The disclosure relates generally to communication systems and more specifically to blind communication schemes that transmit over unknown wireless multipath channels.
The future generation of wireless networks faces a diversity of new challenges. Trends on the horizon—such as the emergence of the Internet of Things (IoT) and the tactile Internet—have radically changed thinking about how to scale wireless infrastructure. Among the main challenges new emerging technologies have to cope with is the support of a massive number (billions) of devices ranging from powerful snmartphones and tablet computers to small and low-cost sensor nodes. These devices come with diverse and even contradicting types of traffic including high speed cellular links, massive amounts of machine-to-machine (M2M) connections, and wireless links which carrying data in short-packets. Although intensively discussed in the research community, the most fundamental question of how we will communicate in the near future under such diverse requirements remains largely unresolved.
A key problem of supporting sporadic and short-message traffic types is how to acquire, communicate, and process channel information. Conventional channel estimation procedures typically require a substantial amount of resources and overhead. This overhead can dominate the intended information exchange when the message is short and the traffic sporadic. For example, once a node wakes up in a sporadic manner to deliver a message it has first to indicate its presence to the network. Secondly, training symbols (pilots) are typically used to provide sufficient information at the receiver for estimating link parameters such as the channel coefficients. Finally, after exchanging a certain amount of control information, the device transmits its desired information message on pre-assigned resources. In current systems these steps are usually performed sequentially in separate communication phases yielding a tremendous overhead once the information message is sufficiently short and the nodes wake up in an unpredictable way. Therefore, a redesign and rethinking of several well-established system concepts and dimensioning of communication layers will likely be necessary to support such traffic types in an efficient manner. Noncoherent and blind strategies, provide a potential way out of this dilemma. Classical approaches like blind equalization have been investigated in the engineering literature, but new noncoherent modulation ideas which explicitly account for the short-message and sporadic type of data will likely be required.
In many wireless communication scenarios the transmitted signals are affected by multipath propagation and the channel will therefore be frequency-selective if the channel delay spread exceeds the sampling period. Additionally, in mobile and time-varying scenarios one encounters also time-selective fast fading. In both cases channel parameters typically have a random flavor and potentially cause various kinds of interference. From a signal processing perspective it is, therefore, desirable to take care of possible signal distortions, at the receiver and potentially also at the transmitter.
A known approach to deal with multipath channels is to modulate data on multiple parallel waveforms, which are well-suited for the particular channel conditions. A simple approach that can be utilized for frequency-selective multipath channels is orthogonal frequency division multiplexing (OFDM). When the maximal channel delay spread is known, inter-symbol-interference (ISI) can be avoided by a suitable guard interval. Orthogonality of the subcarriers can be achieved by a cyclic prefix preventing inter-carrier-interference. On the other hand, from an information-theoretic perspective, random channel parameters are helpful from a diversity view point. Spreading data over subcarriers can exploit diversity in a frequency-selective fading channel. But to coherently demodulate the data symbols at the receiver, the channel impulse response (CIR) should be known at least at the receiver. To gain knowledge of the CIR, training data (pilots) are typically added to the information baseband samples, leading to a substantial overhead when the number of samples per signal is in the order of the channel taps. If the number of samples is even less than the number of channel taps, it, can be mathematically impossible to accurately estimate from any pilot data the channel (assuming full support). Hence, one is either forced to increase the signal length by adding more pilots or assume some side-information on the channel. Furthermore, the pilot density has to be adapted to the mobility and, in particular, OFDM is very sensitive to time-varying distortions due to Doppler shift and oscillator instabilities. Dense CIR updates are often required, which can result in complex transceiver designs.
Due to ubiquitous impairments between transmitter and receiver clocks a carrier frequency offset (CFO) is likely to be present after a down conversion to the baseband. Doppler shifts due to relative velocity can also cause additional frequency dispersion which can be approximated in first order by a CFO. This is a known weakness in many multi-carrier modulation schemes, such as OFDM, and various approaches have been developed to estimate or eliminate the CFO effect. A common approach for OFDM systems is to learn the CFO in a training phase or from blind estimation algorithms, such as MUSIC or ESPRIT. Furthermore, due to the unknown distance and asynchronous transmission, a timing offset (TO) of the received symbol typically has to be determined as well, which will otherwise destroy the orthogonality of the OFDM symbols. By “sandwiching” the data symbol between training symbols a timing and frequency offset can be estimated. By using antenna arrays at the receiver, antenna diversity of a single-input-multiple output (SIMO) system can be exploited to improve the performance.
OFDM is typically used in long packets (frames), consisting of many successive symbols resulting in long signal lengths. In a sporadic communication, only one packet is transmitted and the next packet may follow at an unknown time later. In a random access channel, a different user may transmit the next packet from a different location. Such a packet experiences an independent channel realization. Hence, the receiver can barely use any channel information learned from the past. To reduce overhead and power consumption, again low-latency and short-packet durations are favorable.
A communication system that supports sporadic packet communication at ultra low latency can be useful in a number of applications including (but, not limited to) critical control applications, like commands in wireless for high performance (HP), ad hoc signaling protocols, secret key authentication, or initiation, synchronization and channel probing packets to prepare for longer or future transmission phases. At the same time, ultra reliability is required for such low latency communications (URLLC), especially if dealing with industrial wireless scenarios where the packets contain critical control data. The IEEE 802.11 standard for WirelessHP specifies a target packet error probability of 10−9 at scheduling units (SU) below 1 μs for power system automation and power electronic control. Here, the SU is the actual transmission time between transmitter and receiver. Furthermore, the next generation of mobile wireless networks aims for large bandwidths with carrier frequencies beyond 30 GHz, in the so called mmWave band, such that the sampling period is in the order of nano seconds. Hence, even at moderate mobility, the wireless channel remains approximately time-invariant only for a short duration, encouraging shorter symbol lengths. On the other hand, wideband channels resolve many multipaths due to the large bandwidth, which makes equalizing in the time-domain very challenging and is commonly simplified by using OFDM instead. But this can require long signal lengths, due to additional pilots needed to learn the channel. This may not be feasible if the transmission time or scheduling unit requirement is too short. Also, the maximal CIR length needs to be known at the transmitter and if underestimated might lead to a serious performance loss. Considering indoor channels at 60 GHz, a delay spread of up to 30 ns can still be present. Considering a bandwidth of 1 GHz results in a CIR length of 30 and a signal length of 100-1000 to meet the SU requirement. Hence, exploiting multiple OFDM symbols becomes more and more challenging if the receive duration approaches the order of the channel delay spread. Therefore, one-shot symbol transmissions can become necessary to push the latency on the physical-layer to its physical limits.
Another issue in transmitting at high frequencies can be attenuation, which can be overcome by exploiting beam-forming with massive antenna arrays. For massive or mobile users, this again increases the complexity and energy consumption for estimating and tracking the huge amount of channel parameters. Furthermore, a bottleneck in mmWave MIMO systems can be the blockage of line-of-sight connections which require wider or multiple beams, resulting in a significant reduction of the receive power.
Systems and methods in accordance with many embodiments of the invention utilize timing-offset (TO) and carrier frequency offset (CFO) estimation in a BMOCZ scheme to communicate over unknown multipath channels including (but not limited to) wideband frequency-selective fading channels. In several embodiments, the CFO robustness is realized by a cyclically permutable code (CPC), which can enable a receiver to identify the CFO. In a number of embodiments, an oversampled DiZeT decoder is utilized within the receiver that is capable of estimating the CFO. In certain embodiments, CPC codes are utilized that are constructed with cyclic BCH codes, which can provide the capability to correct additional bit errors and can enhance the performance of the BMOCZ scheme for moderate SNRs.
Due to the low-latency of BMOCZ the CFO and TO estimation can be performed from as few as one single BMOCZ symbol. This blind scheme can be ideal for control-channel applications, where a limited amount of critical and control data is exchanged while at the same time, channel and impairments information needs to be communicated and estimated. Communication systems that employ BMOCZ coded with a CPC in accordance with many embodiments of the invention can enable low-latency and ultra-reliable short-packet communications over unknown wideband channels.
