1. Field of the Invention
The invention relates to a method and a device for determining an extrinsic information.
2. Discussion of the Background
To allow an exact detection of Phase-Shift-Keying (PSK) modulated symbols in a transmission channel of which the phase transmission behavior is time-variable because of phase noise, pilot symbols are transmitted for an estimation of the transmission function of the transmission channel characterizing the time-variable phase-transmission behavior. If a transmission in short blocks is provided and if an estimation of the phase-transmission behavior is required in every block, a coherent detection of this kind impairs the transmission efficiency to a considerable extent and accordingly fails.
In the case of a non-coherent detection of a PSK-modulated symbol, especially a differential PSK-modulated symbol, there is no transmission of pilot symbols. Instead, probability distributions of the phase of the transmission channel are additionally determined in the detection alongside estimated values for the individual transmitted PSK-modulated symbols, which leads to an increase in the complexity of the detection. Barbieri, A. et al. “Soft-Output Decoding of Rotationally Invariant Codes Over Channels with Phase Noise”, IEEE Transactions on Communications, Volume 55, No. 11, November 2007, pages 2125 to 2133, describes a recursive detection method which presents a non-coherent detection of differentially M-PSK-modulated symbols.
This detection method is disadvantageously characterized by a plurality of additions, multiplications and divisions, which impair the detection of PSK modulated symbols in real-time. Moreover, this detection method is characterized by a wide dynamic range of the values to be calculated, which makes a fixed-point implementation more difficult.
Embodiments of the invention therefore advantageously develop a method and a device for real-time-compatible detection of differentially phase-modulated symbols in a transmission channel subject to phase noise.
Accordingly, for every symbol time and every symbol hypothesis, an associated extrinsic information is determined, which results from the relationship of the a-posteriori probability for the respective symbol hypothesis at the respective symbol time with a given sequence of sampled values of the received signal and the a-priori probability for the respective symbol hypothesis.
The a-posteriori probability for the respective symbol hypothesis with a known sequence of sampled values of the received signal also provides a dependence upon the a-posteriori probability of the phase of the transmission channel with a known sequence of sampled values of the received signal and assuming a positive, real, coded symbol. The probability density of the phase of the transmission channel at a given time with a known sequence of sampled values of the received signal from the beginning of the sequence up to the given time and assuming a positive, real, coded symbol is approximated as the sum of Tikhonov distributions weighted respectively with a weighting factor and dependent respectively upon a complex coefficient and the phase of the transmission channel. By analogy, the probability density of the phase of the transmission channel at the given time with a known sequence of sampled values of the received signal from the given time to the end of the received sequence and with the assumption of a positive, real, coded symbol is approximated as the sum of Tikhonov distributions weighted respectively with a weighting factor and dependent respectively upon a complex coefficient and upon the phase of the transmission channel.
With this approximation of the probability density of the phase of the transmission channel, a recursive solution which can therefore be transferred into industrial practice to determine the extrinsic information for the respective symbol hypothesis is obtained. The disadvantage still associated with this approximation solution of a plurality of additions, multiplications and divisions to be implemented, which has hitherto stood in the way of real-time-compatible implementation, is removed by the determination according to the invention of a log extrinsic information. Moreover, the logging of the extrinsic information leads to a reduction in the signal modulation and accordingly to a dynamic reduction. With a fixed-point implementation, an efficient implementation of the method according to the invention is therefore achieved.
The logging of the extrinsic information leads to a calculation formula for the extrinsic information, in which log weighting factors and complex coefficients of the Tikhonov distribution occur, which are determined respectively in a recursion running in a positive time direction, referred to below as a forward recursion, and a recursion running in a negative time direction, referred to below as a backward recursion.
While in the case of the recursive calculation of the complex coefficient of the Tikhonov distribution for a given symbol time with a forward recursion, the symbol received at the same symbol time is preferably additively linked to the complex coefficient of the Tikhonov distribution determined for the preceding symbol time, in the case of a backward recursion, the symbol received at the same symbol time is preferably additively linked to the complex coefficient of the Tikhonov distribution determined for the following symbol time.
With the recursive calculation of the log weighting factor of the Tikhonov distribution for a given symbol time in the case of a forward recursion, the so-called Jacobi-logarithm is determined from the previously known log a-priori probability for all of the symbol hypotheses to be investigated for the same symbol time and the log weighting factors of the Tikhonov distribution for the preceding symbol time, and in the case of a backward recursion, the Jacobi-logarithm is determined from the previously known log a-priori probability for all symbol hypotheses to be investigated for the following symbol time and the log weighting factors of the Tikhonov distribution for the following symbol time.
In a preferred first variant, the Jacobi-logarithm is calculated accurately by adding a maximal-value function and a correction function, and, in a second variant, it is approximated by ignoring the correction function.
