This application claims the priority under 35 U.S.C. § 119 of European patent application no. 15185335.5, filed on Sep. 15, 2015, the contents of which are incorporated by reference herein.
The present disclosure relates to a detector and a method of detecting values of a signal. In particular, the disclosure relates to a differential detector for a receiver.
Amplitude shift keying (ASK) is a signaling method where the message is encoded in the amplitude of the transmitted waveform. A typical ASK receiver includes a receiving antenna followed by an analog front-end (AFE) which down-converts the wireless signal from the receiving antenna by extracting the signal envelope. The signal envelope is quantized into discrete values using an analog-to-digital converter (ADC) for further digital signal processing (DSP) since the received signal suffers from various non-idealities.
Examples of non-idealities include the following:
These signal distortions necessitate DSP at the receiver to reliably recover the transmitted message without incurring symbol errors.
Traditionally, transversal, lattice, or block adaptive equalizers have been used to compensate for ISI and time-varying signal gain. However, in burst communications and in constrained frame formats with few or no training symbols, the equalizers may not be adequately trained. Consequently, the use of an equalizer with non-converged filter weights will yield a large residual ISI. Blind equalizers are an attractive alternative but their convergence time is generally long (in the order of several thousand symbols), making them unsuitable for burst communications.
Phase jitter can be combated using fractionally-spaced equalization. Unfortunately, for the same reasons described above, a poorly converged equalizer is of little use in compensating phase jitter in burst communications.
In the literature, use of decision feedback equalizers and of low-pass filtered symbol decisions to restore the low-frequency components in the ADC's digitized signal output has been suggested to overcome baseline wander. However, these methods have increased computational complexity making them unsuitable for hardware implementation. Moreover, the equalizer based method would need increased filter length and training period, whereas difficult manual tuning of parameters is required in designing the low-pass filter used to restore the low-frequency components.
According to a first aspect of the present disclosure, there is provided a differential detector for a receiver, said detector comprising: an analog to digital converter for sampling samples from symbols of a signal; a differentiator configured to differentiate the samples with a transfer function to produce a differentiated series of samples for each symbol; and a decision device configured to determine the value of each symbol by comparing values of the differentiated series of samples with boundary condition values.
Comparing values of the differentiated series of samples with boundary condition values may mitigate issues relating to non-idealities such as 151, phase jitter or other signal distortions in received signals.
In embodiments, the analog to digital converter may sample each symbol with L samples per symbol, where L is greater than or equal to 2.
In other embodiments, the detector may assign a ternary value to a symbol of either: +1 to a symbol if a value of the differentiated series of samples for that symbol exceeds an upper boundary condition value; or −1 to a symbol if a value of the differentiated series of samples for that symbol exceeds a lower boundary condition value; or 0 to a symbol if neither the upper nor lower boundary condition values are exceeded by the differentiated series of samples. Additionally, the decision device may determine the value of a symbol based on the sum of the ternary value of a symbol and the value of its preceding symbol.
Additionally or alternatively, the boundary condition values may be adaptive and may be adapted for each symbol. The detector may also either: adapt the upper boundary condition value of a symbol if the ternary value of its preceding symbol is +1; or adapt the lower boundary condition value of a symbol if the ternary value of its preceding symbol is −1; or maintain the upper and lower boundary condition values of a symbol if the ternary value its preceding symbol is 0.
In embodiments, for each symbol either: a positive sequence may be assigned or maintained for a symbol where at least one sample of its differentiated series of samples exceeds an upper boundary condition value; or a negative sequence may be assigned or maintained for a symbol where at least one sample of its differentiated series of samples exceeds a lower boundary condition value; or a positive or negative sequence may be maintained for a symbol where no sample of its differentiated series of samples exceed the upper or lower boundary condition value. Additionally, the decision device may determine ternary values of each symbol within each positive or negative sequence of symbols. Furthermore, the symbol with the sample that exceeded the boundary condition value by the greatest amount for each sequence may be assigned a ternary value of +1 for a positive sequence or −1 for a negative sequence. Every remaining symbol in a sequence may be assigned a ternary value of 0.
In embodiments, the ternary values of the final sequence of symbols may be assigned a value of 0 if the sum of the ternary values of all the symbols differ from a predetermined sum of expected ternary values. For example, from a priori knowledge of the signal frame, an expected outcome of the sum of the ternary values can be determined. For example, if it is expected that the sum of all ternary symbols yields a 1, but the actual sum equals 0, then the final sequence of symbols may be assigned (i.e., reset) a value of 0. This knowledge can be determined by analysing the values of the signal at the start and end of the signal frame.
In embodiments, the decision device may determine the value of a symbol based on the integral of the ternary value of a symbol.
In other embodiments, the detector may further comprise a symbol synchroniser for retrieving a symbol timing for each symbol.