One embodiment of the communication system includes a transmitter having: an encoder configured to receive a plurality of information bits and output a plurality of encoded bits in accordance with a cycling register code (CRC); a modulator configured to modulate the plurality of encoded bits to obtain a discrete-time baseband signal, where the plurality of encoded bits are encoded in the zeros of the z-transform of the discrete-time baseband signal: and a signal generator configured to generate a continuous-time transmitted signal based upon the discrete-time baseband signal. In addition, the communication system includes a receiver, having: a demodulator configured to down convert and sample a received continuous-time signal at a given sampling rate to obtain a received discrete-time baseband signal, where the received discrete-time baseband signal includes at least one of a timing offset (TO) and a carrier frequency offset (CFO); and a decoder configured to decode a plurality of bits of information from the received discrete-time baseband signal. Furthermore, the decoder decodes the plurality of bits of information by: estimating a TO for the received discrete-time baseband signal to identify a received symbol; determining a plurality of zeros of a z-transform of the received symbol; identifying zeros from the plurality of zeros that encode a plurality of received bits; and decoding a plurality of information bits based upon the plurality of received bits using the CRC.
In a further embodiment, the receiver receives the continuous-time transmitted signal over a multipath channel.
In another embodiment, the modulator is configured to modulate the plurality of encoded bits so that the z-transform of the discrete-time baseband signal comprises a zero for each of a plurality of encoded bits.
In a still further embodiment, the modulator is configured to modulate the plurality of encoded bits so that each zero in the z-transform of the discrete-time baseband signal is limited to being one of a set of conjugate-reciprocal pairs of zeros.
In still another embodiment, each conjugate reciprocal pair of zeros in the set of conjugate-reciprocal pairs of zeros comprises: an outer zero having a first radius that is greater than one; and an inner zero having a radius that is the reciprocal of the first radius. In addition, the inner and outer zero have phases that are the same phase, the radii of the outer zeros in each pair of zeros in the set of conjugate-reciprocal pairs of zeros are the same, and the phases of the outer zeros in each pair of zeros in the set, of conjugate-reciprocal pairs of zeros are evenly spaced over one complete revolution.
In a yet further embodiment, the cycling register code is a cyclically permutable code (CPC).
In yet another embodiment, the CPC is extracted from a Bose Chaudhuri Hocquenghem (BCH) code.
In a further additional embodiment, the CPC is extracted form a primitive BCH code.
In another additional embodiment, the CPC has a code length that is a Mersenne prime.
In a further embodiment again, the CPC has a code length selected from the group consisting of 3, 7, 31, and 127.
In another embodiment again, the CRC is generated by an inner code and an outer code which are combined in a non-linear fashion.
In a still yet further embodiment, the outer code is a cycling register code having a lower code rate than the inner code.
In still yet another embodiment, the outer code is a cyclically permutable code (CPC).
In a still further additional embodiment, the CRC is an affine CPC (ACPC) code.
In still another additional embodiment, the ACPC is characterized by being attainable using a cyclic inner code having codewords of an inner codeword length, which is affine translated by a given binary word of the inner codeword length, and then further encoded by a cyclic outer code.
In a still further embodiment again, the decoder is configured to estimate the timing offset by measuring energy over an expected symbol length with a sliding window in the sampled signal.
In still another embodiment again, the decoder is configured to measure energy over an expected symbol length by convolving samples with a universal Huffman sequence of the expected symbol length comprising two impulses at the beginning and the end of the expected symbol length.
In a yet further additional embodiment, the decoder is configured to estimate the TO by identifying a set of three energy peaks that yield a maximum energy sum over an expected symbol length.
In yet another additional embodiment, the demodulator is configured to oversample the received continuous-time signal, and the decoder is configured to identify zeros from the plurality of zeros that encode a plurality of received bits by identifying a fractional rotation resulting from the carrier frequency offset.
In a yet, further embodiment again, the decoder is configured to determine a most likely set of zeros for the z-transform of the discrete-time baseband signal used to generate the transmitted signal based upon the received symbol.
In yet another embodiment again, the decoder is configured to determine the plurality of received bits by performing a weighted comparison of samples of the z-transform of the received symbol with each zero in a set of zeros.
In a further additional embodiment again, each zero in the z-transform of the discrete-time baseband signal used to generate the transmitted signal is limited to being one of a set of conjugate-reciprocal pairs of zeros.
In another additional embodiment again, the receiver comprises a plurality of receive antennas and the decoder determines the plurality of information bits by combining values derived from the samples of a plurality of continuous-time signals received by the plurality of receive antennas to perform decoding.
A transmitter in accordance with one embodiment of the invention includes: an encoder configured to receive a plurality of information bits and output, a plurality of encoded bits in accordance with a cycling register code (CRC); a modulator configured to modulate the plurality of encoded bits to obtain a discrete-time baseband signal, where the plurality of encoded bits are encoded in the zeros of the z-transform of the discrete-time baseband signal; and a signal generator configured to generate a continuous-time transmitted signal based upon the discrete-time baseband signal.
In a further embodiment, the continuous-time transmitted signal comprises a carrier frequency modulated based upon the discrete-time baseband signal.
A receiver in accordance with one embodiment of the invention includes a demodulator configured to down convert and sample a received continuous-time signal to obtain a received discrete-time baseband signal and over sample the received discrete-time signal by zero padding, where the received discrete-time baseband signal includes at least one of a timing offset. (TO) and a carrier frequency offset. (CFO); and a decoder configured to decode a plurality of bits of information from the received discrete-time baseband signal by: estimating a TO for the received discrete-time baseband signal to identify a received symbol: determining a plurality of zeros of a z-transform of the received symbol; identifying zeros from the plurality of zeros that encode a plurality of received bits by identifying and correcting a fractional rotation in the plurality of zeros resulting from the CFO; and decoding a plurality of information bits based upon the plurality of received bits using a cycling register code (CRC).
It should be noted that the patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
Turning now to the drawings, communication systems and methods in accordance with various embodiments of the invention utilize a blind (noncoherent) communication scheme, called modulation on conjugate-reciprocal zeros (MOCZ), which can reliably transmit sporadic short-packets of fixed size over channels including (but not limited to) unknown wireless multipath channels. In many embodiments, communication systems utilize MOCZ schemes to transmit reliable and robust data with as few as one symbol in the presence of timing and/or frequency offsets. As is discussed further below, a carrier frequency offset (CFO) can result in an unknown rotation of all zeros of a received signal's z-transform. Therefore, in several embodiments, a binary MOCZ scheme (BMOCZ) is utilized in which the modulated binary data is encoded using a cyclically permutable code (CPC), which can cause the BMOCZ symbol to be invariant with respect to any cyclic shift resulting from a CFO. In a number of embodiments, the communication systems can utilize techniques similar to those described herein to achieve high spectral efficiency and/or low-latency.
In several embodiments, a transmitter modulates the information of a packet on the zeros of a transmitted discrete-time baseband signal's z-transform. The discrete-time baseband signal can be called a MOCZ symbol, which is a finite length sequence of complex-valued coefficients. These coefficients can then modulate a continuous-time pulse shape at a sample period of τ=1/W, where W is the bandwidth, to generate a continuous-time baseband waveform. Since the MOCZ symbols (sequences) are neither orthogonal in the time nor frequency domain, the MOCZ design can be seen as a non-orthogonal multiplexing scheme. After up-converting to the desired carrier frequency by the transmitter, the transmitted passband signal can propagate in space such that, due to reflections, diffractions, and/or scattering, different delays of the attenuated signal can interfere at the receiver. Hence, multipath propagation can cause a time-dispersion which can result in a frequency-selective fading channel. Furthermore, a CFO is likely to be present after a down conversion to baseband at the receiver.
Unlike OFDM, which is typically used in long frames, MOCZ can be utilized with shorter transmissions. In a bursty signaling scheme, timing and carrier frequency offsets may need to be addressed from only one received symbol or a small number of received symbols. In MOCZ schemes in accordance with a number of embodiments of the invention, communication is scheduled and timed on a MAC layer by a certain bus, running with a known bus clock-rate. Therefore, timing-offsets of the symbols can be assumed as fractions of the bus clock-rate. Accordingly, MOCZ receivers in accordance with many embodiments of the invention can be designed to be robust to these impairments.
In a communication system that employs MOCZ, a CFO is likely to result in an unknown common rotation of all received zeros. Since the angular zero spacing in a BMOCZ symbol of length K+1 is given by a base angle of 2π/K, a fractional rotation can be easily obtained at the receiver by an oversampling during the post-processing to identify the most likely transmitted zeros (zero-pattern).