The connection between the recursion of the complex coefficient of the Tikhonov distribution determined for a given symbol time and the recursion of the log weighting factor of the Tikhonov distribution determined for a given symbol time is implemented by adding a complex coefficient of the Tikhonov distribution determined for the same symbol time to the result of the Jacobi-logarithm. Accordingly, in the case of the previously implemented calculation of the complex coefficient of the Tikhonov distribution determined for the same symbol time, with a forward recursion, the complex coefficient of the Tikhonov distribution for the preceding symbol time, or respectively, with a backward recursion, the complex coefficient for the Tikhonov distribution for the following symbol time is preferably multiplied by a phase term corresponding to a possible symbol hypothesis of the PSK-modulation used. By preference, the modulus of the complex coefficient of the Tikhonov distribution is added to the result of the Jacobi logarithm.
In each case, the complex coefficient of the Tikhonov distribution used for the calculation of the log extrinsic information and determined respectively in a forward or respectively a backward recursion is preferably that complex coefficient of the Tikhonov distribution for the recursive calculation of which the complex coefficient of the Tikhonov distribution determined for the preceding symbol time (in the case of a forward recursion), or respectively, the complex coefficient of the Tikhonov distribution determined for the following symbol time (in the case of a backward recursion) is multiplied respectively by a phase term, of which the phase factor corresponds to the phase factor of the respective maximal log weighting factor of the Tikhonov distribution for the same symbol time.
Through the logging according to the invention of the extrinsic information, multiplications occurring in the individual recursion formulae are replaced with less calculation-intensive additions.
Through the preferred introduction of the Jacobi-logarithm into the recursion formulae of the weighting factors of the Tikhonov distribution and into the calculation formulae of the extrinsic information, a logarithmic summation of exponential functions which is very costly to implement is advantageously avoided.
The preferred determination of the phase factor in the phase term associated with every symbol hypothesis at which the log weighting factor of the Tikhonov distribution becomes maximal, reduces the summation occurring in the recursion formulae for the determination of the complex coefficients of the Tikhonov distribution to a significantly simpler calculation of a single summand instead of a cost-intensive division.
The calculation of the extrinsic information is preferably implemented through Jacobi logging of the log weighting factors determined respectively in the forward recursion and in the backward recursion of the Tikhonov distribution, taking into consideration the complex coefficients of the Tikhonov distribution determined respectively in the forward recursion and in the backward recursion.
The device according to the invention and the method according to the invention for determining an extrinsic information are explained in detail below with reference to the drawings. The figures of the drawings are as follows:
Before the method according to embodiments of the invention for determining an extrinsic information is described in greater detail with reference to the flow diagram in
The following section considers a transmission system in which, at individual symbol times k=1, . . . , K, data symbols ak to be transmitted which satisfy the symbol alphabet of a multi-value Phase-Shift-Keying (PSK) according to equation (1), are subjected to a differential M-PSK modulation according to equation (2). The coded symbols ck generated in this manner at the individual symbol times k=1, . . . , K also satisfy the symbol alphabet of an M-PSK modulation according to equation (3).
The coded symbols ck generated by means of a differential M-PSK modulation are transmitted on a non-frequency-selective transmission channel with an approximately constant amplification factor which provides a phase noise and an additive Gaussian noise.
The phase noise is modelled through a time-variable phase θk. The time behavior of the time-variable phase θk corresponds to the mathematical relationship in equation (4), The phase increment Δk in equation (4) satisfies a real Gaussian distribution and provides a mean value of zero and a standard deviation σΔ. The phase θ0 at the symbol time zero is distributed over the phase range between zero and 2π corresponding to a uniform distribution. While the standard deviation σΔ of the phase increment Δk is determined through measurement and/or simulation and is therefore known to the receiver, the sequence of the individual phase increments Δk is not known to the receiver and is statistically independent of the additive Gaussian noise νk and of the coded symbol ck.
The additive Gaussian noise, which corresponds to a complex, additive, white, Gaussian noise (Additive White Gaussian Noise (AWGN) with a mean value of zero and a variance N0=2σ2, is described by the noise term νk. Any existing real amplification factor of the transmission channel is taken into consideration by standardization of the variance of the additive Gaussian noise.
θk−1=θk+Δk for k=0, . . . ,K (4)
The sampled value of the received signal rk after the matched filtering is obtained according to equation (5).
r
k
=c
k·θjθ
In the following section, the detection method according to the invention is derived on the basis of the Maximum A-Priori (MAP) symbol detection algorithm. In order to estimate the sequence a={ak}k=1K of symbols to be transmitted independently of one another in the case of an unknown sequence θ={θk}k=0K of mutually independent phase values of the transmitted signal, in the case of an unknown) sequence c={ck}k=1K of coded symbols dependent upon one another because of the differential modulation and in the case of a known sequence r={rk}k=0K of sampled values of the received signal, the conditional probability density p(a,c,θ|r) for the simultaneous occurrence of a given sequence a of symbols to be transmitted, a given sequence θ of phase values of the transmission channel and a given sequence c of coded symbols with a known and therefore given sequence r of sampled values of the received signal must be determined with a MAP-algorithm.
