This invention relates to radio frequency localization, in some embodiments using synthetic aperture techniques, and in particular relates to use of techniques in which emission from targeted objects are not necessarily synchronous with the receiver and/or emissions from a targeted object to the receiver follow multiple discrete paths, such as direct path and one or more reflected paths.
Synthetic Aperture Radar (SAR) is a technique in which, generally, successive pulses of radio waves are transmitted from a transceiver to “illuminate” a target scene, and the echo of each pulse is received and recorded at the transceiver. The antenna of the transceiver is generally mounted on a moving vehicle, such as a moving aircraft, so that the antenna's location relative to the target changes over time. Signal processing of the recorded radar echoes allows combination of recordings from the multiple antenna locations, thereby forming the synthetic antenna aperture and providing finer resolution image of the illuminated target scene than what would be possible with the given physical antenna at a single location. Note that in such systems, the signal transmitted from the antenna is synchronized with the received echoes by virtue of the transmitting and receiving sections of the system having a common time reference, for example, in the form of a common and relatively stable oscillator (i.e., stable in the time scale of the round trip time of the reflected signals).
Localization of radio frequency reflectors or transmitters (collectively “emitters”) may be complicated by the presence of reflecting structures that cause there to be multiple paths from a target object to a receiver. For example, in indoor localization, reflections from walls may introduce such multipath effects. As another example, in outdoor localization in urban environments, signals may be reflected from buildings causing multipath effects. In some situations, the reflected signals may have higher energy than the direct path from the target to the receiver.
In one aspect, in general, a method is directed to determining a most direct direction of arrival of radio signals. A plurality of radio transmissions are received from a target device. Each radio transmission of the plurality of radio transmissions is received at a plurality of antennas at known locations (but not necessarily the same plurality of antennas for each transmission). Each radio transmission comprises a plurality of components at different transmission frequencies. The received radio transmissions are processed to determine, for each of a plurality of directions of arrival of the radio transmissions, a characterization of a channel from the target device. The characterization of the channel including characterizations of the channel at the different transmission frequencies of the components of the radio transmissions. At least one of the directions of arrival corresponds to a reflected path from the target device to the locations of the antenna. A most direct direction of arrival is determined from the plurality of directions of arrival. This includes computing for each direction of arrival a quantity representing a path length (e.g., a relative path length compared to one or more other directions of arrival) from the target using the characterization of the channel for the direction of arrival at the different transmission frequencies, and comparing said computed quantities to determine the most direct direction.
Aspects can include one or more of the following features.
Comparing the computed quantities to determine the most direct direction comprises selecting the direction of arrival with the smallest relative path length of the plurality of directions of arrival.
The plurality of directions of arrival are determined by processing the received radio transmissions and identifying directions of arrival with local maximum energy over a range of directions of arrival.
The radio transmissions comprise frequency division multiplexed encodings of transmission data. In some examples, the radio transmissions comprise Orthogonal Frequency Division Multiplexed (OFDM) encodings of transmission data.
The received radio transmissions are processed for each of the plurality of directions of arrival. This processing includes determining a phase response of a channel from the target device to a location of the plurality of antennas at each of the different transmission frequencies. In some examples, determining the quantity representing the path length includes determining a quantity characterizing a relationship between the phase response and the frequency at each of the different transmission frequencies, for instance, characterizing rate of change (i.e., slope) of phase response as a function of frequency.
Receiving the plurality of radio transmissions from a target device at the plurality of antennas at known locations includes, for each radio transmission receiving said radio transmission at a first antenna at a fixed location and at a second moving antenna.
Processing the received radio transmissions to determine the characterization of the channel from the target device for each of the plurality of directions of arrival includes combining channel estimates from the target to the first antenna and to the second moving antenna at each of the different transmission frequencies.
Receiving the plurality of radio transmissions from a target device at the plurality of antennas at known locations includes, for each radio transmission receiving said radio transmission at an array of fixed antennas comprising a first antenna and a plurality of other antennas all at fixed locations.
Processing the received radio transmissions to determine the characterization of the channel from the target device for each of the plurality of directions of arrival includes combining channel estimates from the target each antenna of the array of fixed antennas.
Receiving and processing the plurality of radio transmissions from a target device at the plurality of antennas at known locations includes applying a Synthetic Aperture Radar (SAR) approach.
Receiving the plurality of radio transmissions from a target device at the plurality of antennas at known locations includes, for each radio transmission, receiving said radio transmission at a first antenna at a fixed location, and at a second moving antenna.