Rotations, which are integer multiples of the base angle, can correspond to cyclic shifts of the binary message word. By using a CPC for the binary message, which can be extracted from cyclic codes, such as (but not limited to) Bose Chaudhuri Hocquenghen (BCH) code, a BMOCZ symbol can become invariant against cyclic shifts and hence against a CFO present with a communication system. In several embodiments, use of a CPC to encode a binary message can enable the operation of a communication system in a manner that does not rely upon symbol transmissions for estimation of a CFO, which can reduce overhead, latency, and complexity. In a number of embodiments, the communication system is able to provide a CFO estimation as part of the decoding process of a single BMOCZ symbol. In a number of embodiments, the receiver is able to estimate the cyclic shift that has been introduced by the CFO based upon the mapping of the zeros of the z-transform of the received symbol to bits and the CPC used to encode the transmitted message. Furthermore, the error correction capabilities of the CPC can also improve the BER and moreover the block error-rale (BLER) performance of the communication system tremendously.
By measuring the energy of the expected symbol length with a sliding window in the received signal, a receiver in accordance with various embodiments of the invention can identify arbitrary TOs. The robustness of the TO estimation can be demonstrated analytically, which reveals another strong property of communication systems that employ MOCZ schemes. Once the TO is determined, the symbol can be decoded and the CPC utilized to correct for any CFO.
In many embodiments, communication systems employ multiple receive antennas and achieve robustness to CFO and TO using a CPC for error correction. By simulating BER over the received SNR for various average power delay profiles, with constant and exponential decay as well as random sparsity constraints, performance of communication systems in accordance with various embodiments of the invention in different indoor and outdoor scenarios can be demonstrated.
Communication systems, transmitters, and receivers that can be utilized to transmit data encoded using a CPC by MOCZ in accordance with various embodiments of the invention are discussed further below.
In the discussion that follows, small letters are used for complex numbers in . Capital Latin letters denote natural numbers and refer to fixed dimensions where small letters are used as indices. Boldface small letters denote row vectors and capitalized letters refer to matrices. Upright capital letters denote complex-valued polynomials in [z]. The first N natural numbers in are denoted as [N]:={0, 1, . . . , N−1}. For K∈, K+[N]={K, K+1, . . . K+N−1} is denoted by the K-shift of the set [N]. The Kronecker-delta symbol is given by δnm and is 1 if n=m and 0 otherwise. For a complex number x=a+jb, given by its real part Re(x)=a∈ and imaginary part Im(x)=b∈ with imaginary unit j=√{square root over (−1)}, its complex-conjugation is given by
Systems and methods in accordance with many embodiments of the invention involve transmission of data of an unknown multipath channel. Multipath propagation of transmitted data is conceptually illustrated in
A transmitter and receiver that utilize a binary MOCZ scheme over an unknown multipath channel implemented in accordance with an embodiment of the invention are conceptually illustrated in
The binary message sequence mk∈{0, 1} can be chunked at the transmitter in blocks of length K. As is discussed further below, these blocks can then be encoded using a code that is robust to cyclic permutations. In several embodiments, the encoding can involve multiple codes. In certain embodiments, a combination of an inner code an outer code is utilized, where the inner code is a cyclic code which is affine translated and an outer code which is a cyclic code that provides error correction capabilities and robustness against cyclic shifts. As can readily be appreciated the specific code and/or combination of codes that are utilizes within a transmitter are largely dependent upon the requirements of specific applications in accordance with various embodiments of the invention.
For BMOCZ, the modulator f encodes the block m to a normalized complex-valued symbol (sequence) x=(x0, . . . , xK+1)T∈K+1+1 by using the zero-codebook of cardinality 2K. In many embodiments, when the block size K is small, the discrete-time BMOCZ symbols can be pre-generated using the methods described below for creating a codebook, and is selected using a lookup mechanism such as (but not limited to) a lookup table. The BMOCZ symbol x is typically modulated onto a carrier frequency fc with a pulse generator running at a sampling clock T=1/W to transmit a real-valued passband signal of bandwidth W to the receiver over an unknown time-invariant channel with a maximum delay spread of Td=(L−1)T which resolves L equally spaced multi-paths (delays). After a down-converting and sampling to the discrete-time baseband, the receiver observes the channel output y under an unknown additive noise vector w. As noted above, the down conversion can also introduce a CFO and/or a TO. The demodulator/decoder 206 can obtain from the received signal an estimated block codeword {circumflex over (m)} by the knowledge of the zero-codebook . As is discussed further below, use of a CPC in the encoding of the transmitted data enables the receiver to decode the transmitted data despite the presence of a CFO and/or a TO.
Although a specific binary MOCZ scheme is described above with reference to
Communication systems and methods in accordance with many embodiments of the system utilize a blind and asynchronous transmission of a short single MOCZ symbol at a designated bandwidth W. In this “one-shot” communication, it can be assumed that no synchronization and no packet scheduling occurs between the transmitter and receiver. Such extreme sporadic, asynchronous, and ultra short-packet transmissions are often employed in applications that include (but are not limited to): critical control applications, exchange of channel state information (CSI), signaling protocols, secret keys, authentication, commands in wireless industry applications, or initiation, and synchronization and channel probing packets to prepare for longer or future transmission phases.
By choosing the carrier frequency, transmit sequence length, and bandwidth accordingly, a receive duration in the order of the channel delay spread can be obtained, which can reduce latency at the receiver (potentially to the lowest latency possible). Since the next generation of mobile wireless networks aims for large bandwidths with carrier frequencies beyond 10 Ghz, in the so called mm Wave band, the transmitted signal duration of a signal transmitted in accordance with an embodiment of the invention can be in the order of nano seconds. Hence, even at moderate mobility, the wireless channel in an indoor or outdoor scenario can be considered as approximately time-invariant over such a short time duration. On the other hand, wideband channels can be highly frequency selective, which can be due to the superposition of different delayed versions (echoes) of the transmitted signal at the receiver. This can make performing equalization in the time-domain very challenging and is commonly simplified by using an OFDM scheme. But conventional OFDM typically requires an additional cyclic prefix to convert the frequency-selective channel to parallel scalar channels and, in coherent mode, it often requires additional pilots (training) to learn the channel coefficients. As can readily be appreciated, this can increase latency for short messages dramatically.
For a communication in the mmWave band, massive antenna arrays can be exploited to overcome attenuation. Use of multiple receive antennas can increase complexity and energy consumption in estimating channel parameters and can become a bottleneck in mmWave MIMO systems, especially for mobile scenarios. However, in a sporadic communication one or a small number of symbols are transmitted and additional symbols may follow at an unknown later time. In a random access channel (RACH), a different user may transmit the next symbol from a different location, which will therefore experience an independent channel realization. Hence, the receiver can barely use any channel information learned from past communications. OFDM systems typically approach this by transmitting many successive OFDM symbols as a long frame, to estimate the channel impairments, which can cause considerable overhead and latency if only a few data-bits need to be communicated. Furthermore, to achieve orthogonal subcarriers in OFDM, the cyclic prefix typically has to be at least as long as the channel impulse response (CIR) length, resulting in signal lengths at least twice the CIR length during which the channel also needs to be static. Using OFDM signal lengths much longer than the coherence time might not be feasible for fast time-varying block-fading channels. Furthermore, the maximal CIR length typically needs to be known at the transmitter and if underestimated can lead to a serious performance loss. This is in high contrast to communication systems in accordance with various embodiments of the invention that employ a MOCZ scheme, where the signal length can be chosen for a single MOCZ symbol independently from the CIR length. As is discussed further below, communication systems in accordance with many embodiments of the invention encode transmitted data using CPCs to address the ubiquitous impairments of MOCZ schemes under such ad-hoc communication assumptions for communications involving signal lengths in the order of the CIR length.