This conditional probability density p(a,c,θ|r) can be mathematically converted according to equation (6) using the general relationship for a conditional probability or respectively conditional probability density according to equation (7). The probability density p(r) for the occurrence of the sequence r of sampled values of the received signal occurring in this context is identical for all possible values of the sequences a and c; it can therefore be ignored. On the basis of the discrete value range of the sequences a and c according to equation (6), the probability density p(a,c,θ,r) can be broken down into a probability P(a,c) and a conditional probability density p(r,θ|a,c). Since the sequence c of coded symbols is dependent upon the sequence a of symbols to be transmitted, the probability P(a,c) can be converted into the mathematical relationship P(a,c)=P(a)·P(c|a). Since the sequence r of sampled values of the received signal not only a dependence upon the sequences a and c, but also a dependence upon the sequence θ, the probability density p(r,θ|a,c) can be converted into the mathematical relationship p(r,θ|a,c)=p(r|θ,a,c)·p(θ|a,c).
Since the sequence θ of phase values of the transmission channel is independent of the sequence a of symbols to be transmitted and of the sequence c of coded symbols, the probability density p(θ|a,c) is obtained as p(θ|a,c)=p(θ). Since the sequence r of sampled values of the received signal in the case of a given sequence c of coded symbols is independent of the sequence a of symbols to be transmitted, the probability density p(r|θ,a,c) is obtained as p(r|θ,a,c)=p(r|θ,c). In summary, a mathematical relationship for the probability density p(a,c,θ|r) can be formulated according to the second line in equation (6).
The probability density p(a) for the occurrence of the sequence a of symbols to be transmitted is obtained according to equation (8) from the product of the probabilities for the occurrence of each individual symbol ak, because, by way of mathematical simplification, an independence of the individual symbols to be transmitted relative to one another is assumed. This independence of the individual symbols to be transmitted is not always given in reality.
The probability density p(θ) for the occurrence of the sequence θ of phase values of the transmission channel can be determined according to equation (9) on the basis of the dependence of the individual phase values relative to one another from the product of the probability density p(θ0) for the occurrence of the phase value θ0 at the symbol time zero and the probability densities p(θk|θk−1) for the occurrence of the phase value θk at the symbol time k on the condition that the phase value θk−1 is known for the preceding symbol time k−1.
The probability density p(c|a) for the occurrence of the sequence c of coded symbols subject to the condition that the sequence a of symbols to be transmitted is known at the same time, is obtained according to equation (10) from the product of the probability density p(c0) for the occurrence of the coded symbol c0 at the symbol time zero and the indicator function I(ck,ck−1,ak) associated respectively with each coded symbol ck, which, in the presence of the coding condition according to equation (2), provides the value one and otherwise provides the value zero.
The probability density p(r|c,θ) for the occurrence of the sequence r of sampled values of the received signal subject to the condition that the sequence c of coded symbols and the sequence θ of phase values of the transmission channel are known at the same time, can be presented according to equation (11) through the product of the probability densities p(rk|c0,θk) for the occurrence of each individual sample value of the received signal rk at the individual symbol times k subject to the condition that the coded symbol ck and the phase value θk of the transmission channel at the individual symbol times k are known at the same time. The probability density p(rk|ck,θk) for the occurrence of each individual sample value of the received signal rk at the individual symbol times k subject to the condition that the coded symbol ck and the phase value θk of the transmission channel at the individual symbol times k are known at the same time, is given in the MAP algorithm according to equation (12) as a Gaussian distribution of the sampled value of the received signal rk at the symbol time k with the product of the coded symbol ck at the symbol time k and the phase term with the known phase value θk at the symbol time k as the mean value.
Taking into consideration equations (8), (9), (10) and (11), starting from equation (6), a relationship for the conditional probability density p(a,c,θ|r) is obtained according to equation (13).
This equation (13) describes the probability density for the occurrence of several unknown sequences, namely the sequence a of symbols to be transmitted, the sequence c of coded symbols and the sequence θ of phase values of the transmission channel, subject to the condition of a known sequence r of sampled values of the received signal. A conversion of this mathematical formula for the probability density with regard to a determination of the symbol
respectively transmitted at each symbol time k is technically too complicated in this form because of the plurality of probability densities linked multiplicatively to one another, which have to be calculated for each sequence a of symbols to be transmitted, for each sequence c of coded symbols and for each sequence θ of phase values of the transmission channel.
One solution to this problem is to separate the overall transmission procedure into a total of three time portions, namely one time portion from symbol time zero (the start of the individual sequences) up to the symbol time k−1, one time portion from the symbol time k−1 up to the symbol time k and one time portion from the symbol time k up to the symbol time K at the end of the individual sequences.
In the time portion from symbol time k−1 to symbol time k, the symbol ak to be transmitted according to equation (2) at symbol time k acts, via the coded symbol ck−1, at the symbol time k−1 directly on the coded symbol ck at the symbol time k. Moreover, according to equation (5), the coded symbol ck, at the symbol time k−1 and the phase value θk−1 of the transmission channel at the symbol time k−1 has a direct effect on the sampled value of the received signal rk−1 at the symbol time k−1, or respectively, the coded symbol ck at the symbol time k and the phase value θk of the transmission channel at the symbol time k has a direct effect on the sampled value of the received signal rk at the symbol time k. Finally, the phase value θk−1 of the transmission channel at the symbol time k−1 acts, according to equation (4), directly on the phase value θk of the transmission channel at the symbol time k.
