Embodiments of the present disclosure relate generally to the field of radio or sound transmission, in particular direction of arrival (DOA) estimation of radio or sound signals. Particular embodiments include a method for DOA estimation and a receiver configured for DOA estimation. Particular embodiments relate to DOA in mobile networks such as 4G and 5G networks, in Cognitive Radio Networks, in radio navigation, in indoor radio location, for example of items with transmitters, or in sonar or radar.
The Direction of Arrival (DOA) problem is critical to position location of one or more radio transmitters and arises across numerous applications in radio communications, radio navigation, object location and radar.
For example, in cellular 4G and 5G networks, a precise estimate of incoming DOA can facilitate operation of the network, for example through resource allocation to provide increased in-cell information capacity, such as through the use of small cells within the cell and direct device to device communication within the cell. Location information on radio transmitters is usable to achieve efficient resource allocation, for example to assist in maximising transmission capacity attained through the efficient designation of mobile users as device-to-device users, users transmitting and receiving through the base station, or small cell users transmitting through a radio head. In another example resources may be efficiently allocated to users when the location of the users is known. Resources that may be allocated include channels and transmit power levels.
In a Cognitive Radio Network, DOA may also be used for resource allocation. For example, the angular domain may be evenly sectorized into spatial slots. The dedicated spatial slots allow primary/licensed and secondary/unlicensed users to be spatially multiplexed simultaneously into the same channel. This results in an uninterrupted communication between users (primary/secondary), hence increasing the throughput of the overall network in a specific geographical region. In general, in Cognitive Radio Networks, knowledge of the position of radio transmitters is crucial for efficient networks operation.
In cellular networks as well as in CRN, when considering radio jamming, the determination of the DOA can be critical in producing a null in the received antenna pattern in the correct location to null-out the jammer. Determination of the location of radio jammers may also be important in defence networks. Further, the determination of the location of a radio transmitter may also be important for identifying whether a transmission originated from a legitimate user of the network or from a spoofer or unauthorized user of the network.
The DOA problem also arises in the context of determining the location of a source of sound. For example, DOA estimation may be required in relation to a sonar system.
In general, the determination of the location of a transmitter may be achieved by determining the angle of arrival at two receive locations and then using triangulation. For the case of the transmitter being colinear with the line between the two receiving stations, the angle of arrival from a third receiving station may be required.
The precision of the transmitter location increases with increasing precision of the angle of arrival. The minimization of error in the angle of arrival determination is therefore important, for at least some applications of the DOA problem.
Additionally, in at least some applications of the DOA problem there are limits on the computational capability and/or power consumption of the implementing device and/or it would be advantageous to provide a solution to the DOA problem that can be implemented on relatively low computationally capable platforms and/or with relatively low power consumption hardware or processors.
The present disclosure generally relates to methods of direction of arrival (DOA) estimation of signals, including the example methods described in the paragraphs below.
A method for use in a direction of arrival estimator for a signal, includes:
receiving, at a computational processor, a set of measurements of a signal taken by an array of sensor elements;
generating first and second measures of a direction of arrival estimate, the generating based on first and second grids of potential direction of arrivals respectively, the first and second grids offset from each other;
generating an angular discriminant based on the first and second measures; and
generating third and fourth measures of a direction of arrival estimate, the generating based on third and fourth grids of potential direction of arrivals respectively, the third and fourth grids offset from the first and second measures by an amount based on the angular discriminant.
A method for use in a of direction of arrival estimation for a signal, includes:
receiving, at a computational processor, a set of measurements of a signal from a source taken by an array of sensor elements;
generating, by the computational processor based on the received measurements, a first measure associated with a first direction of arrival estimate for the signal, based on a first grid with a plurality of grid points corresponding to potential directions of arrival, the grid comprising a larger number of grid points than antenna elements in the array of sensor elements and a lower resolution of grid points than required to achieve a target accuracy for the direction of arrival estimation;
generating, by the computational processor, a second measure associated with a second direction of arrival estimate for the signal, based on a second grid comprising grid points around the first direction of arrival estimate that are offset to grid points in the first grid; and
determining, by the computational processor, an angular discriminant based on the first measure and the second measure,
wherein the measures associated with the direction of arrival estimates are based on a solution to a sparse problem defined by the received set of measurements and the respective grid points.
A method of direction of arrival estimation for a signal includes:
receiving, at a computational processor, a set of measurements of a signal from a source taken by an array of sensor elements;
generating, by the computational processor based on the received measurements, a direction of arrival estimate for the signal, wherein the direction of arrival estimate is based on compressive sensing of a sparse problem defined by the received set of measurements and a grid with a plurality of grid points corresponding to potential directions of arrival, the grid comprising a larger number of grid points than sensor elements in the array of sensor elements.
A sensor array for direction of arrival estimation includes a plurality of sensor elements arranged in an array geometry, each sensor element configured to provide a measurement signal of a signal having a base wavelength, wherein a distance between pairs of sensor elements is substantially equal to a distance that minimises at least one of or a combined measure of a mutual coherence and a condition number of a matrix of said measurement signals of a signal by the sensor array at the base wavelength.
A sensor array for direction of arrival estimation includes a plurality of sensor elements arranged in an array geometry, each sensor element configured to provide a measurement signal of a signal having a base wavelength, wherein a distance between pairs of sensor elements is greater than a distance corresponding to one wavelength at the base wavelength.
A method comprising receiving, at a processor, input signals representative of detection of one or more signals received at respective plurality of spatially separated sensor elements:
in an first determination determining, by a processor, based on phase information in the input signals and a known geometry of the spatially separated sensor elements, a sparse solution indicating one or more estimated directions of arrival amongst a first set of candidate directions of arrival; and
in a second determination, determining, by a processor, based on phase information in the input signals and the known geometry of the spatially separated sensor elements, a sparse solution indicating one or more estimated directions of arrival amongst a second set of candidate directions of arrival, wherein the second set of candidate directions of arrival is offset from the first set of candidate directions of arrival;
identifying, by a processor, an estimated direction of arrival, the estimated direction of arrival being offset from directions of arrival in the first and second sets by an amount determined based on a magnitude of the sparse solution for the first determination and a magnitude of the sparse solution for the second determination.
A method comprising receiving, at a processor, input signals representative of detection of one or more signals received at respective plurality of spatially separated sensor elements:
in an initial determination and in at least a first and a second iteration determining, by a processor, based on phase information in the input signals and a known geometry of the spatially separated sensor elements, a sparse solution indicating one or more estimated directions of arrival amongst a set of candidate directions of arrival, wherein for each iteration the set of candidate directions of arrival are rotated, the rotation selected based on preceding sparse solutions to cause the iterations to display convergence in the sparse solutions; and
outputting data indicative of the solution for the second iteration or a subsequent iteration.