The transfer function may be h=[0a 1 0b −c].
According to a second aspect of the present disclosure, there is provided a method of detecting the value of symbols of a signal, said method comprising the steps of: sampling samples from symbols of a signal; differentiating the samples with a transfer function to produce a differentiated series of samples for each symbol; determining the value of each symbol by comparing values of the differentiated series of samples with boundary condition values.
It is an object to provide a robust low-complexity, multiplier-free, DSP algorithm to decode a received signal impaired by ISI, time-varying signal gain, phase jitter, and baseline wander, without utilizing any training sequence.
There may be provided a computer program, which when run on a computer, causes the computer to configure any apparatus, including a circuit, controller, sensor, filter, or device disclosed herein or perform any method disclosed herein. The computer program may be a software implementation, and the computer may be considered as any appropriate hardware, including a digital signal processor, a microcontroller, and an implementation in read only memory (ROM), erasable programmable read only memory (EPROM) or electronically erasable programmable read only memory (EEPROM), flash memory, or a chip as non-limiting examples. The software implementation may be an assembly program.
The computer program may be provided on a computer readable medium, which may be a physical computer readable medium, such as a disc or a memory device, or may be embodied as a transient signal. Such a transient signal may be a network download, including an internet download.
These and other aspects of the disclosure will be apparent from, and elucidated with reference to, the embodiments described hereinafter.
Embodiments will be described, by way of example only, with reference to the drawings, in which
It should be noted that the Figures are diagrammatic and not drawn to scale. Relative dimensions and proportions of parts of these Figures have been shown exaggerated or reduced in size, for the sake of clarity and convenience in the drawings. The same reference signs are generally used to refer to corresponding or similar feature in modified and different embodiments.
An example of a detector according to an example of the present disclosure is shown in
The ADC 110, differentiator 130, and decision device 140 will be explained in depth, whereas the generic symbol synchronizer block 120 will be briefly described, in the following.
ADC
Consider the transmission of a binary ASK signal, with a non-return-to-zero (NRZ) pulse shape given by s(t). Let the ADC's 110 sample output 115 at time k be u(k). Let q refer to the symbol index which is related to the original sample time k as
k=qL+i, i=0,1, . . . ,L−1 q=0,1,2, . . . (1)
where L is the number of samples per symbol. Here, L is greater than or equal to 2 samples per symbol. To aid the initialization of the decision device 140, let u(k)=δ for time k≤−1, where δ is the average of the binary ASK signal levels of ‘1’ and ‘0’.
Symbol Synchronizer
The symbol synchronizer 120 functions to retrieve the symbol timing 125 of the signal output 115 at the beginning of the communication period. For example, symbol synchronizer 120 could be implemented using early-late sampling, which adjusts the symbol time towards the local peak time of correlator output v(k)=s(k)*u(k), where * represents convolution.
Differentiator
A differentiator 130 with transfer function h=[0a 1 0b −c] is introduced, where 0<c≤1, 0i is a row vector of zeros of length i. Here, bϵ{0, 1, . . . , L−1} and aϵ{0, 1, . . . , L−b−1}.
Differentiating an ASK signal having baseline wander 220, mitigates the baseline wander effect by converting the signal into a ternary ASK signal 230 with levels ‘1’, ‘0’, and ‘−1’ as illustrated by example
An undesirable byproduct of the differentiator h used in
Symbol timing errors and dispersed symbol pulse due to ISI lead to symbol decision errors. A value of bϵ{0, 1, . . . , L−2}, compared to b=L−1, in the differentiator h is seen to create a narrower symbol pulse, and ISI tail. Hence, using bϵ{0, 1, . . . , L−2} more accurately defines the arrival of a symbol pulse and its time location with respect to the symbol observation windows. This improved accuracy enhances the symbol detection process in the decision device later. An example depicting the creation of narrower symbol pulse is shown in
Poor symbol timing due to phase jitter and ISI-degraded symbol synchronization, is further guarded against by assigning a non-zero value to a. A non-zero a, essentially controlling the signal delay with respect to symbol observation window, ensures the narrow differentiated symbol pulse lie centered within each symbol observation window. Therefore, it provides the highest probability of correct symbol pulse detection within the correct symbol observation window.
Initial oversampling by the ADC 110 at L≥2 is an important factor to realize the benefits offered by the differentiator h, namely, mitigating the effect of ISI and phase jitter.