A parameter which characterizes the probability for the occurrence of the symbol
to be transmitted at the symbol time k, is the extrinsic information εi,k for the symbol ak to be transmitted at the symbol time k, which is defined as the ratio of the a-posteriori probability P(ak|r) of the symbol ak to be transmitted at the symbol time k in the case of a known sequence r of received symbols and the a-priori probability P(ak) of the symbol ak to be transmitted at the symbol time k.
In order to determine the extrinsic information
for the symbol ak to be transmitted at the symbol time k, for all hypotheses of the coded symbol ck−1 and of the phase value θk−1 of the transmission channel at the symbol time k−1, in the case of a known sequence r0k−1 of sampled values of the received signal from the symbol time 0 to the symbol time k−1 and in the case of a known sequence rkK of sampled values of the received signal from the symbol time k to the symbol time K, the associated probabilities of the above-named relationships are summated.
For this purpose, according to equation (14), the probability densities p(ck−1,θk−1|r0k−1) for the occurrence of the coded symbol ck−1 and of the phase value θk−1 of the transmission channel at the symbol time k−1 in the case of a known sequence r0k−1 of sampled values of the received signal from the symbol time 0 to the symbol time k−1, the probability densities p(ck=ck−1·ak,θk|rkK) for the occurrence of the coded symbol ck and of the phase value θk of the transmission channel at the symbol time k in the case of a known sequence rkK of sampled values of the received signal from the symbol time k to the symbol time K and the probability densities p(θk|θk−1) for the phase value θk of the transmission channel at the symbol time k in the case of a known phase value θk−1 of the transmission channel at the symbol time k−1 are multiplied with one another and summated for all hypotheses of the coded symbol ck−1 at the symbol time k−1 and integrated over all hypotheses of the phase value θk−1 of the transmission channel at the symbol time k−1 and of the phase value θk of the transmission channel at the symbol time k.
The probability density p(ck−1,θk−1|r0k−1) for the occurrence of the coded symbol ck−1 and of the phase value θk−1 of the transmission channel at the symbol time k−1 in the case of a known sequence r0k−1 of sampled values of the received signal from the symbol time 0 to the symbol time k−1 can be determined for the time portion from symbol time 0 to the symbol time k−1 within the framework of a forward recursion.
In order to determine a recursion formula for a forward recursion of this kind in the recursion step between the symbol times k−1 and k, the probabilities or respectively probability densities of all relationships according to equation (2), (4) and (5), which are present at the symbol times k−1 and k and between the symbol times k−1 and k, are determined:
The probability density p(ck,θk|r0k) for the occurrence of the coded symbol ck and of the phase value θk of the transmission channel at the symbol time k in the case of a known sequence r0k of sampled values of the received signal from the symbol time 0 to the symbol time k is obtained according to equation (15) within the framework of a forward recursion starting from the probability density p(ck−1,θk−1|r0k−1) for the occurrence of the coded symbol ck−1 and of the phase value θk−1 of the transmission channel at the symbol time k−1 in the case of a known sequence r0k of sampled values of the received signal from the symbol time 0 to the symbol time k by means of a multiplication by the remaining determined probabilities followed by a summation of all hypotheses for the symbol ak to be transmitted at the symbol time k and integration over all hypotheses of the phase value θk−1 of the transmission channel at the symbol time k−1.
The probability density p(ck,θk|rkK) for the occurrence of the coded symbol ck and of the phase value θk of the transmission channel at the symbol time k in the case of a known sequence rkK of sampled values of the received signal from the symbol time k to the symbol time K can be determined for the time portion from the symbol time k to the symbol time K within the framework of a backward recursion.
In order to determine recursion formula for a backward recursion of this kind in the recursion step between the symbol times k−1 and k, the probabilities or respectively probability densities of all relationships according to equations (2), (4) and (5), which are present at the symbol times k−1 and k and between the symbol times k−1 and k, are determined:
The probability density p(ck−1,θk−1|rk−1K) for the occurrence of the coded symbol ck−1 and of the phase value θk−1 of the transmission channel at the symbol time k−1 in the case of a known sequence rk−1K of sampled values of the received signal from the symbol time k−1 to the symbol time K is obtained according to equation (16) in the framework of a backward recursion starting from the probability density p(ck,θk|rkK) for the occurrence of the coded symbol ck and of the phase value θk of the transmission channel at the symbol time k in the case of a known sequence rkK of sampled values of the received signal from the symbol time k to the symbol time by means of a multiplication by the remaining determined probabilities or respectively probability densities followed by a summation of all hypotheses of the symbol ak to be transmitted at the symbol time k and an integration of all hypotheses of the phase value θk of the transmission channel at the symbol time k.
The probability density p(ck−1,θk−1|r0k−1) for the occurrence of the coded symbol ck−1 and of the phase value θk−1 of the transmission channel at the symbol time k−1 in the case of a known sequence r0k−1 of sampled values of the received signal from the symbol time 0 to the symbol time k−1 can be converted according to equation (17) taking into consideration the intermediate values x=θk and y=ck+r0k.
p(ck,θk|r0k)=p(θk|ck,r0k)·p(ck|r0k) (17)
With reference to the documents cited above, the following properties additionally apply:
III. The summation of all hypotheses of the coded symbol ck−1 at the symbol time k−1 in equation (14) disappears, because all M summands are identical.