A method comprising receiving, at a processor, input signals representative of detection of one or more signals received at respective plurality of spatially separated sensor elements:
in an initial determination and in at least a first iteration determining, by a processor, based on phase information in the input signals and a known geometry of the spatially separated sensor elements, at least one sparse solution indicating one or more estimated directions of arrival amongst a set of candidate directions of arrival, wherein for each iteration the set of candidate directions of arrival are rotated, the rotation selected based on preceding sparse solutions to cause the iterations to display convergence in the sparse solutions; and
outputting data indicative of the solution for the first iteration or a subsequent iteration.
A method for use in a of direction of arrival estimation for a signal, comprising:
receiving, at a processor, a set of measurements of a signal by an array of sensor elements;
generating, by a processor, a first plurality of measures of a direction of arrival estimate, the first plurality of measures related to first and second grids of candidate direction of arrivals respectively, the first and second grids offset from each other by a predetermined amount;
generating, by a processor, a first angular discriminant based on the first plurality of measures;
generating, by a processor, a second plurality of measures of a direction of arrival estimate, the second plurality of measures related to third and fourth grids of candidate direction of arrivals respectively, the third and fourth grids offset from the first and second grids by an amount determined by the angular discriminant; and
generating, by a processor, a direction of arrival estimation based on a second angular discriminant based on the second plurality of measures.
A method for use in a of direction of arrival estimation for a signal, comprising:
receiving, at a processor, a set of measurements of a signal by an array of sensor elements;
iteratively generating, by a processor, a plurality of measures of a direction of arrival estimate, the plurality of measures related to first and second grids of candidate direction of arrivals respectively, the first and second grids offset from each other by a predetermined amount; and
generating an angular discriminant for each iteration, wherein the first and second grids in a subsequent iteration are offset from the first and second grids in a current iteration by an amount determined by the angular discriminant for the current iteration;
generating a direction of arrival estimation based on the angular discriminant from at least one iteration.
In some embodiments, the predetermined amount is equal to a distance between two grid points in the first and second grids.
In some embodiments, the method further comprising generating, by a processor, an initial direction of arrival estimate identified from within a third grid of candidate direction of arrivals, the third grid centred with respect to the first and second grids, wherein the direction of arrival estimation is based on the initial direction of arrival estimate.
A method comprising receiving, at a processor, input signals representative of detection a signal received at a plurality of spatially separated sensor elements:
determining, by a processor, a plurality of sparse solutions for Ŝt in Vn=Φ(Θt)Ŝt; and
Vn includes phase information of the input signals;
Θt represents a grid of points for candidate directions of arrival; and
Φ is a function of Θt and locations of the sensor elements.
In some embodiments, Vn includes a complex envelope of voltages of signal outputs from the plurality of spatially separated sensor elements, and Φ provides a multiplicative matrix transformation between the complex envelope of voltages at the directions of arrival of the grid points and the complex envelopes of the voltages of the sensor elements.
In some embodiments, the candidate directions of arrival are uniformly spaced in a plane.
In some embodiments, the error discriminant is based on a difference between two magnitudes of solutions for adjacent candidate directions of arrival.
A method comprising receiving, at a processor, M input signals representative of detection a signal received at respective spatially separated sensor elements:
in an initial computation, t=0, determining by a processor a sparse solution for Ŝt in Vn=Φ (Θt)Ŝt;
in at least a first and a second iteration t=1 and t=2 respectively, determining by a processor a sparse solution for Ŝt in
and
generating, by a processor an estimated direction of arrival of the signal received at the sensor elements, wherein the estimated direction of arrival is determined based on ΔΘt in a said iteration;
wherein:
Vn is an M×1 vector for a complex envelope for each of the M input signals;
Θ0 is an N×1 vector representing N candidate angles of arrival, M<N;
Θt is (Θt-1+ΔΘtū)2π;
Φ is an M×N matrix function of Θt-1 and locations of the sensor elements;
ω is an angular distance between two of the N potential angles of arrival;
ū is a vector of ones;
ΔΘt is determined for
In some embodiments, for the purposes of determining at least one of
and (Θt-1+ΔΘt-1ū)2π, (Q)2π=modulo(Q+πū, 2πū)−πū for any vector Q.
In some embodiments, the method further comprises continuing the iterations until a condition |ΔΘt|>Ω is not met, where Ω is a predetermined threshold value.
In some embodiments, the candidate angles of arrival are located in a plane and the estimated direction of arrival is an angle within that plane.
In some embodiments, the candidate angles of arrival, N, are located in a first plane and the estimated direction of arrival is an estimated direction of arrival for that plane and the method further comprises:
repeating the initial computation and the at least one iteration in respect of O candidate angles of arrival in place of the N candidate angles of arrival, wherein the O candidate angles of arrival are located in a second plane having at least a component substantially transverse to the first plane, to determine an estimated direction of arrival for the second plane; and
determining a second estimated direction of arrival, based on the estimated direction of arrival for the first and second planes.
In some embodiments, the second plane is perpendicular to the first plane.
In some embodiments, the second plane intersects the first plane along a line having a direction corresponding to the first estimated direction of arrival.
In some embodiments, the method further comprises determining a third estimated direction of arrival by repeating the initial computation and the at least one iteration in respect of P potential angles of arrival in place of the N potential angles of arrival, wherein the P potential angles of arrival are located in a third plane, the third plane intersecting points on a line in three dimensional space corresponding to the second estimated direction of arrival.
In some embodiments, the method further comprises iteratively determining estimated directions of arrival in planes with substantial components transverse to the preceding plane until a threshold minimum variation in estimated direction of arrival is reached.
In some embodiments, the candidate angles of arrival are spatially separated in three dimensional space, whereby Ŝt for t=0 has solution vector elements for both azimuth and elevation and wherein the method further comprises applying the initial computation and the at least one iteration to determine the azimuth in relation to the largest absolute value adjacent pair of elements with constant elevation and applying the initial computation and the at least one iteration to determining the elevation in relation to the largest absolute value adjacent pair of elements with constant azimuth.
In some embodiments, determining the sparse solution comprises utilising a CoSaMP algorithm.
In some embodiments, the method further comprises determining an estimated direction of arrival of a single signal and setting a target number of primary elements in the determined solution for Ŝt at two.