Processing the received radio transmissions to determine the characterization of the channel from the target device for each of the plurality of directions of arrival includes combining channel estimates from the target to the first antenna and to the second moving antenna at each of the different transmission frequencies.
In another aspect, in general, a localization system is configured to perform all the steps of any of the above methods.
In another aspect, in general, software embodied on a non-transitory machine-readable medium, comprises instructions for causing a processor of a localization system to perform all the steps of any of the above methods.
In another aspect, in general, a localization system includes a plurality of antenna and a receiver coupled to the plurality of antennas for receiving radio signals acquired at the plurality of antennas. The system also includes a signal processor coupled to the receiver configured to processing a plurality radio transmissions from a target radio device to determine a most direct direction of arrival, wherein each radio transmission comprises a plurality of components at different transmission frequencies. The signal processor is configured to processing the received radio transmissions to determine, for each of a plurality of directions of arrival of the radio transmissions, a characterization of a channel from the target device, the characterization of the channel including characterizations of the channel at the different transmission frequencies of the components of the radio transmissions, wherein at least one of the directions of arrival corresponds to a reflected path from the target device to the locations of the antenna, and determining a most direct direction of arrival from the plurality of directions of arrival, including computing for each direction of arrival a quantity representing a path length from the target using the characterization of the channel for the direction of arrival at the different transmission frequencies, and comparing said computed quantities to determine the most direct direction.
In another aspect, in general, a method is used to determine a characterization (e.g., an azimuth and elevation characterizing direction) of a location of the target device. According to this method, a plurality of radio transmissions is received from the target device. Each radio transmission is received at first antenna at a fixed location, and is also received at an antenna at a location other than the fixed location of the first antenna such that the plurality of transmissions are received at a multiple locations other than the fixed location of the first antenna. For each radio transmission, a first channel characteristic for a radio channel from the target device to the first antenna is determined, and a second channel characteristic for a radio channel from the target device to the antenna at the location other than the fixed location of the first antenna is also determined. The first channel characteristics and the second channel characteristics are combined to determine a relative channel characteristic associated with each of the radio transmissions. These relative radio characteristics and the corresponding locations other than the fixed location of the first antenna are combined to determine the characterization of the location of the target device.
Aspects may include one or more of the following features.
Receiving the radio transmission at a location other than the fixed location of the first antenna comprises receiving said transmission at a second moving antenna. The plurality of locations other than the fixed location of the first antenna then comprise a plurality of locations of the second antenna.
The method further comprises causing the second antenna to move along a spatial path (e.g., a circular, linear, or irregular path), and the plurality of locations of the second antenna falling on the spatial path. In some examples, the spatial path comprises a repeated path (e.g., repeated traversals of a circular path).
Receiving the radio transmission at a location other than the fixed location of the first antenna comprises selecting a second antenna from a set of antennas. The plurality of locations other than the fixed location of the first antenna then comprises locations of the selected second antennas.
Each radio transmission comprises a plurality of components at different transmission frequencies. The first channel characteristic, the second channel characteristic, and the relative channel characteristic each comprises channel characteristics corresponding to the different transmission frequencies. In some examples, the radio transmissions comprise frequency division multiplexed encodings of transmission data, for example, the radio transmissions comprise Orthogonal Frequency Division Multiplexed (OFDM) encodings of transmission data.
The method further comprises identifying a plurality of directions of arrival plurality of radio transmissions, at least one of the directions of arrival corresponding to a reflected path from the target device.
The method further comprises identifying a most direct direction of arrival from the plurality of directions of arrival.
Identifying a most direct direction of arrival comprises combining the relative radio characteristics and the corresponding locations of the second antenna to determine a channel characteristic corresponding to each of the plurality of directions of arrival, the channel characteristic representing a variation a phase characteristic across different of the different transmission frequencies.
The method further comprises combining the relative radio characteristics and the corresponding locations of the second antenna to identify a most direct direction of arrival from the plurality of directions of arrival.
The first channel characteristic and the second channel characteristic each comprises a phase characteristic, and the relative channel characteristic comprises a relative phase characteristic.
Determining the directional characterization of location comprises determining a power distribution as a function of direction of arrival. In some examples, determining the directional characterization further comprises identifying a set of one or more directions of peak power of the power distribution.
The target device comprises at least one of a wide area cellular communication device and a wireless local area network device.