In particular, with regard to properties I and II, it is the case that within the framework of the forward recursion, only the probability density ψk(θk)=p(θk|ck=1,r0k), and within the framework of the backward recursion, only the probability density ωk(θk)=p(θk|ck=1,rkK) must be calculated. Accordingly, starting from equations (15), (17) and (19), the simplified calculation formula for the probability density ψk(θk) at the symbol time k is obtained in the forward recursion according to equation (20), and starting from equations (16) and (17), the simplified calculation formula for the probability density ωk−1(θk) at the preceding symbol time k−1 in the backward recursion is obtained according to equation (21).
For the extrinsic information, the relationship according to equation (22) applies, starting from equation (14) and taking into consideration property III and equation (19).
This simplified forward-backward recursion presented in equations (20), (21) and (22) including calculation of the extrinsic information contains the continuous probability-density functions ψk(θk)=p(θk|ck=1,r0k), ωk(θk)=p(θk|ck=1,rkK), p(rk|ck=1,θk), p(rk−1|ck−1=1,θk−1) and p(θk|θk−1), as well as integrations of these continuous probability-density functions, which make a direct conversion into an implementation capable of execution in a computer more difficult.
A simplification of this problem is achieved by approximating the probability-density functions ψk(θk)=p(θk|ck=1,r0k) and ωk(θk)=p(θk|ck=1,rkK) according to equation (23) and (24) as sums of respectively M Tikhonov distributions t(.) weighted with a real weighting factor qm,kforward and respectively qm,kbackward. The factor M corresponds to the valence of the symbol alphabet of the PSK modulation used.
The respective Tikhonov distribution is dependent upon a complex factor zkforward and respectively zkbackward and upon the phase value θk at the symbol time k and is obtained from equation (25). It contains the modified, first-order Bessel function I0.
The probability density ωk(θk) in the forward recursion is obtained starting from equation (20) taking into consideration a Tikhonov distribution for the probability density ωk(θk) according to equation (23) as a relationship according to equation (26). In this context, a Gaussian distribution according to equation (12) is used for the probability density p(rk|ck,θk) for the sampled value of the received signal rk at the symbol time k in the case of a known coded symbol ck and a known phase value θk of the transmission channel at the symbol time k in the forward recursion in equation (20), and in this context, all exponential function terms are ignored, which do not provide a dependence upon the phase value θk and which accordingly represent constant terms with regard to the probability density ψk(θk). For the probability density p(θk|θk−1) for the phase value θk of the transmission channel at the symbol time k in the case of a known phase value θk−1 of the transmission channel at the symbol time k−1, a Gaussian distribution of the mean value θk−1 and variance σΔ2 is assumed, because the characteristic of the individual phase increments Δk in equation (4) provides a Gaussian distribution with mean value zero and variance σΔ2. Additionally, all multiplicative factors which do not provide a dependence upon the phase value θk are ignored.
For the convolution of the Tikhonov distribution t(.) with the Gaussian distribution in equation (26), the approximation (27) can be used. With the introduction of this approximation, the mathematical relationship for the probability density ψk(θk) in the forward recursion according to equation (26) is converted into equation (29) with the introduction of the modified complex coefficient z′m,kforward of the Tikhonov distribution t(.) according to equation (28).
The Bessel function I0(.) used in the Tikhonov distribution t(.) can be approximated for large arguments through an exponential function. The mathematical relationship in equation (30) therefore follows from equation (25).
Through the use of the mathematical relationship in equation (30) and through substitution of the running indices i and m with the new running index n=i+m, the mathematical relationship for the probability density ψk(θk) in the forward recursion in equation (29) is converted into the mathematical relationship in equation (31).
A comparison of the mathematical relationship for the probability density ψk(θk) in equation (31) and in equation (23) gives a mathematical recursion formula for the calculation of the real weighting factor qm,kforward of the Tikhonov distribution t(.) according to equation (32) and for the calculation of the complex coefficient zkforward of the Tikhonov distribution t(.) according to equation (33). In this context, the running index n has been replaced by the running index m. For the determination of the mathematical relationship in equation (33), the approximation in equation (34) has been taken into consideration.
Before the implementation of the forward recursion for the determination of the complex coefficient zkforward of the Tikhonov distribution t(.), the real weighting factors qm,kforward of the Tikhonov distribution t(.) must be standardized according to equation (35) so that, in sum, they result in the value 1.
A value according to equation (36) is used as the starting value for the forward recursion for the determination of the complex coefficient zkforward of the Tikhonov distribution t(.), and a value according to equation (37) is used for the determination of the real weighting factor qm,kforward of the Tikhonov distribution t(.).
By analogy, a recursion formula according to equation (38) can be derived for the backward recursion of the complex coefficient zk−1backward of the Tikhonov distribution t(.), and a recursion formula according to equation (39) can be derived for the backward recursion of the real weighting factor qm,kbackward of the Tikhonov distribution t(.).
The standardization of the weighting factors qm,kbackward of the Tikhonov distribution t(.) determined in the backward recursion is obtained according to equation (40). The starting value zKbackward for the backward recursion of the complex coefficient zkbackward of the Tikhonov distribution t(.) is obtained according to equation (41), and the starting value qm,Kbackward of the real weighting factor qm,kbackward of the Tikhonov distribution t(.) is obtained according to equation (42).