After up-converting the MOCZ symbol, which is a discrete-time complex-valued baseband signal x=(x0, x1, . . . , xK)∈K+1 of two-sided bandwidth W, to the desired carrier frequency fc, the transmitted passband signal will propagate in space. Regardless of directional or omnidirectional antennas, the signal can be reflected and diffracted at point-scatters, which can result in different delays of the attenuated signal and interfere at the receiver if the maximal delay spread Td of the channel is larger than the sample period T=1/W. Hence, the multipath propagation causes time dispersion resulting in a frequency-selective fading channel. Due to ubiquitous impairments between transmitter and receiver clocks an unknown frequency offset Δf will be present after the down-conversion to the received continuous-time baseband signal
{tilde over (r)}(t)=r(t))ej2πtΔf. (1)
A phase shift ϕ0 can also be present after down-conversion, which can yield a received continuous-time baseband signal
{tilde over (r)}(t)=r(t)ej2πtΔf+jϕ
By sampling {tilde over (r)}n={tilde over (r)}(nT) at the sample period T, the received discrete-time baseband signal can be represented by a tapped delay line (TDL) model. Here the channel action is given as the convolution of the MOCZ symbol x with a finite impulse response {}, where the lth complex-valued channel tap describes the lth averaged path over the bin [T, (+1)T), which can be modelled by a circularly symmetric Gaussian random variable as
The average power delay profile (PDP) of the channel can be sparse and exponentially decaying, where ∈{0, 1} defines the sparsity pattern of S=|supp(h)|=∥s∥1 non-zero coefficients. To obtain equal average transmit and average receive power the overall channel gain can be eliminated from the analysis by normalizing the CIR realization h=(h0, . . . , hL-1) by its average energy Σl=0L-1slpl (for a given sparsity pattern), such that [∥h∥2]=1. The convolution output can then be additively distorted by Gaussian noise wn∈(0, N0) of zero mean and variance (average power density) N0 for n∈ as
Here ϕ=2πΔf/W mod 2π∈[0, 2π) denotes the carrier frequency offset (CFO) and τ0∈the timing offset (TO), which marks the delay of the first symbol coefficient x0 via the first channel path h0. The symbol {tilde over (x)}=xMϕ∈[+K+1 in (4) has phase-shifted coefficients {tilde over (x)}k=ejkϕxk as well as the channel {tilde over (h)}l=ej(l+r
Instead of modulating the information of a message m=(m1, . . . , mK)∈[M]K on time or frequency coefficients, communication systems and methods in accordance with many embodiments of the invention can employ a M-ary MOCZ. A MOCZ signal's z-transform is a polynomial of degree K that is determined by exactly K complex-valued zeros αk(m
In several embodiments, the MOCZ encoder maps each message m of length K to the zero-pattern (zero-constellation) α(m)=(α1(m
∀q=2, . . . ,K:xq=(0,xq-1)−(αq(m
the normalized MOCZ symbol (constellation) after the last iteration step x=xK/∥xK∥∈K+1. Since the convolution with the CIR in (4) for the noise-free case (no CFO, no TO) is given as a polynomial product Y(z)=X(z)H(z), the transmitted zeros will not be affected by any CIR realization. Moreover, the added random channel zeros will not match any zero in with probability one, such that the transmitted zero-pattern can be blind (noncoherent) K identified at the receiver. To obtain noise robustness, communication systems in accordance with many embodiments of the invention utilize a Binary MOCZ (BMOCZ) constellation, where each symbol defines the coefficients of a polynomial of degree K given by the zeros (roots)
which are uniformly placed on a circle of radius R or R−1, selected by the message bits mk, see
a=a(K,η)=x*
for some R>1. The absolute value of (7) forms a trident with one main peak at the center, given by the energy ∥x∥22=1, and two equal side-peaks of η∈[0, ½), see
R
uni
=R(K)=√{square root over (1+sin(π/K))}>1, K≥2. (8)
Hence, the BMOCZ constellation set == with η*=η(R(K), K) is only determined by the number K. From the received N=L+K noisy signal samples (no CFO and no TO)
the BMOCZ decoder can perform Direct Zero-Testing (DiZeT) for each reciprocal zero pair on the received polynomial magnitude |Y(z)|=|Σn=0N-1ynzn| and can decide for the most likely one
where the inside zero samples are weighted accordingly.
Therefore, a global phase in Y(z) will have no effect on the decoder. But the CFO ϕ modulates the BMOCZ symbol in (4) and causes a rotation of its zeros by −ϕ in (5), which complicates the hypothesis test of the DiZeT decoder. Hence, communication systems in accordance with many embodiments of the invention estimate 0 and/or use an outer code for BMOCZ to be invariant against an arbitrary rotation of the entire zero-set . In many embodiments, before decoding can be performed, the TO of the symbol which yields to the convolution (9) is identified. Due to the symmetry of the zero-pattern and the energy concentration of the Huffman sequences, the BMOCZ design can address TO and CFO robustness and estimation, as is discussed further below.
In an asynchronous communication, the receiver typically does not know when a packet from a transmitter (user) will arrive. Hence, in communication systems in accordance with many embodiments of the invention the receiver initially must detect a transmitted packet, which is already one bit of information. It can be assumed that the receiver detects the transmitted packet correctly and that in an observation window of Nobs=Nnoise+K+L received samples, one single MOCZ packet of length K with maximal channel length of L is captured. By assuming a maximal length L and a known or a maximal K at the receiver, the observation window can be chosen, for example, as Nobs=2N. From the noise floor knowledge at the receiver, a simple energy detector with a hard threshold over the observation window can be used for a packet detection. An unknown TO τ0∈[Nnoise] and CFO ϕ∈[0, 2π) can also be present in the observation window
{tilde over (r)}
n
=e
jnϕ(x+h)n-τ
The challenge here is to identify τ0 and the efficient channel length which contains most of the energy of the instantaneous CIR realization h. In conventional communication systems, the estimation of this Time-of-Arrival (TOA) parameter can be performed by observing the same channel under many symbol transmissions, to obtain a sufficient statistic of the channel PDP. As noted above, where only one or a small number of observations are available, obtaining a good estimation can be very challenging.
The efficient (instantaneous) channel length Lef, defined by an energy concentration window, is likely to be much less than the maximal channel length L, due to blockage and attenuation by the environment, which might also cause a sparse, clustered, and exponential decaying power delay profile. For the MOCZ scheme, it can be beneficial to correctly identify in the window (11) the first received sample h0x0 from the transmitted symbol x, or at least to not miss it, since it will carry most of the energy if h0 is the line of sight (LOS) path. For the optimal radius in BMOCZ, x0 typically carries on average ¼ to ⅕ of the BMOCZ symbol energy, see also
Given an assumption of no CSI at the receiver, the channel characteristic, i.e., the instantaneous power delay profile, is determined entirely from the received MOCZ symbol. In a number of embodiments that utilize a BMOCZ scheme, the radar properties of the Huffman sequences can be exploited to obtain estimates of the timing offset and the effective channel delay in moderate and high SNR.
Huffman sequences have an impulsive autocorrelation (7), originally designed for radar applications, and are therefore very suitable to measure the channel impulse response. If the received signal r in (4) has no CFO and the transmitted sequence x is known at the receiver, correlation can be performed with x (matched-filter) and decision made based upon sample maximal energy
The above approach can be referred to as the HufED (Huffmnan Energy Detector), since the filtering with the conjugate-reciprocal sequence will detect in an ideal AGWN channel the noise distorted Huffman energy. When the transmitted Huffman sequence is unknown at the receiver, the received signal cannot be correlated with the correct Huffman sequence to retrieve the CIR. Instead, an approximative universal Huffman sequence can be used, which is just the first and last peak of a typical Huffman sequence, expressed by the impulses (δ0)k=δ0k and (δK)n=δKk for k∈[K+1] as
ψ=δ0+ejψδK∈K+1 (13)
which an be referred to as the K-Huffman bracket of phase ψ. Since the first and last coefficients are
x
0=√{square root over (R2∥m∥
typical Huffman sequences, i.e., having same amount of ones and zeros, will have
|x0|2=|xK|2=η. (15)
By convolving the modulated Huffman sequence {tilde over (x)} with the Huffman bracket ψ the locational properties of the Huffman autocorrelation (trident) are maintained
where x̊=x0δ0+xKδK denotes the exterior signature and {dot over (x)}=(0, 1, . . . , xK−1,0) the interior signature of the Huffman sequence x, see
|ă0|2=|x0|2, |ăK|2=|x0|2+|xK|2−2|x0xK|cos(Kϕ−ψ), |ă2K|2=|xK|2, (17)
where the side-peaks have energy
E
sides
=|x
0|2+|xK|2=(R2∥m∥
Since ϵ=2∥m∥1−K∈[−K, K] we have 2≤Rϵ+R−ϵ≤RK+R−K and 2η≤Esides≤1, where the lower bounds are achieved for typical sequences with ϵ=0 (having the same amount of ones and zeros) and the upper bounds for ϵ=±K (all ones or all zeros). If η=½ then the two coefficients (the exterior signature x̊) will carry all the energy of the Huffman sequence. But then also R=1 and the only Huffman sequences (real valued first and last coefficient) are given by x0=±1/√{square root over (2)}, xk=±1/√{square root over (2)} and xk=0 for k else, which are the coefficients of polynomials with K uniform zeros on the unit circle. For R given by (8) the autocorrelation side-lobe η is exponentially decaying in K but is bounded to η≥⅕ for K=1, 2, . . . , 512. Hence, Esides≥0.4, such that almost half of the Huffman sequence energy is always carried in the two peaks.