In some embodiments, the method comprises determining estimated directions of arrival of two or more signals and setting a target number of primary elements in the determined solution for Ŝt at double the number of signals for a determination in two dimensional space or at four times the number of signals for a determination in three dimensional space.
A method comprising:
receiving, at a processor, input signals representative of detection of one or more signals received at respective plurality of spatially separated sensor elements;
in an initial determination and in at least a first iteration determining, by a processor, based on phase information in the input signals and a known geometry of the spatially separated sensor elements, one or more sparse solutions indicating one or more estimated directions of arrival amongst a set of candidate directions of arrival, wherein for each iteration the set of candidate directions of arrival are rotated; and
generating data indicative of the solution for the first iteration or a subsequent iteration, wherein the generated data represents one or more direction of arrival estimates for the one or more signals.
An iterative method for direction of arrival estimation of a signal at a receiver with a plurality of spatially separated sensor elements, in which a first quantized estimate of the angle of arrival is obtained from a compressive sensing solution of a set of equations relating sensor output signals to direction of arrival is refined in a subsequent iteration by a computed error based a quantized estimate of the direction of arrival in relation to quantization points offset from the quantization points for the first quantized estimate of the angle of arrival, wherein the offset is selected to cause the iterations to converge on an estimated direction of arrival.
An iterative method for angle of arrival estimation, wherein an angle of arrival estimation in relation to a grid of candidate angles of arrival Θ in one iteration, t-1, the grid having an angular distance ω between adjacent grid points, is modified for iteration t by an error discriminant defined by
Ŝt. is solved in
using compressive sensing,
In some embodiments the method further comprises repeating the direction of arrival estimation, thereby determining a movement of the estimated direction of arrival over time.
It will be appreciated that the disclosed inventions extend to mathematical equivalents and useful mathematical approximations of the disclosed methods of determination.
In some embodiments the signal is a radio signal, the sensor elements are radio antenna elements, and the measurements are based on phase angles of a complex envelope of output from the radio antenna elements.
In some embodiments the signals are acoustical signals, the sensor elements are acoustical sensors, and the measurements are based on phase angles of a complex envelope of output from the acoustical sensors.
A radio or sound receiver may implement the disclosed method and/or include a disclosed radio antenna or acoustical sensor array. Non-transient memory may include instructions to cause a computational device to perform the disclosed method.
As used herein, except where the context requires otherwise, the term “comprise” and variations of the term, such as “comprising”, “comprises” and “comprised”, are not intended to exclude further additives, components, integers or steps.
Further aspects of the present disclosure and further embodiments of the aspects described in the preceding paragraphs will become apparent from the following description, given by way of example and with reference to the accompanying drawings.
A method for direction of arrival (DOA) estimation involves the determination of the DOA of a signal, for example a radio signal, from a measured characteristic of the signal, for example from signal complex voltages at the outputs of antenna elements configured in an array. In other examples the signal is a sound signal detected by an array of sound detectors, for example an array of microphones. In other examples the signal is a phase coherent light signal detected by an array of photodetectors.
The array may be 2-dimensional or 3-dimensional. The range of potential angles of arrival is quantized into a grid, in which the number of grid points in the quantization is greater than the number of antenna elements, whereby a sparse recovery problem is created. The grid may have points that are uniformly spaced or non-uniformly spaced. For clarity of illustration the description herein is given with reference to a uniform grid, which in at least some embodiments provides an advantage of requiring reduced computational resources. The grid may extend around all directions or occupy only a subset of directions.
In some embodiments the array of antenna elements is a circular array, which in one embodiment is a uniform circular array (UCA). In other embodiments, the array is a linear array, for example a uniform linear array. The disclosed methods may be used with other forms of uniform and non-uniform arrays. The described technique is applicable to any antenna array geometry.
In some embodiments the measurements are transformed using a transformation function that increases sparsity. For example, in one embodiment the measurements are transformed by a decorrelating transform, which may be an orthogonal transform. In other embodiments the transformation step or process is omitted.
The signals are processed using a computational technique for solving an under-determined set of linear equations. In some embodiments compressive sensing (CS) is used to determine a DOA estimate. Embodiments of compressive sensing are described, for example, in United States Patent publication number 2006/0029279 A1 (Donoho), which is hereby incorporated herein by reference. In some embodiments CS algorithms utilise basis pursuit or another greedy algorithm such as CoSaMP. CS, in particular CoSaMP is the basis of the examples provided herein, but as noted above other techniques for solving an under-determined set of linear equations may be used. The solution indicates the grid point with the greatest signal magnitude and this grid point corresponds to at least an initial estimate of the angle of arrival.
In some embodiments CS is applied with respect to antenna array output and both a first grid and a second grid, different from the first grid. In one implementation the second grid is or can be viewed as an electronic rotation of the first grid, with grid points rotationally offset (frame of reference being potential DOAs) from the grid points in the first grid. CS for the second grid may use the same measurements, e.g., the same set of complex envelope voltage outputs, as were used for the first grid.
In some embodiments CS is performed incorporating a fixed or a variable phase shift from a previous CS determination, for example as described with reference to equations (8) herein. A fixed phase shift may be to rotate the grid points to a mid-point between points in the preceding determination or in a preceding two determinations. A variable phase shift may be determined based on solutions in preceding determinations. In one embodiment a fixed phase shift is used between an initial determination and a second determination and a variable phase shift is used for a third determination.
A measure of relative magnitude between a first identified grid point and a second identified grid point from CS for the first and second grids respectively is used to determine an angular discriminant. The identified grid points indicate a resultant DOA estimate for the first and second grids, for example by being the grid point identified by a maximum value in an output vector from CS. For example, disparate magnitudes indicate an estimated DOA off-centre to the first and second grid points, whereas close or equal magnitudes indicate an estimated DOA at or near the centre of the identified grid points. The angular discriminant is used to determine an estimated direction of arrival. In some embodiments the estimated direction of arrival is determined directly from the angular discriminant and a preceding CS determination. In some embodiments the angular discriminant is used to identify a third grid incorporating a phase shift from the grid used for the preceding CS determination. In some embodiments, information identifying or related to the angular discriminant is output as an indication of a measure of error. In some embodiments the angular discriminant is used as a stop condition for an iterative process to arrive at a DOA estimate.