To determine the extrinsic information according to equation (43), the mathematical relationships for the probability density ψk(θk) in the forward recursion according to equation (23) and for the probability density ωk(θk) in the backward recursion according to equation (24) are introduced into the equation (22) of the extrinsic information. In this context, it should be noted that the probability density p(θk|θk−1) for the phase value θk of the transmission channel at the symbol time k in the case of a known phase value θk−1 of the transmission channel at the symbol time k−1 satisfies a Gaussian distribution with the mean value θk−1 and the variance σΔ2.
Using the approximation for the convolution of a Tikhonov distribution with a Gaussian distribution according to approximation (27) and with the introduction of the modified complex coefficient z′m,kforward for the Tikhonov distribution according to equation (28), the equation (43) can be converted into an approximation, which is approximated by equation (44).
The two Tikhonov distribution functions in equation (44) are each presented according to their definition equation (25). While the first-order Bessel functions occurring in this context are placed before the integral because they provide no dependence upon the phase value θk, the exponential functions occurring in this context are combined to form a single exponential function, which is, once again, described according to the definition equation (25) with a Tikhonov distribution function and a first-order Bessel function. Accordingly, with the introduction of the intermediate value
a mathematical relationship according to equation (45) is obtained from the mathematical relationship for the extrinsic information in equation (44).
The integral of the phase value θk in equation (45) results in the value 1. The Bessel functions in the denominator of equation (45) provide no dependences upon the running indices m and l and therefore represent irrelevant multiplicative terms, which are no longer considered. The final mathematical relationship for the extrinsic information is therefore obtained according to equation (46).
In order to reduce the plurality of summations and multiplications in the recursion formulae of the equations (32), (33), (35), (38), (39) and (40) and in equation (46) for the calculation of the extrinsic information, and in order to limit the value range with regard to a signal-dynamic reduction, the following section will show how an algorithmic simplification can be achieved with reference to the example of the forward recursion. For this purpose, the weighting factor qm,kforward of the Tikhonov distribution t(.) determined in the forward recursion is logged according to equation (32). The log weighting factor ηm,kforward of the Tikhonov distribution t(.) provided in this manner is obtained according to equation (47).
In this context, the intermediate value γi,k according to equation (48) is introduced as the natural log of the a-priori probability of the symbol hypothesis i for the symbol ak to be transmitted at the symbol time k and the intermediate value {tilde over (η)}m,kforward according to equation (49) is introduced as the log, standardized, weighting factor ln({tilde over (q)}m,kforward) of the Tikhonov distribution t(.) determined in the forward recursion.
According to equation (49), the log, standardized weighting factor ln({tilde over (q)}m,kforward) of the Tikhonov distribution t(.) determined in the forward recursion can be regarded, starting from equation (35) for the standardization of the weighting factor qm,kforward of the Tikhonov distribution t(.) determined in the forward recursion, as the difference between the log-non-standardized weighting factor qm,kforward of the Tikhonov distribution t(.) determined in the forward recursion and the factor Ckforward constant with regard to the phase factor m according to equation (50).
The Jacobi-logarithm according to equation (51) is introduced to simplify the mathematical relationship in equation (47),
ln(ex
The Jacobi-logarithm can be regarded according to equation (52) as a modified maximal-value function max*{x1,x2}, which modifies a maximal-value function max{x1,x2} by a correction function g(x1,x2)=ln(1+e−|x
max*{x1,x2}=max{x1,x2}+g(x1,x2) (52)
Starting from equation (52), the modified maximal-value function max*{.} can be determined iteratively for a larger number of arguments from the modified maximal-value function max*{.} for a number of arguments x1, x2, . . . , xn−1 reduced by the last argument.
max*{x1,x2, . . . ,xn}=max*{max*{x1,x2, . . . ,xn−1},xn} (53)
However, the Jacobi-logarithm can also be determined approximately according to equation (54), without calculating the correction function g(.).
ln(ex
The introduction of the Jacobi-logarithm into the mathematical relationship for the log weighting factor ηm,kforward in the forward recursion according to equation (47) in combination with equation (49) achieves a simplification according to equation (55). In this context, the constant Ckforward can be ignored, because it provides no dependence upon the phase factor m.
In order to avoid the standardization of the weighting factors in the forward recursion according to equation (35) and in the backward recursion according to equation (40), each of which contains a calculation-intensive division and summation, a determination of the maximal value is implemented instead of a standardization. For this purpose, according to equation (56), the phase factor {tilde over (m)}k of the log weighting factor ηm,kforward of the Tikhonov distribution t(.) determined in the forward recursion is determined at the symbol time k which is maximal.
With the use of exclusively the maximal weighting factor max{q0,kforward, . . . , qM−1,kforward} of the Tikhonov distribution t(.) determined in the forward recursion, the recursion formula for determining the complex coefficient zkforward of the Tikhonov distribution t(.) determined in the forward recursion according to equation (33) is simplified into a simplified recursion formula according to equation (57). In equation (57), the identity illustrated in equation (58) is used to create a connection between the recursion formula for calculating the weighting factor and the complex coefficient of the Tikhonov distribution t(.).