If the CFO were known, ψ=Kϕ−π could be set to obtain the center peak in (17)
E
center
=|x
0|2+|xK|2+2|x0∥xK|≥4η≥0.8, (19)
i.e., the energy of the center peak is roughly twice as large as the energy of the side-peaks, and reveals the trident in the approximated Huffman autocorrelation A. But, since the CFO is unknown in many embodiments of the invention and Kϕ−ψ≈2nπ for some n∈ then x0+xK≈0 for typical Huffman sequences, such that the power of the center peak will vanish. Hence, in the presence of an unknown CFO, the center peak does not always identify the trident. Therefore the positive Huffman bracket can be correlated with the absolute-square value of x or in presence of noise and channel with the absolute-square of the received signal {tilde over (r)}, which will result approximately in
d=
*|{tilde over (r)}|
2
=
*|{tilde over (x)}*{tilde over (h)}T
τ
|2+*|{tilde over (w)}|2≈|ă|2*|{tilde over (h)}Tτ
where {tilde over (w)} and {tilde over ({tilde over (w)})} are colored noise and
|ă|2=(|x0|2,|{combining breve ({dot over (x)})}|2,Esides,|{combining breve ({dot over (x)})}−|2,|xK|2) (21)
denotes the noisy trident which collects three times the instant power delay profile |h|2 of the shifted CIR. These three echoes of the CIR can be separated where K≥L. The approximation in (20) can be justified by the isometry property of the Huffman convolution. Briefly, L<K, the generated (banded) L×N Toeplitz matrix Tx=Σk=0KxkTk, for any Huffman sequence x∈(K), is a stable linear time-invariant (LTI) system, since the energy of the output satisfies for any CIR realization h∈L
∥x*h∥2=∥hTx∥2=tr(hTxTx*h*)=tr(h*Axh)=∥x∥2tr(h*h)=∥x∥2∥h∥2. (22)
Here, Ax=TxTx* is the L×L autocorrelation matrix of x, which is the identity scaled by ∥x∥2 if L≤K. Hence, each normalized Huffman sequence, generates an isometric operator Tx having the best stability among all discrete-time LTI systems.
In several embodiments, instead of or in addition to taking the absolute-squares before correlating with the bracket π, the receiver performs an average over different brackets. In several embodiments, the receiver takes P≥2 uniform phases ψp=2πp/P for p∈[P]. The receiver can then consider the average energy of all P bracket-filters, defining the filter
For n=K
Since
for any Kϕ∈ the term will vanish for any 2≤P∈ by the orthogonality of the Fourier basis
To reduce the effort a selection of P=2 can be made to yield to the center energy |x0|2+|xK|2=Esides≥2η for any normalized Huffman sequence. The other filter outputs are bounded by
In fact, the filter F2,n can be realized for any received signal y by taking the first approach, i.e. by taking the absolute-square of the received signal and then filtering with the brackets 0, i.e., F2,n(y)=(|y|2*0)n. Note, that it holds trivially max{|x0|2, |xK|2}<F2,K(
Processes that can be utilized to perform timing offset estimation in accordance with various embodiments of the invention are discussed further below.
The delay of the strongest path |hs=∥h∥∞ can be identified from the maximum in (20)
where the last equality follows from the fact that both peaks in 0 are contributing between K and Nobs. If the CIR has a LOS path, then s=0 and an estimate for the timing-offset can be found by {circumflex over (r)}0=1.
When the receiver takes an average over different brackets, simulations reveal the existence of a typical sequence attaining an energy peak of 1−2η, for even K see
for any K≥2, τ0Σ, ϕ∈, ½≤η>¼ and x∈. Here, the center peak is weighted by a factor of two, since it carries the energy of both side-peaks. To increase the maximal filter output further, a maximal energy filter can be utilized in accordance with many embodiments of the invention, which is defined by
where for n=K the center energy is increased by maximizing over the P phases
Since Kϕ is uniformly distributed, induced by the channel CFO, p can be selected such that Kϕ−π∈[(p−1)/P,p/P]2π. Hence, the worst case estimation (ϕ=pπ/KP for some p) would be −cos(π−π/P)=cos(π/P)≥1−2/P+(π−2)(P−2)/P2≥¾ for P≥6, by the extended Kober's inequality, such that for any x∈ and ϕ∈ it holds
Hence, for x∈ and {tilde over (x)}τ=xTτ0Mϕ with τ∈ the maxTriED will identify the true TO
In
In case of NLOS or if the first paths are equally strong, then processes in accordance with several embodiments of the invention can go further back and identify the first significant peak above the noise floor, since the convolution sum of the CIR with the interior signature might produce a significant peak. It should be noted that this might result in a misidentification of the trident's center peak by (27), for example if |hs|/|h0|>>1. Therefore, processes in accordance with several embodiments of the invention can utilize a peak threshold
which is the average power of the Huffman sequence distorted by the channel and noise. The noise-dependent threshold can be set based upon the Noise Power N0 to
ρ0=max{ρ(K,d)/10, . . . ,ρ(K,d)/100,10·N0} (34)
By using an iterative back stepping in Algorithm 1 as shown in
Since a communication system that utilizes BMOCZ does not need any channel knowledge at the receiver, it is also well suited for estimating the channel itself at the receiver. Here, a good channel length estimation is helpful for the performance of the decoder, particularly if the power delay profile (PDP) is decaying. At some extent, the channel delays will fade out exponentially and the receiver can cut-off the received signal by using a threshold such as (but not limited to) a certain energy ratio threshold. The average received SNR is
where E=∥x∥2=N is the energy of the BMOCZ symbols, which is constant for the codebook. If the power delay profile is flat, then the collected energy is uniform and the SNR is unlikely to change if the channel length at the receiver is cut. However, the additional channel zeros can increase the confusion for the DiZeT decoder and may reduce BER performance. Therefore, the performance can decrease for increasing L at a fixed symbol length K. For the most interesting scenario of K≈L the BER performance loss is only 3 dB over Eb/N0, but will increase dramatically if L>>K. The reason for this behaviour is the collection of many noise taps, which can lead to more distortion of the transmitted zeros. Since in most realistic scenarios the PDP will be decaying, most of the channel energy is typically concentrated in the first channel taps. Hence, cutting the received signal length to Neff=K+Leff, can reduce the channel length to Leff<L and improve the rSNR for non-flat PDPs with p<1, since it holds
Since 1/[∥heff∥2]<<N/Neff a significant gain in SNR can be obtained if L>>K and p<1. Hence, by cutting the received signal to the effective channel length, given by a certain energy concentration, the SNR can be improved and, at the same time, the amount of channel zeros can be reduced, which is demonstrated in the simulations discussed below.
Assuming knowledge of the noise floor N0 at the receiver, a cut-off time can be defined as a window of time which, for example, contains 95% of the received energy. As can readily be appreciated, the cut-off time can be determined using any of a variety of techniques appropriate to the requirements of a specific application in accordance with various embodiments of the invention.
In several embodiments of the invention, the estimation of the channel length Lef is performed after the detection of the timing-offset τ0 with Algorithm 1 from
There are many signal processing methods that can be utilized to detect the efficient energy window Neff in the received samples, including (but not limited to) total variation smoothing, or regularized least-square methods which promotes short window sizes (sparsity). In several embodiments, the process (i.e. Algorithm 2) shown in
E
r
=∥r
h∥2−LN0 (37)
starting with the maximal CIR length L. By assuming a path exponent of p, processes in accordance with various embodiments of the invention can calculate a threshold for the effective energy Eeff≅μEr with μ=pLN
{tilde over (y)}=({tilde over (r)}{tilde over (τ)}
which can be further processed for CFO detection and final decoding as is discussed further below.
While specific processes are described above for performing channel length estimation, any of a variety of techniques for performing channel length estimation can be utilized as appropriate to the requirements of specific applications in accordance with various embodiments of the invention. Processes for determining CFOs in accordance with various embodiments of the invention are discussed further below.