Advantages include being able to distinguish between direct and indirect (i.e., reflected) paths in a localization system. For example, in an indoor or an outdoor localization system, reflected paths (e.g., reflecting off walls or buildings) may be identified, even if they have relatively higher power than a direct path.
Applications of the approaches outlined above include identifying the line of sight path for localization of a wireless transmitter based on antenna arrays or SAR. This can be applied, for instance, to localize LTE or WiFi devices.
Other features and advantages of the invention are apparent from the following description, and from the claims.
A number of approaches are described below in the context of localization of radio frequency transmitting devices in an indoor environment in which the transmitting devices are independent of a localization receiver and there are generally multiple reflected paths from the transmitting devices to the receiver. A specific embodiment is described in which the transmitting devices are cellular telephones (e.g., LTE transmission in the 700 MHz-2.6 GHz range) or wireless local area network devices (e.g., IEEE 802.11 standard (“WiFi”) transmission in at 2.4 GHz or 5 GHz). Note that approaches that address the independence of the transmitting devices and the localization receiver and approaches that address multipath effects can be used independently in various applications, and together provide high accuracy in applications such as indoor localization. For reference, the wavelength of a radio signal at 2.4 Ghz and 5.0 Ghz is about 12.5 cm and 6.0 cm, respectively.
A first embodiment is described for two-dimensional localization using directly received signals. A second related embodiment is then described for three-dimensional localization using the same approaches. Further embodiments are then described in which multipath effects are addressed.
As introduced above, conventional Synthetic Aperture Radar (SAR) takes advantage of the feature that the radio signal that is transmitted toward and then reflected from a targeted object is generated by a clock signal that is also used in the processing of the received reflected signal. In particular, the relative phase of the transmitted signal and the received signal can be used to provide range information. In this sense, the emission from a SAR antenna is synchronous with the reception of the echo from the targeted object, thereby providing range information between the location of the transmitter when it emitted the signal to the targeted object and back to the location of the receiver when it received the reflected signal. In the application of localization of independent transmitting devices (e.g., LTE or WiFi devices), the receiver of the emission from the transmitting devices does not share a common clock or oscillator, and therefore the reception of the signal does not provide range information in the same manner as is available in conventional SAR techniques.
Referring to
In general, each target device 150 makes a series of transmissions, for example, each transmission comprising a transmission frame carrying data (e.g., which may include voice data). For example, in an LTE application, each frame may be 10 milliseconds long and WiFi frames are generally shorter than 10 milliseconds. In this embodiment, the moving antenna 111 is moving relatively slowly as compared to the frame length, and is therefore considered stationary for the duration of a frame for the analysis. For example, the rotating antenna 111 may have a rotation radius of 10 centimeters and a rotation period of 0.5 to 2 seconds (30-120 revolutions per minute), and therefore travels only a fraction of a millimeter during a frame transmission time. In LTE, the estimation procedure can be performed at a sub-frame level such that a separate estimate is performed for each sub-frame (e.g., 1 millisecond) and the antenna is only considered to be stationary for the duration of the sub-frame.
Referring to
d1(n)−d0=d(n)=D0−r cos(φT−φR(n)).
The constant term D0 does not vary with φR(n). In the limit that the target device is far from antennas, D0=L cos φT, but as is shown below, the specific value of D0 is not significant. The transmission from the target device is assumed to include a known (complex valued) signal p that is modulated by a carrier, which is represented as the complex exponential exp(jωt). For example, the known signal is a pilot signal or an error corrected data signal. The receiver demodulates the received signal at the antennas with an oscillator that is offset in phase by ψ(n) from the transmitting transmitter. The superscript (n) represents the fact that the receiver does not assume a fixed phase offset between transmissions from the target device. For example, frequency differences may not vary significantly during a single frame but may nevertheless exhibit significant phase drift between transmissions. After demodulation the received signal at moving antenna 111 has a phase offset due to the distance d1(n) as well as the phase difference ψ(n) and the demodulated signal at the fixed antenna 112 has a phase offset due to the distance d0 as well as the phase difference ψ(n). Specifically,
q1=pm1 exp(−j(kd1(n)+ψ(n))), and
q0=pm0 exp(−j(kd0+ψ(n))).
where k=2π/λ=ω/c, and c is the propagation speed of the signal, and m0 and m1 are complex quantities (i.e., representing constant attenuation and phase offset) that do not depend on n. The receiver forms channel estimates using these demodulated values as
h1(n)=q1/p, and
h0(n)=q0/p.