To simplify the calculation formula for the extrinsic information, the new phase factor n=(l−m)mod M is introduced into equation (46). The calculation formula for the extrinsic information is thus obtained according to equation (59).
Starting from equation (59), a logging of the extrinsic information and an approximation of the first-order Bessel function through an exponential function leads to the mathematical relationship for the log, extrinsic information λi,k in equation (60).
With the introduction of the maximal log weighting factor fn,k determined in forward and backward recursion at the symbol time k and for the phase factor n according to equation (61) and of the intermediate value μn−i,k at the symbol time k and for the phase factor n−i according to equation (62), the log extrinsic information λi,k is obtained, starting from equation (60), according to equation (63).
Starting from equation (62), the introduction of the modified phase factor ν=n−i leads to the calculation formula for the intermediate value μν,k according to equation (64) and, starting from equation (63), to the calculation formula for the log extrinsic information λi,k according to equation (65).
In summary, the following calculation formula is obtained for the simplified detection algorithm of a differential M-PSK modulated signal:
For the forward recursion, the starting value {tilde over (η)}m,0forward of the log, standardized weight factor ηm,kforward of the Tikhonov distribution t(.) at the symbol time zero can be determined according to equation (66), the starting value z0forward of the complex coefficient zkforward of the Tikhonov distribution t(.) at the symbol time zero can be determined according to equation (67), and the starting value z′0forward of the modified complex coefficient z′kforward of the Tikhonov distribution t(.) at the symbol time zero can be determined according to equation (68).
The log weighting factor ηm,kforward determined in a forward recursion at the symbol time k is obtained according to equation (69) taking into consideration equations (70) and (71), which form the connection to the forward recursion of the complex coefficient of the Tikhonov distribution t(.).
According to equation (72), the complex coefficient zkforward of the Tikhonov distribution t(.) at the symbol time k determined in a forward recursion is obtained starting from the result of equation (71) as the intermediate value
in brie case of phase factor αk at the symbol time k, which corresponds, according to equation (73), to the phase factor m of the maximal weighting factor
of the Tikhonov distribution t(.) at the symbol time k determined in a forward recursion. The modified complex coefficient z′kforward of the Tikhonov distribution t(.) at the symbol time k determined in a forward recursion is obtained according to equation (74).
For the backward recursion, the starting value {tilde over (η)}m,kbackward of the log, standardized weighting factor {tilde over (η)}m,kbackward of the Tikhonov distribution t(.) at the symbol time K can be determined according to equation (75), the starting value zKbackward of the complex coefficient zkbackward of the Tikhonov distribution t(.) at the symbol time K can be determined according to equation (76), and the starting value z′Kbackward of the modified complex coefficient z′kbackward of the Tikhonov distribution t(.) at the symbol time K can be determined according to equation (77).
The log weighting factor ηm,k−1backward at the symbol time k−1 determined in a forward recursion is obtained according to equation (78) taking into consideration equations (79) and (80), which form the connection to the backward recursion of the complex coefficient of the Tikhonov distribution t(.).
According to equation (81) the complex coefficient zk−1backward of the Tikhonov distribution t(.) at the symbol time k−1 determined in a backward recursion is determined starting from the result of equation (80) as the intermediate value ρβ
of the Tikhonov distribution t(.) at the symbol time k−1 determined in a backward recursion. The modified complex coefficient z′k−1backward of the Tikhonov distribution t(.) at the symbol time k−1 determined in a backward recursion is obtained according to equation (83).
The extrinsic information can be calculated according to equations (61), (62) and (65).
In the following section, the method according to the invention for determining an extrinsic information is explained in detail on the basis of the flowchart in
In the first method step S10, the individual recursion variables are initialised. This takes place on the basis of equation (65) for the total of M log, standardized weighting factors {tilde over (η)}m,0forward of the Tikhonov distribution t(.) determined in a forward recursion at the symbol time zero, on the basis of equation (67) for the complex coefficient z0forward of the Tikhonov distribution t(.) determined in a forward recursion at the symbol time zero, on the basis of equation (68) for the modified complex coefficient z′kforward of the Tikhonov distribution t(.) determined in a forward recursion at the symbol time zero, on the basis of equation (75) for the total of M log, standardized weighting factors {tilde over (η)}m,Kbackward of the Tikhonov distribution t(.) at the symbol time K, on the basis of equation (76) for the complex coefficient zKbackward of the Tikhonov distribution t(.) determined in a backward recursion and on the basis of equation (77) for the modified complex coefficient z′Kbackward of the Tikhonov distribution t(.) determined in a backward recursion.