When processes similar to those described above are utilized to estimate timing offset, processes in accordance with several embodiments of the invention can attempt to estimate a CFO assuming that the down-converted baseband signal in (11) has no further timing-offset and captured all path delays up to N=K+L. Under these assumptions, the signal can further be assumed to experience an unknown CFO of ϕ∈[0, 2π)
{tilde over (y)}
n
=e
jnϕ(x*h)n+wn, n∈[N]. (39)
This is a common problem in many multi-carrier systems, such as OFDM, which therefore often require CFO estimation algorithms as noted above. For a bandwidth of W=1/T, the relative frequency offset is
ϵ=Δf·T=Δf/W. (40)
Given a carrier frequency of fc=1 GHz with a drastic frequency offset of Δf∈[−1, 1] MHz and bandwidth W=1 Mhz, this would result in a relative frequency offset ϵ∈[−1, 1], which is able to rotate all zeros by any ϕ=2πϵ∈[0,2π) in the z-plane. Hence, the received polynomial (noiseless) will experience a rotation of all its N−1 zeros by the angle ϕ
As illustrated in
To apply the DiZeT decoder, decoding processes in accordance with many embodiments of the invention find θ such that ejθ{tilde over (α)}∈, i.e., ensuring that all the K data zeros will lie on the uniform grid. Hence, for θK=2π/K the CFO can be split into
ϕ=lθK+θ (42)
for some l∈[K] and θ∈[0, θK), where l is called the integer and θ the fractional CFO. When θ=0 (or is correctly compensated), the DiZeT decoder can sample at correct zero positions and decode a cyclic permuted bit sequence {tilde over (m)}=mSl of the transmitted message. The cyclic permutation is due to the unknown integer shift l, which can be corrected by use of a cyclically permutable code to encode the transmitted data in accordance with various embodiments of the invention and as is discussed further below.
In many embodiments, the DiZeT decoder for BMOCZ can allow a simple hardware implementation at the receiver. In a number of embodiments, the received samples yn are scaled with the radius powers Rn respectively R−n
By applying the Ñ-point unitary IDFT matrix F* on the N0 zero-padded scaled signal, where Ñ=QK with Q:=┌N/K┐, the samples of the -transform can be obtained
where
Hence, the DiZeT decoder simplifies to
Here, Q≥2 can be seen as an oversampling factor of the IDFT, where each Qth sample point is picked to obtain the zero sample values. Hence, in many embodiments the decoder can be fully implemented by a simple IDFT from the delayed amplified received signal, by using for example FPGA or even analog front-ends. The diagonal scaling matrix (43) can be rewritten in the symmetric form
D
R:=diag(R(N-1)/2, . . . ,R−(N-1)/2)=R−(N-1)/2DR, (45)
such that DR−1=DR
|y{tilde over (D)}RFQK*|Qk≤|
since the absolute values cancel the phases from a circular shift S and the conjugate-time-reversal
To estimate the factional frequency offset, oversampling can be performed in many embodiments of the invention by choosing Q >┌N/K┐ to add Q further K zero blocks to DR. This can lead to an oversampling factor of Q and allows quantization of [0, θh) in Q uniform bins with separation ϕQ=θK/Q for a base angle θK=2π/K. Hence, the absolute values of the sampled z-transform in (39) of the rotated codebook-zeros are given by
for each q∈[Q] and k∈[K], where ⊕N is addition modulo N. To estimate the fractional frequency offset of the base angle, the K smaller sample values can be summed and the fraction corresponding to the smallest sum selected
Then the recovered signal ŷ={tilde over (y)}M−{tilde over (θ)} will have the data zeros on the constellation grid K. See
To be robust against rotations which are integer multiples of the base angle, an outer block code in 2K can be used for the binary message m∈2B, which is invariant against cyclic shifts, e.g., a bijective mapping on the Galois Field 2={0, 1}
:F2B→2K, mc=(m) (49)
such that −1(cSl)=m for any l∈[K]. The common notation for the code length n=K can be used. Such a block code is called a cycling register code (CRC) CRC, which can be constructed from the linear block code 2n, by separating it in all its cyclic equivalence classes
[c]CRC={cSl|l∈[n]}, c∈F2n (50)
where c has cyclic order ν if cSν=c for the smallest possible ν∈{1, 2, . . . , n}. To make coding one-to-one, each equivalence class can be represented by the codeword c with smallest decimal value, also called a necklace. Then 2n is given by the union of all its MCRC equivalence class representatives and its cyclic shifts, i.e.
In a number of embodiments, the above expression can be utilized to generate in a systematic way a look-up table for the cycling register code. Unfortunately, the construction is non-linear and combinatorial difficult. However, the cardinality of such a code can be proven explicitly for any positive integer n to be (number of cycles in a pure cycling register)
where Φ(d) is the Euler function, which counts the number of elements t∈[d] coprime to d.
For n prime, the following can be obtained
which would allow a transmitter to encode at least B=n−[log n] bits. For n=K=31 this would result in a loss of only 5 bits and is similar to the loss in a BCH-(31, 26) code, which can correct 1 bit error. Note, the cardinality of a cycling register code CRC is minimal if n is prime. This can be seen by acknowledging the fact that the cyclic order of a codeword is always a divisor of n. Therefore, if n is prime the trivial orders 1 and n are present, where the only codewords with order ν=1 are the all one 1 and all zero 0 codeword and all other codewords have the maximal or full cyclic order ν=n. Hence, extracting the CRC from 2n obtains the same cardinality (53). Taking from a block code of length n only the codewords of maximal cyclic order n and selecting only one representative of them defines a cyclically permutable code (CPC). If n is prime, only two equivalence classes in CR are not of maximal cyclic order, hence the cardinality for a CPC if n is prime is at most (2n−2)/n.
However, the construction of CPCs, even for n prime, is a combinatorial problem, especially the decoding. Hence, to reduce the combinatorial complexity, many approaches starting from cyclic codes and extract all codewords with maximal cyclic order. Since a cyclic (n, k, dmin) code corrects up to (dmin−1)/2 bit errors, any CPC code extraction will inherit the error correction capability.
In many embodiments, a CPC can be constructed from a binary cyclic (n, k, dmin) code by still obtaining the best possible cardinality (2k−2)/n if n is a Mersenne prime. An affine subcode can be extracted from the CPC with maximal dimension, which can be referred to as an affine cyclically permutable code (ACPC). This allows a linear encoding of B=k−log(n+1) bits by a generator matrix and an additive non-zero row vector, which defines the affine translation.
CPC Construction from Cyclic Codes
Cyclic codes exploit efficiently the algebraic structure of Galois fields q, given by a finite set having a prime power cardinality q=pm′. A linear block code over q is a cyclic code if each cyclic shift of a codeword is a codeword. It is a simple-root cyclic code if the characteristic p of the field q is not a divisor of the block length n. If the block length is of the form n=qm−1, it can be referred to as a primitive block length and if the code is cyclic it can be called a primitive cyclic code. In a number of embodiments, binary cyclic codes of prime length n=2m−1 with q=p=2 are utilized, which are simple-root and primitive cyclic codes. Due to the linearity of cyclic codes, they can be encoded and decoded by a generator G and check matrix H in a systematic way. The cardinality of a binary cyclic (n, k) code is always Mc=2k. Hence, for cyclic codes of prime length n, the partitioning in equivalence classes of maximal cyclic order and selecting one codeword as their representative provides, leaves us with a maximal cardinality of
for any extracted CPC. Note, the zero codeword is always a codeword in a linear code but has cyclic order one and hence is typically not an element of a CPC. To exploit the cardinality most efficiently, the goal is to find cyclic codes such that each non-zero codeword has maximal cyclic order. In several embodiments, codes are constructed for prime code lengths of the form n=2m−1, also known as Mersenne primes. For m=2, 3, 5, 7 this applies to K=n=3, 7, 31, 127, which are relevant signal lengths for binary short-messages. Furthermore, several embodiments only consider cyclic codes which have 1 as a codeword. Since n is prime, each codeword, except 0 and 1 has maximal cyclic order. Hence, each codeword of a cyclic (n, k) code has maximal cyclic order and since it is a cyclic code all its cyclic shifts must be also codewords. Hence the cardinality of codewords having maximal order is exactly M=2k−2. In a number of embodiments, the cyclic code is partitioned in its cyclic equivalence classes, which leaves |CPC|=M/n=(2k−2)/n. Note, this number is indeed an integer, by the previous mentioned properties. The main advantages of the construction described herein (also referred to as the Kuribayashi-Tanaka (KT) construction) is the systematic code construction and the inherit error-correcting capability of the underlying cyclic code, from which the CPC is constructed. Furthermore, combining error-correction and cyclic-shift corrections can provide advantages in many systems that utilize BMOCZ in accordance with various embodiments of the invention.
