The present invention relates to location determination using radio frequency signals.
Determining the location and rate of movement of an object within a limited area can benefit a broad range of applications, such as gaming, human machine interface, security, environment awareness, health systems, wireless power transfer, hospitality, and the like. Three dimensional (3D) maps of various entities within an area (for example a room) can be done by determining the distance from an object to a source at different directions.
In a four-dimensional (4D) imaging system, in addition to location information, additional information about the various targets, such as their speed and direction of movement is also obtained. In standard lidar and radar solutions, the distance from the signal source to a remote target is measured by evaluating the time of flight, i.e., the time it takes for the signal to reach the target and travel back to the source of the signal. Therefore, a timing marker on the probing signal is required to enable such measurement. This can be performed as a pulse radar (i.e. amplitude modulation of the radar signal) where a short pulse of radio-frequency signal is transmitted toward the target and its time of flight is measured.
Frequency-modulated continuous-wave (FM-CW) radars and phase-modulated continuous-wave (PM-CW) radars may also be used to determine the distance (range) by evaluating the difference between the frequency of reflected and transmitted signals, when a chirp frequency that linearly increases with time is used as the transmit signal.
However, in such conventional methods, because the range resolution is mainly determined by the bandwidth of the transmitted signal, the modulated signal occupies a significant bandwidth. The bandwidth limitation affects the range resolution.
A method of determining an object's distance, in accordance with one embodiment of the present invention, includes, in part, delivering a first RF signal from a first transmitter to the object, changing the direction of the first transmitter until the first transmitter reaches a first direction defined by a first angle at which the power of the first RF signal as reflected off the object and received by a receiver reaches a maximum value, delivering a second RF signal from a second transmitter to the object, changing the direction of the second transmitter until the second transmitter reaches a second direction defined by a second angle at which the power of the second RF signal as reflected off the object and received by the receiver reaches a maximum value, and determining the distance between the object and the first transmitter using the distance between the two transmitters, the second angle, and the difference between the first and second angles.
In one embodiment, the method further includes, in part, determining the distance between the object and the second transmitter using the distance between the two transmitters, the first angle, and the difference between the first and second angles.
In one embodiment, the method further includes, in part, determining the distance between the object and the receiver using the distance between the two transmitters, the first and second angles, the difference between the first and second angles, and the distance between the receiver and each of the first and second transmitters. In one embodiment, the first transmitter, the second transmitter and the receiver are positioned along a substantially straight line.
In one embodiment, the direction of the first transmitter is changed by mechanically rotating the transmitter. In one embodiment, the direction of the first transmitter is changed by changing the phases of a multitude of transmit/antenna elements of a phased array. In one embodiment, the direction of the first transmitter is changed by changing phases of a multitude of transmit/antenna elements of a first subarray of a phased array, and the direction of the second transmitter is changed by changing phases of a multitude of transmit/antenna elements of a second subarray of the phased array.
In one embodiment, the method further includes, in part, deactivating the second transmitter while delivering the first RF signal, and deactivating the first transmitter while delivering the second RF signal. In one embodiment, the receiver is a Doppler receiver adapted to detect a difference between the frequency of the first RF signal and the frequency of the RF signal as reflected by the object to determine the speed of the object.
A method of determining an object's distance, in accordance with one embodiment of the present invention, includes, in part, delivering an RF signal from a transmitter to the object, changing the direction of the first transmitter until the first transmitter reaches a first direction defined by a first angle at which the power of the RF signal as reflected off the object reaches a first maximum value at a first receiver, and at which the power of the RF signal as reflected off the object reaches a second maximum value at a second receiver, and determining the distance between the object and the transmitter using the distance between the transmitter and the first receiver, the distance between the transmitter and the second receiver, and the first angle.
In one embodiment, the first receiver, the second receiver and the transmitter are positioned along a substantially straight line. In one embodiment, the first receiver is positioned substantially near the transmitter. In one embodiment, the first and second receivers are Doppler receivers.
A method of determining an object's distance, in accordance with one embodiment of the present invention, includes, in part, delivering a first RF signal from a first transmitter to the object, changing the direction of the first transmitter along both azimuth and elevation until the first transmitter reaches a first direction defined by first and second angles at which the power of the first RF signal as reflected off the object and received by a receiver reaches a maximum value, delivering a second RF signal from a second transmitter to the object, changing the direction of the second transmitter along both azimuth and elevation until the second transmitter reaches a second direction defined by third and fourth angles at which the power of the second RF signal as reflected off the object and received by the receiver reaches a maximum value, and determining the distance between the object and the first transmitter using the distance between the two transmitters, and the first, second, third and fourth angles.