In the next method step S20, in a unit 1 for determining log weighting factors in a forward recursion, the total of M log weighting factors ηm,kforward of the Tikhonov distribution t(.) determined in a forward recursion are determined for the respective symbol time k on the basis of the recursion formula according to equation (69). For this purpose, the Jacobi-logarithm is calculated from the individual sums of the a-priori probability γi,k associated respectively with each symbol hypothesis i at the respective symbol time k and of log weighting factor n forward η(m−i) mod M,k−1forward the Tikhonov distribution t(.) at the preceding symbol time k−1. The modulus of the intermediate value ρm,kforward determined at the same symbol time k−1 in the unit 2 for determining complex coefficients in a forward recursion is added to the Jacobi-logarithm, which is composed, according to equation (71), of the modified, complex coefficient z′k−1forward of the Tikhonov distribution t(.) at the preceding symbol time k−1 determined in a forward recursion and the received symbol rk at the symbol time k, and which is additionally buffered for further processing in the following method step S30 in an intermediate buffer, which is not illustrated in
As the Jacobi-logarithm, the variant max1*{.} of the Jacobi-logarithm composed of the maximal-value function max{.} and the correction function g(.) can be used according to equation (52), or alternatively the approximation max{.} consisting exclusively of the maximal-value function max2*{.} can be used according to equation (53).
In the next method step S30, in a unit 2 for determining the phase factor in the case of the maximal log weighting factor in a forward recursion according to equation (73), that phase factor αk at the symbol time k is determined, which is associated with the maximal log weighting factor
of the Tikhonov distribution t(.) determined in a forward recursion at the symbol time k of all of the total of M log weighting factors ηm,kforward of the Tikhonov distribution t(.) at the symbol time k determined in a forward recursion.
According to equation (72), in the same method step S30, in a unit 3 for determining complex coefficients in a forward recursion, the complex coefficient zkforward of the Tikhonov distribution t(.) at the symbol time k determined in a forward recursion is determined from the intermediate value ρα
In the next method step S40, in a unit 4 for determining log weighting factors in a backward recursion, the total of M log weighting factors ηm,k−1backward of the Tikhonov distribution t(.) determined in a backward recursion at the respectively preceding symbol time k−1 is determined on the basis of the recursion formula according to equation (78). In this context, the Jacobi-logarithm is calculated from the individual sums of a-priori probabilities γi,k at the respective symbol time k respectively associated with each symbol hypothesis i and of log weighting factors ηm,kbackward of the Tikhonov distribution t(.) at the preceding symbol time k−1 determined in a backward recursion. The modulus of the intermediate value ρm,k−1backward determined at the same symbol time k−1 in the unit 5 for determining complex coefficients in a backward recursion is added to the Jacobi-logarithm, which is composed of the modified, complex coefficient z′kbackward of the Tikhonov distribution t(.) according to quotation (80) at the symbol time k determined in a backward recursion and the received symbol rk−1 at the preceding symbol time k−1 and which is additionally buffered for further processing in the following method step S50 in an intermediate buffer, which is not illustrated in
In the next method step S50, in a unit 6 for determining the phase factor in the case of the maximal log weighting factor in a backward recursion according to equation (82), that phase factor βk−1 at the preceding symbol time k−1 is determined, which corresponds to the phase factor m of the maximal weighting factor
of all of the total of M log weighting factors ηm,k−1 of the Tikhonov distribution t(.) at the preceding symbol time k−1 determined in a backward recursion.
In the next method step S60, in a unit 7 for determining an extrinsic information, the log extrinsic information λi,k associated with the symbol hypothesis i at the symbol time k according to equations (61), (62) and (63) on the basis of the total of M log weighting factors ηm,k−1backward of the Tikhonov distribution t(.) at the preceding symbol time k−1 determined in a forward recursion according to method step S20, the total of M log weighting factors ηm,kbackward of the Tikhonov distribution t(.) determined in a backward recursion according to method step S40 at the symbol time k of a modified complex coefficient z′k−1backward of the Tikhonov distribution t(.) at the preceding symbol time k−1 determined in a forward recursion according to method step S30 and of the modified complex coefficient z′kbackward of the Tikhonov distribution t(.) determined in a backward recursion according to method step S50 at the symbol time k are calculated. In this context, the Jacobi-logarithm is used in the variant max1*{.} comprising the maximal value function max{.} and the correction function g(.) according to equation (52) or in the variant max2*{.} comprising exclusively the maximal value function max{.} according to equation (53).
In the final optionally implemented method step S70, in a maximal value detector 8, the maximal a-posteriori probability
is determined as the maximal sum
of the extrinsic information λi,k and the a-priori probability
of all of the total of M a-posteriori probabilities
associated respectively with a symbol hypothesis i at the symbol time k. The symbol hypothesis i associated with this maximal a-posteriori probability
represents the estimated value âk for the symbol ak to be transmitted at the symbol time k.
The invention is not restricted to the individual embodiments and variants described. In particular, all combinations of all of the features presented and mentioned in the claims, in the description and in the figures of the drawings are also covered by the invention. Especially, all of the features of the dependent claims formulated in the independent method claims relate by analogy to the independent device claim.
Number | Date | Country | Kind |
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10 2011 006 565.2 | Mar 2011 | DE | national |
10 2011 078 565.5 | Jul 2011 | DE | national |
The present application is a national phase application of PCT Application No. PCT/EP2012/053723, filed on Mar. 5, 2012, and claims priority to German Application No. 10 2011 006 565.2, filed on Mar. 31, 2011, and German Application No. 10 2011 078 565.5, filed on Jul. 4, 2011, the entire contents of which are herein incorporated by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP12/53723 | 3/5/2012 | WO | 00 | 5/12/2014 |