In some embodiments CS based on the first and second grids, as described above follow CS based on a third grid, whereby the first grid is rotationally offset from the third grid in one direction and the second grid is rotational offset from the third grid in the opposite direction (e.g., clockwise and anti-clockwise respectively). In one embodiment, the grid points of the first and second grids are offset to a mid-point between the grid points of the third grid. In some embodiments rotational offset is iteratively performed until a stop condition is met. In some embodiments the stop condition is the reaching of a threshold. The threshold selected may depend on the application. Examples of a threshold that may be selected include a change in DOA estimate between iterations is less than a predetermined value, a certain number of iterations have been completed, a certain amount of time has elapsed, or the angular discriminant is below a certain level. The threshold may be complex, for example continue until one of a plurality of conditions are met, continue until all of a plurality of conditions are met, or continue until a plurality of conditions are met or one or more other conditions are met.
In some embodiments the iterative procedure is applied to determine the maximum signal amplitude at each of the new grid point sets. These maximum amplitudes are then used in an angular discriminant (e.g., as described herein with reference to Equation (8)), which creates an estimate of the angular estimation error. This estimated angular error is then used to control the magnitude of the offset of the grid points.
In some embodiments the antenna elements are configured to optimise the results of CS. Optimisation variables may include one or both of the number of antenna elements and antenna element placement.
For example, in some embodiments the distance between the antenna elements is configured to optimise one or more parameters that affect at least one of the accuracy and convergence rate of CS and iterative CS. In the case of a UCA, a measure of distance between the antenna elements is the radius (equivalently the diameter) of the array. In some embodiments the one or more parameters include or consist of one or both of mutual coherence and condition number of a matrix of actual or simulated measurements from the array of antenna elements for one or more representative signals (e.g., signals of a particular narrow-band wavelength) of interest for DOA estimation, whereby optimisation includes minimising or at least reducing the mutual coherence and/or condition number. In some embodiments, the optimisation is constrained, for example having regard to physical size or shape constraints for the antenna array. In some embodiments, optimisation comprises locating the local minimum of mutual coherence or condition number that is associated with the smallest value for the condition number or mutual coherence respectively.
In some embodiments the antenna elements are odd in number, which at least in some implementations results in a performance improvement relative to an even number of antenna elements. The methods described are however also applicable to an even number of antenna elements. In particular implementations there are an odd number of elements of at least five elements, or at least nine elements. In some embodiments an odd number of antenna elements, particularly at least five, at least seven or at least nine, are used in combination with an optimised distance between antenna elements, for example an optimised radius in a UCA, as described above. In general, a lower number of antenna elements results in reduced computational complexity, but with a potential cost in accuracy.
In some embodiments the measured characteristics of the signal, for example from signal complex voltages represented as a set of complex envelope voltage outputs, obtained at the outputs of antenna elements configured in an array, is a single measurement value (e.g., a single vector of dimension M, representing the voltages from each antenna element). For example, in one embodiment measurements are obtained from all antenna elements at substantially the same time, so as to obtain a single time sample for use in CS. In another embodiment the sampling is repeated a plurality of times and the results are combined, for example by averaging, into a single measurement value. Using an average may statistically improve the accuracy of the DOA estimate. Using a single measurement value reduces the computational complexity for CS.
From the foregoing description, it can be appreciated that the problem of determining the angle of arrival is represented by a relationship, represented by an under-determined set of equations, which map signals origination at each grid point to the set of complex envelope voltage outputs of the antenna elements. Accordingly, the relations from the received signal from the possible grid points to the voltages at the antenna outputs can be represented by a system of equations. An example discussion of this issue is now provided.
A typical realization of the angle of arrival problem is with respect to a planner array of M isotropic omnidirectional elements equally distributed along a circular ring of Uniform Circular Array (UCA) with radius r and angular separation of
radians. The inter-element spacing
is the length of the straight line between two adjacent antenna elements. The angular positions of the antenna elements in UCA are represented by {γm} where
An electromagnetic plane wave impinges on the antenna elements from some unknown DOA θp. The incident signal is considered to be narrow-band and characterized by the same frequency content. The narrow-band assumption states that all frequencies in the observed band have the same phase shift. This simplifies the construction of steering vector given in equation (2). Under the following assumption, the output of mth antenna array can be written as,
and
and, P is the number of impinging waves.
Or in the case of three dimensions:
where,
and,
siinc represents the ith impinging wave
b is the angular wavenumber
r is the radius of the UCA
θi is the aximuth angle of the ith impinging wave
Ψi is the elevation angle of the ith impinging wave
γm is the angular position of the mth element
and,
The phase of τm is the phase shift due to the increased travel distance of the incoming signal in reference to the first element, while it is being received by the mth element of UCA.
Received open-circuit voltage information at each antenna element is combined to formulate a sparse matrix problem, which may be solved using CS techniques to identify the DOA of an unknown target. To incorporate the architecture of CS into the system model, angular space is being quantized into N discrete regions, each region having a representation value, or grid point. SF discretises the entire 2π radian angular domain into N possible DOAs, Θ={{circumflex over (θ)}n, 1≤n≤N} where N denotes the number of grid points. The incoming DOA, θ can be anywhere in the range [−π,π). Using the relationship between output of each antenna elements and DOA of the target in equation (1) and rewriting it in matrix form gives:
and, V={νm, 1≤m≤M} is a one-dimensional column vector representing the complex output at each antenna elements of UCA. Φ(Θ) is the dictionary matrix, where τm ({circumflex over (θ)}n) is calculated using equation (2). In general, Φ(Θ) can be computed for any antenna array geometry, (in 2 or 3-dimensional space) and any set of grid points (in 2 or 3-dimensional space). The iterative algorithm is in this sense universally applicable.
The column Φ(Θ) represents an M-element array response vector, for an incoming plane wave arriving from the direction {circumflex over (θ)}n. The vector S={sninc, 1≤n≤N} is a one-dimensional column vector of size N, where sninc represents the incoming plane wave from the direction {circumflex over (θ)}n. The outputs of antenna elements in equation (3) will be corrupted with a noise vector ηM×1. The entries of ηM×1 are statistically independent and are extracted from a complex Gaussian distribution with zero mean and variance σ2. The effect of noise on the output observation can be expressed as.
V
n=Φ(Θ)S+η (5)
The system defined in (5) is an under-determined set of equations, where M<N, and can be formulated as a CS problem to recover an estimate Ŝ of the original sparse vector S via convex optimization as shown in (1). Therefore
where is the ∥•∥p is the lp norm and ϵ is the regularization parameter that is being determined by the noise or quantization level. Since the model assumes a single transmitting source among the N possible DOAs, the recovered sparse vector will have only one nonzero element. The index n of the non-zero element refers to the angular grid) ({circumflex over (θ)}n) corresponding to the source DOA. Additionally, ϵ can be increased to cater for optimized designed for small antenna geometries, with close spacing between the antenna elements.