In one embodiment, the method further includes, in part, determining the distance between the object and the second transmitter using the distance between the two transmitters, and the first, second, third and fourth angles. In one embodiment, the method further includes, in part, determining the distance between the object and the receiver using the distance between the two transmitters, the distance between the first transmitter and the receiver, and the first, second, third and fourth angles.
In one embodiment, the first transmitter, the second transmitter and the receiver are positioned along a substantially straight line. In one embodiment, the method further includes, in part, deactivating the second transmitter while delivering the first RF signal, and deactivating the first transmitter while delivering the second RF signal. In one embodiment, the receiver is a Doppler receiver.
A method of determining an object's distance, in accordance with one embodiment of the present invention, includes, in part, delivering a first RF signal from a transmitter to the object, changing the direction of the first transmitter until the first transmitter reaches a first direction defined by first and second angles at which angles the power of the first RF signal as reflected off the object reaches a first maximum value at a first receiver, and at which angles the power of the first RF signal as reflected off the object reaches a second maximum value at a second receiver, and determining the distance between the object and the transmitter using the distance between the transmitter and the first receiver, the distance between the transmitter and the second receiver, and the first and second angles.
A mapping system, in accordance with one embodiment of the present invention, includes, in part, a first transmitter adapted to deliver a first RF signal to an object, a second transmitter adapted to deliver a second RF signal to the object, a receiver, and a controller configured to change the direction of the first transmitter until the first transmitter reaches a first direction defined by a first angle at which the power of the first RF signal as reflected off the object and received by the receiver reaches a maximum value. The controller is further configured to change the direction of the second transmitter until the second transmitter reaches a second direction defined by a second angle at which the power second RF signal as reflected off the object and received by the receiver reaches a maximum value. The controller is further configured to determine the distance between the object and the first transmitter using the distance between the two transmitters, the second angle and the difference between the first and second angles.
In one embodiment, the controller is further configured to determine the distance between the object and the second transmitter using the distance between the two transmitters, the first angle, and the difference between the first and second angles.
In one embodiment, the controller is further configured to determine the distance between the object and the receiver using the distance between the two transmitters, the first and second angles, the difference between the first and second angles, and the distance between the receiver and each of the first and second transmitters.
In one embodiment, the first transmitter, the second transmitter, and the receiver are positioned along a substantially straight line. In one embodiment, the controller is further configured to change the direction of the first transmitter by mechanically rotating the transmitter. In one embodiment, the first transmitter is a phased array transmitter. In one embodiment, the first transmitter is a first subarray of a phased array transmitter, and the second transmitter is a second subarray of the phased array transmitter. In one embodiment, the controller is further configured to deactivate the second transmitter while the first transmitter delivers the first RF signal, and deactivate the first transmitter while the second transmitter delivers the second RF signal. In one embodiment, the receiver is a Doppler receiver.
A mapping system, in accordance with one embodiment of the present invention, includes, in part, a transmitter adapted to deliver a first RF signal to an object, first and second receivers, and a controller configured to change the direction of the first transmitter until the first transmitter reaches a first direction defined by a first angle at which the power of the RF signal as reflected off the object reaches a first maximum value at the first receiver, and at which the power of the RF signal as reflected off the object reaches a second maximum value at the second receiver. The controller is further configured to determine the distance between the object and the transmitter using the distance between the transmitter and the first receiver, the distance between the transmitter and the second receiver, and the first angle.
In one embodiment, the first receiver, the second receiver and the transmitter are positioned along a substantially straight line. In one embodiment, the first receiver is positioned substantially near said transmitter. In one embodiment, the first and second receivers are Doppler receivers.
A mapping system, in accordance with one embodiment of the present invention, includes, in part, a first transmitter adapted to deliver a first RF signal to an object, a second transmitter adapted to deliver a second RF signal to the object, a receiver, and a controller configured to change the direction of the first transmitter along both azimuth and elevation until the first transmitter reaches a first direction defined by first and second angles at which the power of the first RF signal as reflected off the object and received by the receiver reaches a maximum value. The controller is further configured to change the direction of the second transmitter along both azimuth and elevation until the second transmitter reaches a second direction defined by third and fourth angles at which the power of the reflected RF signal as reflected off the object and received by the receiver reaches a maximum value. The controller is further configured to determine the distance between the object and the first transmitter using the distance between the two transmitters, and the first, second, third and fourth angles.
In one embodiment, the controller is further configured to determine the distance between the object and the second transmitter using the distance between the two transmitters, and the first, second, third and fourth angles. In one embodiment, the controller is further configured to determine the distance between the object and the receiver using the distance between the two transmitters, the distance between the first transmitter and the receiver, and the first, second, third and fourth angles.