Decision Device
Finally, a decision device 140 functions to reliably detect the received symbols 135 from the differentiator 130 even in the presence of ISI, time-varying gain, baseline wander, and phase jitter. Input samples 135 to the decision device 140 are denoted by y(k). The samples {y(k)} corresponding to symbol q are defined by the set
y(qL)=[y(qL+L−1) . . . y(qL)]. (2)
The decision device in
Symbol-by-Symbol Detector
Considering the output 135 of the differentiator 130 illustrated in
where βp and βn are the decision boundaries in a ternary signal constellation. In the decision metric of (3), a soft ternary decision of ‘1’ and ‘1’ is assigned when a local maximum and local minimum is detected, respectively, otherwise a soft ternary decision of ‘0’ is assigned by default due to the absence of a symbol pulse. For example, in symbol 1, shown at 310 (corresponding to the signal shown in
Firm binary decision m(q) 145 on the received symbol q is obtained by integrating the soft ternary decisions {circumflex over (m)}(q) as
where m(0)=0 and m(0)=1 if {circumflex over (m)}(0)=−1 and {circumflex over (m)}(0)=1, respectively.
To enhance the symbol-by-symbol detector's tolerance to time-varying gain and asymmetric waveform (i.e., ternary symbol ‘1’ and ‘-1’ with unequal magnitude), the decision boundaries βp and βn are adapted upon every detection of ‘1’ and ‘-1’ ternary symbols as
βp=2−θ
βn=2−θ
βp=βp and βn=βn, otherwise (5)
where θ1 and θ2 are positive real numbers. Ensuring θ1 and θ2 to be integers, removes multiplication operations from (5) since multiplication by factors of 2−i, where i is an integer, can be implemented as bitshift operations.
Use of independent decision boundaries βp and βn for detection of ternary symbol ‘1’ and ‘−1’ enables improved decoding of asymmetric waveforms. Moreover, continuous update of decision boundaries βp and βn based on the observed signal samples allow the detector to track time-varying gain of the signal.
However, the symbol-by-symbol detector requires difficult, time-consuming, optimization of initial βp, βn, θ1, and θ2 values by trial-and-error. Careful selection of initial βp, βn, θ1, and θ2 values is crucial to satisfy the competing demands of (i) sufficiently large decision boundaries to avoid detection of false local maxima or minima created by the differentiator block and to avoid detection of additive noise, and (ii) sufficiently small decision boundaries to avoid missing any true local maxima or minima representing true ternary symbols ‘1’ and ‘-1’.
Sequence Detector
To overcome the parameter optimization difficulties of the symbol-by-symbol detector, the decision device 140 may alternatively be realized as a sequence detector which operates on a set-and-forget mode with no tuning of parameters needed. By utilizing neighboring (i.e. before and after) symbols, the sequence detector is able to make better symbol decisions and thus tolerate greater ISI than the symbol-by-symbol detector. The sequence detector by virtue of its construction is capable of decoding signals impaired with large ISI and time-varying signal gain, which is explained in detail next.
In the differentiated ASK signal, occurrence of any two ‘1’ symbols is separated by the presence of one ‘−1’ symbol in between. In other words, ternary symbol sequences such as [ . . . 1 0 1 . . . ] and [ . . . 1 1 . . . ] do not arise. This principle applies likewise to the occurrence of any two ‘-1’ symbols in the differentiated ASK signal. Given this concept, the input symbols to the sequence detector are assigned to either a positive sequence P or a negative sequence N, according to the rule given in Table 1. For initialization, symbol q=−1 is assigned to a negative sequence and min (y(−L))=−γ. Here, γ represents a small constant positive value to avoid additive noise.
At the beginning of the input signal y(k), the sequence detector attempts to detect the presence of either a positive or a negative sequence. Assume a positive sequence P, comprising symbol indices q=pstart, . . . , pend, is detected. The symbol qp satisfying
and
max(y(qpL))≥γ (7)
within sequence P is assigned a soft ternary decision {circumflex over (m)}(qp)=1 while other symbols within sequence P are assigned soft ternary decisions of ‘0’. The symbol index qp which contains the maximum value, exceeding boundary γ, of sequence P is decided upon as ternary ‘1’ based on maximum likelihood principle where likelihood of y(qL) being a true ternary ‘1’ symbol increases with its value.
Next, the sequence detector proceeds to detect a negative sequence N, since positive and negative sequences alternate in a differentiated ASK signal. Let the symbol indices in the negative sequence be q=nstart, . . . , nend. The symbol qn satisfying
and
min(y(qnn)≤−γ (9)
within sequence N is assigned a soft ternary decision of {circumflex over (m)}(qn)=−1 while other symbols within sequence N are assigned soft decisions of ‘0’. Subsequent soft ternary decisions of the sequence detector are made by alternating between positive and negative sequences.