An assumption that the source is located on one of the angular grid points may not provide sufficiently accurate DOA estimation for at least some applications. In an ideal situation under this assumption, when the DOA of the source is on the grid, i.e. θ∈: {{circumflex over (θ)}n, 1≤n≤N}, the sparse vector solution discussed above enables detection of the DOA of the source. However, in a typical scenario when the source DOA is off the grid, i.e., θ={circumflex over (θ)}n+Δθ, where
the DOA estimate includes an error. The dictionary mismatch between processed observation Vn and measurement matrix Φ, forces the optimized solution vector S to generate several peaks at neighbouring grid points. In such cases, for an off-grid DOAθ, CS generates peaks at {circumflex over (θ)}k and {circumflex over (θ)}k+1, which are the neighbouring angular grids closest to the original off-grid DOAθ. To address this, the estimation process includes a two-stage strategy, wherein at the first stage, an index corresponding to the maximum amplitude is chosen as a coarse estimation k . The coarse estimate of θ, θ̆0, may be obtained from,
where, Ŝ0[n] is the nth element of the recovered sparse vector after CS processing, and Θ0 represents the set of N discrete azimuth angular grid points.
Assuming the Signal to Noise Ratio (SNR) is relatively high, there is a high probability that
is the angular grid separation. The determination of the course estimate in (7) is followed by an iterative process in the second stage. In the second stage, new grid points are determined, which usefully may be located at ½ the distance between the grid points used for the previous estimated angle of arrival. In one embodiment, two modified sparse vectors Ŝt,1 and Ŝt,2 are recovered by introducing a grid shift of
on the N possible DOAs Θ. In another embodiment, a single new modified vector Ŝt is obtained due to the angular rotation of the grid points by
in one direction. t=1,2,3, . . . is the iteration number. In each iteration the magnitudes of the recovered sparse vector are used to determine a correction factor, which enables the algorithm to converge to an accurate estimate.
The coarse estimate is obtained by obtaining a compressive sensing solution of:
Vn=Φ(Θ0)Ŝo.
In particular, using compressive sensing, Ŝ0 is obtained by:
Ŝ0=min∥S0∥1, such that ∥Vn−Φ(Θo) So∥2<ϵ,
where ∥•∥p is the lp norm of a vector.
Then, nmax=max−1[|Ŝo[n]|: 1≤n≤N] and θ̆o=θ(nmax),
where θ̆ is a coarse (quantized) estimate of the angle of arrival of the signal.
More accurate estimates of the angle of arrival than the initial coarse estimate are obtainable through creating additive correction terms and applying these correction terms to the coarse estimate of the angle of arrival. The determination of the correction terms and the more accurate estimate of the angle of arrival are done in an iterative computational procedure.
For the first step of the iteration, define,
where,
(Q)2π=modulo(Q+πū, 2πū)−πū for any vector Q,
ū is the N×1 vector for which every element is 1.
ΔΘ1 is the correction factor for the first iteration,
D(α1,β1) is an angle of arrival error discriminant based on parameter defined in the following.
Ŝ1′ is solved by using compressive sensing.
Therefore Ŝ1=min∥S1∥1 such that
A correction factor for the phase estimate is computed using the error discriminant,
All of the grid points are rotated by ΔΘ1 which is represented as, Θ1=(Θ0+ΔΘ1ū)2π
and therefore the estimate of the angle of arrival after the t=1 iteration is, θ̆1=Θ1 (nmax)=Θ0(nmax)+ΔΘ1=θ̆0+ΔΘ1
where ΔΘ1 is a correction factor for the coarse estimate θ̆0.
For the second iteration, if required, define
Ŝ1′ is solved using compressive sensing, Ŝ2=min∥S1∥1 such that
A correction factor for the phase estimate is computed using the error discriminant:
All of the grid points are rotated by ΔΘ2, which is represented as: Θ2=(Θ1+ΔΘ2ū)2π=(Θ0+ΔΘ1ū+ΔΘ2ū)2π.
Therefore, the estimate of the angle of arrival after the t=2 iteration is: 2=Θ2(nmax)=Θ1(nmax)+ΔΘ2=0+ΔΘ1+ΔΘ2,
where ΔΘ2 is the additional correction factor on the coarse estimate.
The iterative algorithm almost always converges after the second (t=2) iteration. Accordingly, in some embodiments the number of iterations is fixed at 2. In other embodiments, more than two iterations may be used.
For iteration t:
Ŝt′ is solved by using compressive sensing,
Ŝt=min∥St∥1 such that
A correction factor for the phase estimate is computed using the error discriminant,
All of the grid points are rotated by ΔΘt which is represented as,
and therefore the estimate of the angle of arrival after
the iteration t is,
where, ΔΘt is the correction factor for the coarse estimate after iteration t.
The variables in the description above can be described as follows:
is the angular quantization step size,
is the error discriminant for iteration t,
is the scalar output of the error discriminant for iteration t
(Q)2π=modulo(Q+πū, 2πū)−πū.
This equation describes the 2π modulo operation on each of the elements in Q. By adopting this, a rotation in only one direction (either direction) is required to determine the angular discriminant. In alternative embodiments a rotation of
is used in addition to the rotation
with a corresponding increase in computational resources. In the case of a non-uniform grid of points, ω may differ for each direction, to maintain the rotated position at a half interval to either side of the course estimate.
In an alternative embodiment, an angular discriminant, for example the angular discriminant D(αt,βt) described above, is determined based on a first or initial compressive sensing, for example Vn=Φ(Θ0)Ŝo as described above. In the solution vector Ŝo a maximum term is identified, and the maximum adjacent term is also identified. The angular discriminant is then computed based on the identified maximum term and maximum adjacent term. The grid points are then rotated by the angular discriminant for a first iteration. Subsequent iterations, if any, are performed as described above. If the adjacent terms on both sides of the maximum term are equal, then the estimated angle of arrival is the angle corresponding to the grid point for the maximum.
If there are two equal sized adjacent maxima in a compressive sensing solution, then the estimated angle of arrival is determined as the mid-point of the grid points corresponding to the two maxima.
The initial estimate of the angle of arrival is the angle corresponding to the mid-point between the angles corresponding to the two largest magnitude values of This midpoint is the initial angle of arrival estimate θ̆o
The grid points are then rotated by Θ1=(Θ0+ΔΘ1ū)2π
The alternative embodiment of the algorithm has reduced computational complexity. One compressive sensing solution and one computation of the Φ matrix are eliminated by the alternative embodiment.