Note that both these channel estimates, h1(n) and h0(n) are affected by the unknown phase offset ψ(n). However, a ratio of the channel differences is only affected by the difference in differences in the distances d(n)=d1(n)−d0
This ratio can be represented as
{tilde over (h)}(n)=h0 exp(−jkr cos(φT−φR(n)))
where h0=(m1/m0)exp(−D0) is a complex quantity, in which D0 depends on φT and L but not on ψ(n) or φR(n).
Combination of N channel estimates {tilde over (h)}(n) at corresponding receiving antenna angles φR(n) then makes use of a computation analogous to that used in SAR receivers, namely
Note that it should be evident that a(n)(φ){tilde over (h)}(n) has a maximum magnitude at φ=φT, as does the summation over the N receptions from the target device. Therefore, with a single transmitting device 150, estimation of the direction of arrival φT is performed by finding the maximum of the computed P(φ).
When there are multiple target devices 150 in the environment, in some embodiments, content of each received frame identifies the source of the transmission. Therefore, the localizing receiver 110 collects transmissions for each target device and records them separately applying the computation of P(φ) independently for each target device.
In general, the moving antenna moves independently of the transmissions being received, for example, rotating at a constant rate. The localizing receiver 110 receives the angle of rotation φR(n) corresponding to each received frame.
In the case of an orthogonal frequency division multiplexed (OFDM) transmission from the target device, essentially a set of transmission frequencies (indexed by f) are present in each transmitted frame from a target device, and a set of channels estimates {tilde over (h)}f(n) are obtained from a received transmission, and separate directional power estimates Pf(φ) may obtained for each frequency. In some implementations, separate direction estimates may be made from each frequency, or alternatively, the power estimates may be combined to determine a single overall direction estimate.
Referring to
r=10 cm with the antenna rotating about a point (0,0)
L=1.0 m such that the fixed antenna is at coordinates (1.0,0.0)
the target device 150 is at coordinates (1.0,3.0) such that φT≈tan−1(3.0)=72°
the operating frequency is 5 GHz, so λ≈6.0 cm.
A simulation in which N=32 observations equally spaced during one rotation of the moving antenna 111 yields P(φ) as illustrated in
A second embodiment makes use of the same arrangement of fixed and moving antennas as illustrated in
d1(n)−d0=d(n)=D0−r sin θT cos(φT−φR(n))
As in the first embodiment, the ratio of the channel estimates can be represented as
{tilde over (h)}(n)=h0 exp(−jkr sin θT cos(φT−φR(n)))
where h0=exp(−jD0) is a complex quantity that depends on φT, θT and L but not on ψ(n) or φR(n).
Combination of N channel estimates {tilde over (h)}(n) at corresponding receiving antenna angles φR(n) then makes use of a computation analogous to that used in SAR receivers, namely
The location of the maximum of P(φ,θ) then provides the direction estimate for (φT,θT).
Note that the approach to computing the directional power distribution, P(φ,θ), shown above (often referred to as a “Bartlett estimator”) can be replaced with other procedures. For instance, a covariance-based and/or eigen-decomposition approach (e.g., a MUSIC, “MUltiple SIgnal Classifier,” algorithm, or ESPRIT, “Estimation of Signal Parameters via Rotational Invariance Technique,” algorithm) can be used to estimate P(φ,θ) from the {tilde over (h)}(n). Therefore, the procedure used to further process P(φ,θ) can be carried out without regard to which approach is used to estimate it.
In the description of the first and second embodiments above, only direct paths 151-152 are considered. In a third embodiment, multiple paths are assumed. Referring back to
are computed as described above, and P(φ) is computed as described above.
Referring to
An approach to estimating the absolute delay of a signal arriving from a particular direction makes use of the signal having components transmitted at different frequencies. In this third embodiment, a set of known signals pf are transmitted at a set of frequencies indexed by f. As introduced above, in one example, an OFDM signal is transmitted in this manner such that signal pf is transmitted with a wave number kf=2π/λf=ωf/c, for example, for integer indices, ωf=ω0+fΔω.
In order to determine relative delay between paths arriving from different directions, in this third embodiment, the SAR approach is used to determine the (complex) response for each direction of arrival. For example, in the example shown in
k=(ω0, . . . , ωF-1)T/c
yields a vector of ideal direct channels
h1=h(φT1)=exp(−jkd1)h1′
where h1′ is the part of the direct channel not explained by the distance d1. Similarly,
h2=h(φT2)=exp(−jkd2)h2′
and the ideal direct channel to the fixed antenna is
h0=exp(−jkd0)h0′.