The following supplementary decision rule is adopted to mitigate false detection of additional ternary ‘1’ or ‘−1’ symbol toward the end of the signal, if the received signal is formatted in frames and the receiver has knowledge of the frame protocol. This supplementary rule is based on the running sum of soft ternary decisions {circumflex over (m)}, which should be bounded in [0,1] by virtue of the transmitted signal being a binary ASK signal. If ideally Σ{circumflex over (m)}(q)=0 but Σ{circumflex over (m)}(q)=a in the received frame, then the last ternary α symbol in the frame is reset to soft ternary ‘0’ symbol. Here, αϵ{1, −1}. If ideally Σ{circumflex over (m)}(q)=α but Σ{circumflex over (m)}(q)=0 in the received frame, then the last ternary −α symbol in the frame is reset to soft ternary ‘0’ symbol.
A firm binary decision m(q) on the received symbol q is obtained as described by (4).
Notably, the sequence detector avoids the need for any decision slice levels and simultaneously avoids detection of false local maxima or minima created previously by the differentiator h because true local maxima or minima will be of greater magnitude than false maxima or minima. Moreover, sequence detection enables reliable decoding of signals with time-varying gain since decisions are based on selecting symbols containing the maximum or minimum value within a positive or a negative sequence and not based on any externally-set hard decision boundaries. Furthermore, the sequence detector does not require any multiplier hardware in its operation.
As shown in
Initially, the sequence detector makes soft ternary decisions for each symbol 432 in
This sequence is determined by analyzing the signal 430 and identifying sequences 434a-e that correspond to groups of symbols with one or more sample either exceeding a boundary condition or where all samples fall within the boundary conditions. Analyzing the signal 430 yields: negative sequence 434a, positive sequence 434b, negative 434c, positive 434d and negative 434e. Each sequence 434a-e is then analyzed to determine the symbol with the highest value sample. This symbol is then designated with a ternary value corresponding to its sequence value (so symbol 0 is assigned −1 for sequence 434a, and symbols 3, 4, 7 and 8 are assigned +1, −1, +1 and −1 for sequences 434b-e). Every remaining symbol in a sequence is assigned a ternary value of 0. This corresponds to (10).
Since the initial symbol decision sequence yields Σl=09{circumflex over (m)}(l)=−1, the last ternary ‘−1’ symbol is reset to ternary ‘0’ symbol according to the supplementary rule described above. Hence, the final ternary decisions of the sequence detector are {circumflex over (m)}=[−1 0 0 1 −1 0 0 1 0 0]. Integrating {circumflex over (m)} firm binary decisions for the frame are obtained as
which is verified correct by comparing with
Complexity increase due to the proposed sequence detector block only involves several additional registers to store past input y(k) values, unlike the exponential increase of complexity with sequence length in maximum likelihood sequence estimation (MLSE). Moreover, MLSE requires a channel estimator in the presence of ISI and time-varying signal gain. A poor channel estimation in burst communication and signaling with little or no training sequence, effectively renders the MLSE worse off compared to the proposed sequence detector which is robust against large residual ISI and time-varying gain even without a channel estimator.
The combination of oversampled ADC 110, differentiator 130, and decision device 140 (i.e., symbol-by-symbol detector or sequence detector) blocks may be utilized in the receiver baseband DSP structure of the passive integrated circuit card (PICC) or contactless smartcard for Type-B ASK radio-frequency identification (RFID) systems at a carrier of 13.56 MHz, as defined by ISO 14443. In ASK NFC (near field communication), the frame format may lack explicit training sequence which makes the disclosure advantageous for application in the receiver of contactless smartcards. The individual character format with start bit, stop bit, and Σ{circumflex over (m)}(q)=0 in ASK NFC is known apriori to the receiver. Hence, the decision device implemented as a sequence detector may make character-by-character decisions while adopting the supplementary decision rule. The disclosure, having low-complexity, multiplier-free, real-time operation capability, endears itself to the receiver baseband DSP in contactless smartcard since contactless smartcards are passive devices favoring low-power algorithms.
From reading the present disclosure, other variations and modifications will be apparent to the skilled person. Such variations and modifications may involve equivalent and other features which are already known in the art of receivers and which may be used instead of, or in addition to, features already described herein.
Although the appended claims are directed to particular combinations of features, it should be understood that the scope of the disclosure of the present invention also includes any novel feature or any novel combination of features disclosed herein either explicitly or implicitly or any generalisation thereof, whether or not it relates to the same invention as presently claimed in any claim and whether or not it mitigates any or all of the same technical problems as does the present invention.
Features which are described in the context of separate embodiments may also be provided in combination in a single embodiment. Conversely, various features which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable subcombination. The applicant hereby gives notice that new claims may be formulated to such features and/or combinations of such features during the prosecution of the present application or of any further application derived therefrom.
For the sake of completeness it is also stated that the term “comprising” does not exclude other elements or steps, the term “a” or “an” does not exclude a plurality, a single processor or other unit may fulfil the functions of several means recited in the claims and reference signs in the claims shall not be construed as limiting the scope of the claims.
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