In some embodiments, the stopping criterion of the algorithm is determined by a user-defined threshold, for example for a fixed number of iterations or for D(αt,βt)<Ω.
The algorithm terminates at iteration t and t=Θt(nmax).
In some embodiments, a compressive sensing algorithm is used that accommodates pre-determination of the sparsity of the solution vector. For one transmitting source, the sparsity is set to 2, because there will be two significant adjacent elements in the solution vector. In the case of P signal sources, the sparsity is set to 2P . The CoSaMP algorithm is an example algorithm that accommodates predetermination of the sparsity of the solution vector and as such has particular application to the disclosed methods of direction of arrival estimation.
An example discussion of CS is now provided.
Compressive sensing is a mathematical framework that deals with the recovery of a sparse vector xn×1, from an observation vector yn×1 with M<<N. The measurement paradigm consists of linear projection of the signal vector via a known projection matrix ΨM×N. As M<<N, the recovery of sparse vector x from the measurement vector y becomes an underdetermined problem with an infinite number of solutions. In a CS framework, an accurate estimation of a sparse signal x can be obtained in the following reconstruction problem:
min∥x∥1 s.t. ∥y−Ψx∥2≤ζ, (9)
where ∥•∥P is the lp-norm and ζ bounds the amount of noise in the observation data. A vector x is said to be K-sparse, if ∥x∥0=K. A matrix Ψ is said to have satisfied the RIP (Restricted Isometry Property) of order K, if there exists a δk∈(0, 1) such that
(1−δk)∥x∥22≤∥Ψx∥22≤(1+δk)∥x∥22 (10)
If ψ satisfied the above condition, there is a high probability of successfully recovering a sparse signal from noisy measurements, as long as the spark(ψ)>2K. The spark of a matrix is the smallest number of columns in matrix Ψ that are linearly independent. The larger the spark, the bigger the signal space, allowing CS to guarantee exact recovery. Although the spark and the RIP provides guarantees for the recovery of a k-sparse vector, verifying that a matrix satisfies any of the above properties has a combinatorial computation complexity, since each time one must consider
submatrices. Therefore, it is preferable to use a property of a matrix which is easily computable and provides guarantees of recovery.
The mutual coherence of a matrix ψ, μ(Ψ) is the largest absolute inner product between two columns Ψi and Ψj where
Ψi is the i th column of Ψ and Ψj is the j th column of Ψ.
The mutual coherence of a matrix Ψ is always bounded in the range
where the lower bound is known as the Welch Bound. Note that when N>>M, the lower bound is approximately equal to
If the original signal x satisfies the following requirements,
then, CS algorithms such as basis pursuit or other greedy algorithms such as COSAMP can be used to guarantee the recovery of x from under-determined set of equations.
A rectangular matrix such as ΨM×N does not possess quantifiable parameters such as eigenvalues to determine the structure of the matrix. However, Q=ΨTΨ can be considered as a square matrix and the eigenvalues of Q can be related back to quantify the property of Ψ. The singular values ρ1, . . . ρm of a m×n matrix Ψ are the positive square roots, ρi=√
where ρmin and ρmax are the smallest and largest singular value associated with the matrix Ψ. The condition number plays a vital role in providing a geometric interpretation of the action of the matrix. A matrix with lower condition number suggests strong convergence to an accurate and unique solution.
In some embodiments the array of antenna elements is configured to optimise CS. Additionally or alternatively, the number of elements in the array may vary from a conventional approach of an inter-element separation,
between the antenna elements to avoid ambiguity between the steering vectors of distinct DOAs.
Although
has been used as an optimum separation to perform trade-off between mutual coupling and grating lobes, a geometry with
or d>λ or d>2λ or d>3λ or d>4λ or d>5λ may be used with the DOA methods described herein. Also, a geometry with or d>1.5λ or d>2.5λ or d>3.5λ or d>4.5λ or d>5.5λ may be used with the DOA methods described herein. Referring to the example of UCA,
and 10λ with an increment of
In the plot the arrow marked r* refers to a radius of the array such that the inter-element spacing between the antenna elements is
It can be seen that at r* both γ(Φ) and μ(Φ) are significantly higher than at other points and hence is not optimal for an accurate recovery of using CS. An antenna array may be optimised by having a radius such that both γ(Φ) and μ(Φ) are minimized. An optimum radius ropt that contributes to the minimization of γ(Φ) and μ(Φ) may maximize the incoherence between the columns of Φ and efficient utilization of the vector space for CS operation.
In general, an optimum separation of antenna elements in the array is dependent on the number of antenna elements in the array. For example, for a UCA, a radius of about 6λ may be suited to about 9 to 17 antenna elements. A radius of about 8λ may be suited to 19 to 21 antenna elements. In some embodiments, the radius may be selected so that the number of antenna elements is within about 1.5 to 3 times the radius, or within 2 to 3 times the number of antenna elements.
In some embodiments, the distance between the antenna elements may be about 0.5λ. In other embodiments the distance between the antenna elements may be between 1λ and 2λ or between 1λ and 1.5λ or between 1.1λ and 1.5λ.
In some embodiments, the phase information in Vn described above, which is utilised for DOA estimation, is directly indicative of the relative phase between the complex envelopes received at the antenna elements. In other embodiments the phase information in Vn is indicative of the phase of the complex envelope relative to a local oscillator. Using a local oscillator facilitates embodiments with larger signal to noise ratio.
The process flows may be modified to enable DOA estimation in three-dimensional space.
In some embodiments, an estimated angle of arrival in three-dimensional space is determined based on individual determinations for transverse planes. For example, in some embodiments, the candidate directions of arrival are located in a first plane and the estimated direction of arrival is an estimated direction of arrival for that plane. To determine the DOA in three-dimensional space, the method further includes repeating the determinations in respect of candidate angles of arrival located in a second plane having at least a component substantially transverse to the first plane, to determine an estimated direction of arrival for the second plane. An estimated direction of arrival is then based on the estimated direction of arrival for the first and second planes.
In some embodiments, the second plane is perpendicular to the first plane. In some embodiments, the second plane intersects the first plane along a line having a direction corresponding to the first estimated direction of arrival. In some embodiments the method further comprises repeating the determinations in respect of a grid of candidate angles of arrival located in a third plane, the third plane intersecting points on a line in three-dimensional space corresponding to the second estimated direction of arrival. In some embodiments, the method comprises iteratively determining estimated directions of arrival in planes with substantial components transverse to the preceding plane until a threshold minimum variation in estimated direction of arrival is reached.
