectual Property Office, the entire disclosures of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
7107498 | Schmidt et al. | Sep 2006 | B1 |
20080244364 | Shieh et al. | Oct 2008 | A1 |
20090270028 | Khojastepour et al. | Oct 2009 | A1 |
20100246474 | Zhang et al. | Sep 2010 | A1 |
20100260240 | Wang | Oct 2010 | A1 |
20100329227 | Argyriou | Dec 2010 | A1 |
20110096722 | Jung | Apr 2011 | A1 |
Number | Date | Country |
---|---|---|
10-2006-0133928 | Dec 2006 | KR |
10-2009-0063040 | Jun 2009 | KR |
10-2010-0060435 | Jun 2010 | KR |
Number | Date | Country | |
---|---|---|---|
20120207193 A1 | Aug 2012 | US |
Number | Date | Country | |
---|---|---|---|
61443290 | Feb 2011 | US |