In a number of embodiments, an inner in−(k, k−m) cyclic code is utilized in combination with an outer out−(n, k) cyclic code, where the inner cyclic codewords are affine translated by the Euclidean vector e1=(1, 0, . . . , 0)∈2k. In this sense, the CPC construction is affine. This can be realized by an affine mapping from 2k-m to 2n, which can be represented by the BCH generator matrices Gin and Gout together with the affine translation e1 as
:2k-m→in+e1→out⊂2n
m
i=mG
in
+e
1
c=iG
out=(m). (55)
To derive the generator matrix the algebraic structure of the cyclic codes can be exploited, given by its Galois fields. By definition of cyclic codes, the following polynomial is factorized
in irreducible polynomials Gs(x) of degree ms, which are divisors of m. If n=2m−1 is prime, in =log(n+1) is also prime and hence all the irreducible polynomials are primitive and of degree ms=m, except one of them, G0(x)=x−1, has degree one. Hence, it holds that S=(n−1)/m. As outer generator polynomial Gout(x)=Πs=S-J+1SGs(x)=Σi=0J
C(x)=I(x)Gout(x) (57)
where I(x)=Σa=0k-1iaxa is the informational polynomial of degree less than k and represented by the binary information word i=(i0, i1, . . . , ik-1)∈2k, which can be referred to as the inner codeword. Similar, the codeword polynomial C(x) is represented by the CPC codeword c∈2n. A message polynomial M(x)=Σb=0k-m-1mbxb of degree less than k−m and R(x)=1 will be mapped to the information polynomial
I(x)=M(x)Gin(x)+1, (58)
by the inner generator polynomial Gin(x)=G1(x), which has degree in.
All possible cyclic equivalence classes can be mapped to M(x). For J=1, all the possible S−1 primitive polynomials Gs(x) generate S−1 distinct inner codes. However, the remaining −2 inner codes will only map <2k-m more message polynomials to codeword polynomials and therefore are not enough to encode an additional bit. Hence, these other inner codewords can be omitted. This has the advantage, that (55) can be written with the subset of the CPC as an affine cyclically permutable code (ACPC), which is given by the polynomial multiplication over 2
C(x)=I(x)Gout(x)=(M(x)Gin(x)+1)Gout(x)=M(x)G(x)+Gout(x). (59)
Here, a third generator polynomial G(x)=Gin(x)Gout(x) can be introduced which will be affine translated by the polynomial Gout(x). This generator polynomial G(x) will map subjective 2k-m to a cyclic code in 2n and can therefore be expressed in matrix form as
mG+g
out∈ACPC⊂out (60)
where gout=(gout,0, . . . , gout,n-k, 0, . . . , 0)∈2n and the generator matrix (Toeplitz) is given by k−m shifts of the generator polynomial coefficients g0, . . . , gn-(k-m) as
For linear codes, the Euclidean algorithm can be used to compute xn-i=Qi(x)C(x)+Si(x) for i=1, . . . , k−m, where the remainder polynomials Si(x)=Σjsi,jxj will have degree less than n−(k−m), which allows one to rewrite the Toeplitz matrices as systematic matrices. Here, the check symbols si,j define the k−m×n systematic generator and n−k+m×n check matrix
such that {tilde over (G)}{tilde over (H)}T=Ok-m,n-k+m. This allows one to write the cyclic outer code as 2k-mG=2k-m{tilde over (G)}. Of course, each mG and m{tilde over (G)} can be mapped to different codewords, but this is just a relabeling. Since 2k-m{tilde over (G)} defines a cyclic (n, k−m) code and n is prime, each codeword has n distinct cyclic shifts. The affine translation gout separates each of these n distinct cyclic shifts by mapping them to representatives of distinct cyclically equivalence classes of maximal order. This can provide a very simple encoding rule for each m∈2B:
c=m{tilde over (G)}+g
out=(m)∈ACPC, (63)
and decoding rule. Here an ACPC codeword c can be decoded by just subtracting the affine translation gout and cut-off the last B=k−m binary letters to obtain the message word m∈2B, see (62). However, it can be observed that a cyclic shifted codeword v=cSl and by construction that only one cyclic shift will be an element of ACPC and consequently it holds
∀j≠l mod(n−1):{tilde over (c)}j=vS−j−gout∉2k-m{tilde over (G)}⇔={tilde over (c)}j{tilde over (H)}T≠0. (64)
Hence, it is only necessary to check all n cyclic shifts of the sense-word v to identify the correct cyclic shift l, which is given if {tilde over (c)}l{tilde over (H)}T=0. If there is an additive error e, process in accordance with various embodiments of the invention can use the error correcting property of the outer cyclic code out in (59) to repair the codeword. The systematic matrices can be used {tilde over (G)}out and {tilde over (H)}out to represent the outer cyclic code in a systematic way. Note, that each information message i which corresponds to a CPC codeword c will be an element of 2k{tilde over (G)}out. Furthermore, all its cyclic shifts cSl will be outer cyclic codewords. Hence, by observing the sense-word
{tilde over (v)}=cS
l
+e (65)
and determining its syndrome s=v{tilde over (H)}outT, which is looked-up in the syndrome table Tsynd of {tilde over (H)}out to identify the corresponding coset leader (error-word) e, which recovers the shifted codeword (assuming maximal t errors, bounded-distance decoder) as
v={tilde over (v)}−e, (66)
This can allow the receiver to correct up to t=(n−k−1)/2 errors of the cyclic codeword. From the additive error-free sense-word c the process can, as described previously, identify the correct shift {circumflex over (l)} from (64) and by taking the last B=k letters the original message m. If the error vector e introduces more than t bit flips, the error correction is likely to fail and the chance is high that the receiver will mix up the ACPC codewords and experience a block (word) error. In many embodiments, a low coding rate is utilized for the outer cyclic code Gout to reduce the likelihood of such a catastrophic error. In several embodiments, the rate of the outer code can adapt in response to measured channel conditions. In a number of embodiments, the receiver can transmit a message containing at least one of a selected code rate and/or channel measurement to coordinate changing the rate of the outer code in the transmitter.
The identified cyclic shift and fractional CFO estimation (48) yields then the estimated CFO
{circumflex over (ϕ)}={circumflex over (θ)}+{circumflex over (l)}θK. (67)
While specific processes are described above for estimating TO, and/or CFO in addition to correcting bit errors, any of a variety of codes including CRC, CPC, ACPC, and/or any other codes that can be utilized to detect cyclic permutations and/or receiver implementations can be utilized as appropriate to the requirements of specific applications in accordance with various embodiments of the invention. Simulations of various communication systems implemented using BMOCZ schemes and employing cyclic codes to encode message bits in accordance with a number of embodiments of the invention are discussed further below.
Simulations of communication systems employing MOCZ and cyclic codes can be performed in Matlab by using the function primpoly(m, ‘all’) to list all primitive polynomials for 2
Decoding: First an additive error-correction is performed in the outer code out, which works as for cyclic codes via the syndrome-table Tsynd and the check matrix {tilde over (H)}out. First, the syndrome s=v{tilde over (H)}outT is computed and looked-up in the syndrome-table to identify the corresponding coset leader (error-word) e, which yields the recovered shifted codeword (assuming maximal t errors, bounded-distance decoder) as
{tilde over (c)}=v−e. (68)
From the additive error-free but circular shifted codeword {tilde over (c)} the process can construct all 1n shifts, subtract the constant shift vector a=gout, and apply the check matrix {tilde over (H)}out to find the one shift which is most likely the ACPC codeword
The most non-trivial example of ACPC is for m=3 and l=1, which gives
n=23−1=7, k=7−3=4, B=4−1=1 (69)
This is also the Hamming (7, 4) code with minimal distance dmin=3 and hence can correct 1 bit error. The code is also perfect.
For K=n=31 it is possible to get for t=2 error corrections a message length of k=21 in a cyclic BCH-(31, 21) code from which it is possible to construct a CPC of cardinality
This allows communication systems in accordance with several embodiments of the invention to encode B=16=k−m bits. The cardinality can be optimal for any cyclic (31,26) code (54)
The next example would be for n=127, which is also simulated in
Consideration should also be given to what may be the shortest non-trivial CPC, which can be addressed without cyclic code construction, but also with no error correction capabilities.