In some embodiments, the N potential angles of arrival are spatially separated in three-dimensional space, whereby Ŝt for t=0 has solution vector elements for both azimuth and elevation. The method may then comprise applying at least the iterations t=1 and t=2 to determine the azimuth in relation to the largest absolute value adjacent pair of elements with constant elevation and applying at least the iterations t=1 and t=2 to determining the elevation in relation to the largest absolute value adjacent pair of elements with constant azimuth.
A simulation was carried out on N=180 angular grid points, with
The scanning angle ranges between [−π, π) radians. The signal is considered to be transmitted at centre frequency of ƒc MHz, and the wavelength is λ. A simulated UCA consists of 13 isotropic antenna elements distributed evenly on a circular ring with r=ropt=6λ. The inter-element distance d between the antenna elements is approximately 3λ. The simulation scenario has one source, transmitting from any angle in the range between [−π,π) radians. The signals have been supposed to be arriving on the antenna with equal strength in order to perform an unbiased analysis of the accuracy of the method with respect to the angles of arrival.
In order to determine the robustness of the system model, the following noise sensitivity test was considered. The Signal-to-Noise-Ratio (SNR) is calculated at the receiver as the ratio of the sum of the power received from M antenna elements to σ2 where, σ2 is the variance of the complex Gaussian noise. The measured data are characterized by SNRdb=[−10, −5, 0, 5, 10, 15, 20, 25], defined as,
where, νm, m=1, . . . M, is the noiseless complex voltage observation at each antenna element. Since the actual DOA can be placed anywhere in the range [−π,π), T=1000 different scenarios were considered, to give a consistent statistical validation. Compressive Sampling Matching Pursuit (CoSaMP) performs the CS operation. The performance parameter of the algorithm is characterized as Mean Square Error (MSE), where MSE is defined as,
where,
The MSE of the proposed algorithm is compared with the Cramer-Rao Lower Bound (CRB or CRLB), as
A set of results are presented in
Another set of simulations were carried out to examine convergence of the recursive algorithm in achieving the CRLB of DOA estimation.
For SNR of 5 dB or less, the estimates have the same mean square error angle. Above 5 dB the first (course) estimate remains constant at a MSE about 10−4 whereas the first and second iterations perform closer to the CRB, the second iteration converging on the bound for about SNR>10.
COSAMP has a complexity of O(MN) in determining the solution of a sparse vector. The proposed method converges to the bound using just 2 iterations. Compared to Eigen-Value Decomposition (EVD) based DOA estimation such as (MUSIC and Root-MUSIC), the proposed algorithm therefore has much lower computational complexity.
Although the simulation was performed with N=180 for M=13, N may be increased or decreased. A reduction in N reduces computational complexity. For example, N may be reduced to approximately 100, or approximately 50, or approximately 40, or increased to approximately 250, 360 or more. In general, a minimum for N may be determined by the maintenance of sufficient sparsity for CS, which for some implementations may be between about two to three times M, whereas a maximum may be determined computational cost.
In steps 100, 100A a set of complex envelope voltage outputs are received from the antenna element array. These may be stored in transient or non-transient memory for further processing. In step 101, 101A the set of complex envelope voltage outputs are transformed by an orthogonal transform to increase sparsity. Step 101, 101A is omitted in other embodiments. In step 102, 102A CS is applied to the transformed outputs and a grid including a higher number of grid points than measured outputs, to reveal a first DOA estimate, specified by one of the grid points (the DOA grid point). In step 103, 103A two new grids or one new grid is defined, rotated with respect to the first grid. For example, the new grids include grid points that are rotated a half grid quantization interval. In step 104, 104A CS is applied to the new grid(s) and an angular discriminant is determined based on preceding CS solutions. In step 105, 105A a decision is made whether a threshold condition, for example based on the angular discriminant, has been met. If so, the process ends and the latest DOA estimate is used as the final DOA estimate. If not, the process returns to step 103, 103A.
Accordingly, the solutions of the CS operations yield the magnitudes derived from the two shifted sets of grid points, respectively. The magnitudes of the shifted grid points closest in angle to the previous direction of arrival estimate are used as the input to a phase error discriminant. The output of the phase error discriminate is then used to adjust the estimate of the angle of arrival. This process is continued in an iterative manner until the output of the phase error discriminant is below an acceptable, user-defined threshold. On each iteration, the estimate of the angle of arrival improves, until there is negligible discriminate output.
The number of angular grid points for UCA and ULA is set to be NUCA=NULA=180, with grid interval
respectively.
The CRLB for both UCA and ULA are shown. The CRLB of the ULA is lower than that of the UCA. The MSE plots for both the antenna geometries behave in a similar fashion, dipping off at an approximate SNR=6 dB and continuing to be on the CRLBs for higher SNR. For SNR<5 dB, the MSEs are relatively higher than the CRLBs with ULA having a lower MSE than UCA. The high MSE at low SNR regions can be associated with the inaccurate grid estimation of the disclosed algorithm, where the underlying CS operation fails to detect the angular grid on which the source is located.
Embodiments of the iterative compressive sensing direction of arrival estimation algorithm (ICSDOA) described above have significantly less computational complexity than previous algorithms that obtain estimates of the angle of arrival.
MUSIC is the Multiple Signal Classification Algorithm.
Root MUSIC is the Root Multiple Signal Classification Algorithm.
ESPIRIT is the Estimation Signal Parameter via a Rotation Invariant Technique.
Certain embodiments of the MUSIC Algorithm have computational complexity of O(PM2N+M2), where
Certain embodiments of the Root-MUSIC algorithm also have computational complexity O(PM2N+M2).
Certain embodiments of the ESPIRIT Algorithm have computational complexity of O(PM2+M3).
Certain embodiments of MUSIC, Root MUSIC, and ESPIRIT require P to be much greater than 1 for successful operation.
Certain embodiments of the ICSDOA iterative algorithm for the estimation of the angle of arrival has computational complexity of O(3MN), where O(3MN) is for compressive sensing and O(3MN) is for the evaluation of the dictionary matrix Φ. An alternative implementation of the iterative algorithm has computational complexity of O(4MN).
The ICSDOA iterative algorithm has much less computational complexity than at least certain embodiments of MUSIC, Root Music, or ESPIRIT. The iterative algorithm obtains an estimate with only one time sample from the antenna elements. A sequence of output estimates may be further operated upon, if required, with signal processing to produce a reduced error estimate of the angle of arrival.