Therefore, the quantity computed from the N receptions for all the F frequencies
is approximately
Under the assumption that the phase (but not necessarily the magnitude) of the elements of h1′ are equal, and the phase of the elements of h0′ are equal (but not necessarily the same as for h1′), then the phase of {tilde over (h)}1 satisfies
∠{tilde over (h)}1≈−k(d1−d0)+constant.
Therefore because kf=(ω+fΔω)/c, the elements of this phase vector ∠{tilde over (h)}1 vary with a proportionality −Δω(d1−d0)/c (recognizing that phase may need to be “unwrapped” to provide continuity of the phase elements). Similarly, the elements of this phase vector φ{tilde over (h)}2 vary with a slope −Δω(d2−d0)/c. Therefore, if d1<d2, as is the case in this example, the slope for φ=72° is greater than the slope for the path at φ=45°, and therefore the receiver determines that the φ=72° peak in P(φ) corresponds to the direct path (or more generally, the most direct of possibly reflected paths).
In the description of the third embodiment above, the complex response in a particular direction is computed using a SAR technique. However, it should be understood that alternate approaches, including determining the directional responses from a fixed array of antennas that concurrently receive the same signal, can be used to determine the responses that permit discrimination according to travel path length (e.g., direct versus indirect path lengths).
Note that in some examples, only a two dimensional (single direction angle φ) is used. The same approach is applicable in the three dimensional case where peaks in P(φ,θ) are first identified, and then the shortest distance is determined by determining the largest slope in the phase variation over frequencies. Note also, that the frequency components are not necessary uniformly spaced in frequency, and the slope determination can take account of this non-uniform spacing in estimating the slope of the phase variation with frequency.
Therefore, referring back to
In an alternative embodiment, moving antennas at two (or more) different locations and a corresponding fixed antenna for each moving antenna, or a single fixed antenna, are used to determine multiple different directions to each target, and a triangulation approach is used to combine the direction estimates. In yet other examples, a SAR approach is used to directly determine a distribution P(φ,θ,r) where r is the range of the target device. In other embodiments, it is not necessary that the moving antenna or antennas follow circular paths as other repeating of non-repeating (e.g., irregular) patterns of movement of the moving antenna may be used. For example, an antenna may follow a linear path, or may follow an irregular path (e.g., along the path of a vehicle to which it is attached). Furthermore, rather than using one (or a set) of antennas that move, successive selection of different subsets (e.g., selection of successive single) of antennas at different fixed locations can be used. In this way, the mechanical requirements of a moving antenna are essentially replaced with electronic requirements to switch received signals (e.g., at the transmission frequency or at an intermediate or baseband frequency).
Implementations of the approaches described above may use hardware (e.g., application-specific integrated circuits, ASICs), or in software (e.g., using a general purpose processor, a special purpose controller, or a processor in a software defined radio, such as an Ettus Research USRP N210 with a GNU radio), or using a combination of software and hardware. The software includes instructions that are stored on a non-transitory machine readable medium (e.g., semiconductor memory). The hardware, processor, and/or instruction storage can be included within the localizing receiver 110. The system can also include the actuator (e.g., motor) and mechanical linkage required to physically move the antenna as described above. The location (e.g., angle) of the moving antenna can be determined using a sensor (e.g., a rotary encoder) that provides location-indicative measurements to the localizing receiver, or the location (e.g., angle) of the antenna may be inferred according to the commands provided to the actuator.
It is to be understood that the foregoing description is intended to illustrate and not to limit the scope of the invention, which is defined by the scope of the appended claims. Other embodiments are within the scope of the following claims.
This application claims the benefit of U.S. Provisional Application No. 61/921,127, titled “Synthetic Aperture Radar Between Independent Wireless Nodes,” filed Dec. 27, 2013, and U.S. Provisional Application No. 61/921,190, titled “Characterizing Multipath Delays in Antenna Array and Synthetic Aperture Radar Systems,” filed Dec. 27, 2013. The contents of these applications are incorporated herein by reference. This application is also related to U.S. application Ser. No. 14/579,232, titled “Localization with Non-Synchronous Emission and Multipath Transmission,” (attorney docket 70009-D36001) filed concurrently with the present application. This application is incorporated herein by reference.
This invention was made with Government support under Contract No. FA8721-05-C-0002 awarded by the U.S. Air Force. The Government has certain rights in the invention.
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