For n=3 the communication system may only have 23=8 binary words of length 3 which have 4 different cyclic permutable codewords c1=1, c2=(1, 1, 0), c3=(1, 0, 0), c4=0 allowing the transmitter to encode B=2 bits of information with no error correction. However, this code allows a TO estimation, as well as a CIR estimation. By omitting c1 and c4, i.e., by dropping one bit of information, an estimate can be obtained with the DiZeT oversampling decoder for any possible CFO.
While specific codes and encoder and decoder implementations are described above, communication systems in accordance with various embodiments of the invention can use any of a variety of codes that are rotation invariant and/or provide bit error correction capabilities as appropriate to the requirements of specific applications in accordance with various embodiments of the invention. The simulation of specific communication systems in accordance with a number of embodiments of the invention is discussed further below.
Monte-Carlo simulations of communication systems in accordance with various embodiments of the invention were performed using MatLab 2017a the bit-error-rate (BER) over averaged Eb/N0 and rSNR under various channel settings and block lengths K. The transmit and receive time was in all schemes N=K+L over which the CIR h of length L was assumed to be static, see
Due to the embedded error correcting and a complete failure if a wrong CPC codeword is detected, the BER and BLER (block-error-rate) are almost identical over received SNR for BMOCZ-ACPC, see purple filled circle line in
Of course, it would be also possible to detect a wrong decoding and request a retransmit.
For a receiver with M antennas, receive antenna diversity can be exploited, since each antenna can receive the transmit signal over an independent CIR realization (best case). Due to the short wavelength in the mmWave band large antenna arrays with λ/2 spacing can be easily installed on small devices. It was assumed in all simulations:
In many embodiments, the fractional CFO is estimated by (48) for M received signals ym
The effect of different coding rates on BER and block error rate (BLER) for the BMOCZ-ACPC-(K, B) scheme with K=31 transmitted zeros and channel lengths L=16, 32 with flat power profile p=1 is shown in
A random integer timing offset can be chosen in τ0∈{0, 1, 2 . . . , N−1} in
Indeed, if the CIR length is larger with exponential decay, a wrong TO estimation yields to less performance degradation as for shorter lengths, since the last channel tap will be much smaller in average power. A simulation can be performed by choosing randomly for each simulation, consisting of D different noise powers N0.
Each binary plain message m will result in a codeword c∈2K which corresponds to a normalized BMOCZ symbol x∈K+1. The CIR can be normalized at the transmitter to {tilde over (h)}=h/[∥h∥2], where the average energy of the CIR is given by (36) as the expected power delay profile in s
For each selected sparsity pattern of the CIR, normalized CIR energy is obtained if selecting random channel taps by the law of large numbers. By averaging over the sparsity pattern, this can result in a large deviation of the CIR energy and would require many more simulations, therefore the average power was calculated with knowledge of the sparsity patterns, i.e., by knowing the support realization.
First, a comparison is performed without TO and CFO between BMOCZ and OFDM and pilot based schemes, in
Pilot and SC-FDE with QPSK.
A pilot impulse
of length P=L can be used to determine the CIR and K+1−L symbols to transmit data via QPSK in a single-carrier (SC) modulation by a frequency-domain-equalization (FDE). Applying FDE, QPSK or QAM modulated OFDM subcarriers K+1−L can be decoded. The energy E is split evenly between the pilots and data symbols, which can result in better BER performance for high SNR, see
OFDM-Index-Modulation (IM).
A comparison can also be performed with respect to: OFDM-IM with Q=1 and Q=4 active subcarriers out of KIM=K+1 and to OFDM-Group-Index-Modulation (GIM) with Q=1 active subcarriers in each group of size C=4. To obtain an OFDM symbol a cyclic-prefix is added, which requires KIM≥L. For OFDM systems, the CFO will result in a circular shift of the KIM subcarriers and hence create the same confusion as for BMOCZ. The only difference is, that OFDM operates only on the unit circle, whereas BMOCZ operates on two circles inside and outside the unit circle. Note, in OFDM-IM a cyclic permutable code is not applicable, since the information for example with Q=1 is a cyclic shift, which is exactly what the CFO introduces. For more active subcarriers Q>1 and grouping the carriers in groups, ICI free IM schemes can be deployed. A group size of G=4 seems to perform the best for OFDM-IM. However, this will require L<<K which is not the proposed regime for MOCZ.
OFDM-Differential-Phase-Shift-Keying (DPSK).
Two successive OFDM blocks can be used to encode differentially the bits via Q-PSK over Kdif subcarriers. To ensure the same transmit and receive lengths as for BMOCZ, the BMOCZ symbol length K+1 can be split in two OFDM symbols with cyclic prefix xCP(1) p and xCP(2) of equal length Ndif=N/2, where N=K+L is chosen to be even. Furthermore, to include a CP of length L−1 in each OFDM block, it is required that Ndif=(K+L)/2 ≥2L−1 resulting in the requirement K≥3L−2. If L is even and K=nL for some 2<n∈ it is possible to obtain Kdif=Ndif−L+1=(n−1)L/2+1 subcarriers in each OFDM block. The shortest transmission time is then given for even L with n=3 by N=4L, resulting in Kdif=L+1 subcarriers. Modulating them with Q-PSK allows to transmit (L+1) log Q bits differentially. To match the spectral-efficiency of BMOCZ as best as possible, it is possible to select Q=8 to encode 3 bits per subcarrier and hence B=(L+1)3=(K/3+1)3=K+3 message bits, which is 3 bits more than BMOCZ.
The encoding of the DPSK can be done relative to the first OFDM block i=1, which will transmit. PSI(constellation points as with phase zero sk(1)=1 respectively data phases sk(2)=ej2πq
x=(xCP(1),xCP(2)), xCP(i)=(CP(i),x(i)), CP(i)=(xN
for i=1, 2. Here x will be also normalized.
After removing the CP at the receiver the received data symbols in frequency domain via the mth antenna for the kth carrier is given by
R
m,k
(i)
=H
m,k
s
k
(i)
+W
m,t
(i) (77)
where it is possible to consider {Wm,k(i)} as independent circularly symmetric Gaussian random variables and Hm,k∈ the channel coefficient of the kth subcarrier. Hence, each subcarrier can be seen as a Rayleigh flat fading channel and the decision variable can be used for a hard-decoding of M antennas
Here int(⋅) rounds to the nearest integer. It is possible to ignore here a possible weighting by knowledge of SNR.
Simulations with Quadriga Channel Simulator
Version 2.0 of the Quadriga channel simulator was used to generate random CIRs for the Berlin outdoor scenario (“BERLIN_UMa_NLOS”), with NLOS at a carrier frequency fc=4 Ghz and bandwidth W=150 Mhz, see
Since the Q times oversampled DiZeT decoder is realized by the QK-point IDFT, computationally complexity an be reduced for Mersenne primes K, if the chosen oversampling factor Q is relatively prime to K. Since K is prime, Q can be chosen to be not a multiple of K. Since N=K+L, L≠mK need only be chosen for m∈ so that Q=N is relatively prime to K, i.e., only have one as a common divisor. In this case the QK-DFT can be efficiently computed by the prime-factor algorithm (PFA), which is as efficient at the FFT for lengths of powers of two. During simulation in Matlab, a speed improvement by a factor of 10 in the oversampled DiZeT decoder was observed for K=31 when switching from L=31 to L=32.
As can readily be appreciated, the simulations described above form a basis for implementation of communication systems in accordance with various embodiments of the invention using appropriate programmable and/or custom integrated circuits. While specific simulations are described above, any of a variety of simulations and testing processing can be performed in order to finalize a transmitter and/or receiver design as appropriate to the requirements of specific applications in accordance with various embodiments of the invention.
Although the present invention has been described in certain specific aspects, many additional modifications and variations would be apparent to those skilled in the art. It is therefore to be understood that the present invention can be practiced otherwise than specifically described including transmitters and receivers that communicate via any of a variety of communication modalities using MOZ without departing from the scope and spirit of the present invention. Thus, embodiments of the present invention should be considered in all respects as illustrative and not restrictive. Accordingly, the scope of the invention should be determined not by the embodiments illustrated, but by the appended claims and their equivalents.
The present invention claims priority to U.S. Provisional Patent Application Ser. No. 62/802,578 entitled “Robust Transceiver Designs for Frequency and Time Offsets”, filed Feb. 7, 2019, the disclosures of which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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62802578 | Feb 2019 | US |