Further aspects and embodiments of the present disclosure will be apparent from the following description, given by of example to a radio signal. In other example the embodiments are applied to a sound signal. In other examples the embodiments are applied to a phase coherent light signal.
A method for use in a direction of arrival estimation for a radio signal, includes: receiving, at a computational processor, a set of measurements of a radio signal from a radio source taken by an array of antenna elements; generating first and second measures of a direction of arrival estimate, the generating based on first and second grids of potential direction of arrivals respectively, the first and second grids offset from each other; generating an angular discriminant based on the first and second measures; generating third and fourth measures of a direction of arrival estimate, the generating based on third and fourth grids of potential direction of arrivals respectively, the third and fourth grids offset from the first and second measures by an amount based on the angular discriminant.
A method for use in a direction of arrival estimation for a radio signal, includes: receiving, at a computational processor, a set of measurements of a radio signal from a radio source taken by an array of antenna elements; generating, by the computational processor based on the received measurements, a first measure associated with a first direction of arrival estimate for the radio signal, based on a first grid with a plurality of grid points corresponding to potential directions of arrival, the grid comprising a larger number of grid points than antenna elements in the array of antenna elements and a lower resolution of grid points than required to achieve a target accuracy for the direction of arrival estimation; generating, by the computational processor, a second measure associated with a second direction of arrival estimate for the radio signal, based on a second grid comprising grid points around the first direction of arrival estimate that are offset to grid points in the first grid; and determining, by the computational processor, an angular discriminant based on the first measure and the second measure, wherein the measures associated with the direction of arrival estimates are based on a solution to a sparse problem defined by the received set of measurements and the respective grid points.
In some embodiments the set of measurements comprise a single measurement value.
In some embodiments the set of measurements comprises measurements from a circular array. In some implementations the circular array is a uniform circular array.
In some embodiments the set of measurements comprises measurements corresponding to an odd number of antenna elements.
In some embodiments the set of measurements comprises at least 5 measurements, or between 7 and 25 measurements, or between 9 and 23 measurements, or between 9 and 21 measurements, or between 9 and 19 measurements, or between 9 and 17 measurements, or between 9 and 15 measurements.
An antenna array for direction of arrival estimation includes a plurality of antenna elements arranged in a substantially uniform array, each antenna element configured to provide a measurement signal of a radio signal having a base wavelength, wherein a distance between pairs of antenna elements is substantially equal to a distance that minimises at least one of or a combined measure of a mutual coherence and a condition number of a matrix of said measurement signals of a radio signal by the antenna array at the base wavelength.
An antenna array for direction of arrival estimation includes a plurality of antenna elements arranged in a substantially uniform array, each antenna element configured to provide a measurement signal of a radio signal having a base wavelength, wherein a distance between pairs of antenna elements is greater than a distance corresponding to one wavelength at the base wavelength.
In some embodiments the distance between pairs of antenna elements in the antenna array is greater than a distance corresponding to two wavelengths at the base wavelength.
In some embodiments the distance between pairs of antenna element in the array is one half wavelength.
In some embodiment the distance between pairs of antenna elements is less than one wavelength.
In some embodiment the distance between pairs of antenna elements is less than one half wavelength.
In some embodiments the distance between pairs of antenna elements in the antenna array is less than a distance corresponding to ten wavelengths at the base wavelength. In some implementations the distance between pairs of antenna elements is about a distance corresponding to six wavelengths at the base wavelength.
In some embodiments the array comprises an odd number of antenna elements.
In some embodiments the number of antenna elements is at least 5 or at least 7 or at least 9.
In some embodiments the number of antenna elements less than or equal to 15. In other embodiments the number of antenna elements is more than 15.
In some embodiments the antenna array is substantially a uniform circular array.
In some embodiments the antenna array is substantially a uniform linear array.
In some embodiment the antenna array is of a geometry that is neither a uniform linear array nor a uniform circular array.
A radio receiver for direction of arrival estimation includes: an antenna array according to any embodiment described in the preceding paragraphs; and a computational processor configured to receive measurement signals for a radio signal from the antenna array and generate a direction of arrival estimation based on the measurement signals, the direction of arrival estimation utilising compressive sensing.
In some embodiments of the radio receiver, the computational processor is configured to perform the method as described in the preceding paragraphs.
The radio receiver of claim 17 or claim 18, configured to provide a direction of arrival estimate anywhere within the range 0 to 2π.
A method of direction of arrival estimation for a radio signal includes: receiving, at a computational processor, a set of measurements of a radio signal from a radio source taken by an array of antenna elements; generating, by the computational processor based on the received measurements, a direction of arrival estimate for the radio signal, wherein the direction of arrival estimate is based on compressive sensing of a sparse problem defined by a de-correlating transform of the received set of measurements and a grid with a plurality of grid points corresponding to potential directions of arrival, the grid comprising a larger number of grid points than antenna elements in the array of antenna elements.
In some embodiments the set of measurements of a radio signal from a radio source taken by an array of antenna elements, is a set of measurements from a circular array, which may be a uniform circular array.
In some embodiments the set of measurements consists of measurements corresponding to an odd number of antenna elements, for example between 5, 7 or 9 elements and 15 elements.
A method of direction of arrival estimation for a radio signal includes generating, by a computational processor based on received measurements of a radio signal from an antenna element array, a direction of arrival estimate for the radio signal from within a possible range of 0 to 2π, wherein the direction of arrival estimate is based on compressive sensing of a sparse problem defined by the received set of measurements and a grid with a plurality of grid points corresponding to potential directions of arrival, the grid comprising a larger number of grid points than antenna elements in the array of antenna elements.
It will be understood that the invention disclosed and defined in this specification extends to all alternative combinations of two or more of the individual features mentioned or evident from the text or drawings. All of these different combinations constitute various alternative aspects of the invention.
Number | Date | Country | Kind |
---|---|---|---|
2016904419 | Oct 2016 | AU | national |
2016904636 | Nov 2016 | AU | national |
The present application is a continuation of U.S. patent application Ser. No. 16/345,225, filed Apr. 25, 2019, which is a 371 of PCT/AU2017/051189, filed Oct. 27, 2017, which claims priority to Australian patent application 2016904419 filed 28 Oct. 2016 and Australian patent application 2016904636 filed 14 Nov. 2016, the entire contents of which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
Parent | 16345225 | Apr 2019 | US |
Child | 17509543 | US |