In one embodiment, the first transmitter, the second transmitter and the receiver are positioned along a substantially straight line. In one embodiment, the controller is further configured to deactivate the second transmitter while the first transmitter delivers the first RF signal, and deactivate the first transmitter while the second transmitter delivers the second RF signal. In one embodiment, the receiver is a Doppler receiver.
A mapping system, in accordance with one embodiment of the present invention, includes, in part, a transmitter adapted to deliver a RF signal to an object, first and second receivers, and a controller configured to change the direction of the first transmitter until the first transmitter reaches a first direction defined by first and second angles at which the power of the RF signal as reflected off the object reaches a first maximum value at the first receiver, and at which the power of the RF signal as reflected off the object reaches a second maximum value at the second receiver. The controller is further configured to determine the distance between the object and the transmitter using the distance between the transmitter and the first receiver, the distance between the transmitter and the second receiver, and the first and second angles.
In accordance with one embodiment of the present invention, the range of stationary and moving objects are determined using continuous-wave radio frequency to form 3D and/or 4D maps while consuming minimal signal bandwidth. To achieve this, embodiments of the present invention use parallax, defined herein as the angular difference resulting from viewing an object from different lines of sight. In a 3D/4D mapping context and in its simplest case, the angular difference may be attained via a displacement either between at least two receivers (RX) that capture a reflected signal at two slightly different angles, or between at least two transmitters (TX) whose radiated signals arrive at the target at two slightly different angles.
To determine the range of target 15 and generate a 3D/4D map, while one of the transmitters is activated to scan the environment, the other transmitter is deactivated. For example, when transmitter 10 is activated to scan the environment, transmitter 12 remains deactivated. Conversely, when transmitter 12 is activated to scan the environment, transmitter 10 is deactivated.
During an active scan by either of the two transmitters, the strength of the signal reflected by target 15 and captured (or received) by receiver 20 is at a maximum value when the active transmitter's beam is pointed toward the target. For example, assume transmitter 10 is activated to be in a scan mode so as to scan the environment, while transmitter 12 is off. The signal received by receiver 20 as a result of the reflection from target 15 reaches a maximum value when the beam radiated from transmitter 10 is pointed directly toward target 15. Therefore, in accordance with one aspect of the present invention, the beam direction θ1 of transmitter 10 giving rise to the maximum received signal by receiver 20 is used as one of the parameter in determining the range of target 15.
Similarly, the signal received by receiver 20—as a result of the reflection by target 15 of the signal transmitted by transmitter 12 when transmitter 10 is off—reaches a maximum value when the beam radiated from transmitter 12 is pointed directly toward target 15. The beam direction θ2 of transmitter 12 giving rise to the maximum received signal by receiver 20 is also used as a parameter in determining the range of target 15.
The two angles θ1 and θ2, obtained as described above, define the parallax angle Δθ=θ1−θ2. Using the geometry of the arrangement, these two angles are then used to calculate the range of target 15 from transmitters 10, 12 and receiver 20, as described further below. Applying the law of sines to the triangle formed by transmitters 10, 12, and the target 15 yields the following:
Distances R1 and R2, i.e. the range from transmitters 10, 12 to the target, respectively, are obtained as:
Knowing R1 and R2, distance R0 between receiver 20 and target 15 is calculated by applying the law of cosines to either the triangle formed by receiver 20, transmitter 10 and target 15, or the triangle formed by receiver 20, transmitter 12 and target 15:
Distance R0 is thus determined as shown below:
In one embodiment, target 15 is an active target that includes circuitry for receiving the RF signals transmitted by the transmitters 10, 12, and modulating and/or encoding the signal that target 15 subsequently transmits to receiver 20 to help determine the distances computed by the computer.
Referring to
To determine the range of target 15 so as to generate a 3D/4D map, while one of the transmitters is activated to scan the environment, the other transmitter is deactivated. For example, when transmitter 10 is activated to scan the environment, transmitter 12 remains deactivated. Conversely, when transmitter 12 is activated to scan the environment, transmitter 10 is deactivated.
During an active scan by either of the two transmitters, the strength of the signal received by target (or mobile device) 15 is at a maximum value when the active transmitter's beam is pointed toward the target. For example, assume transmitter 10 is activated to be in a scan mode so as to scan the environment, while transmitter 12 is off. The signal received by target 15 reaches a maximum value when the beam radiated from transmitter 10 is pointed directly toward target 15. Target 15 is adapted to transmit the maximum power it receives from transmitter 10 when transmitter 10 is in a scan mode. Therefore, in accordance with one aspect of the present invention, the beam direction θ1 of transmitter 10 giving rise to the maximum received signal by target 15 is used as one of the parameter in determining the range of target 15.
Similarly, the signal received by target 15—as a result of the transmission by transmitter 12 when transmitter 10 is off—reaches a maximum value when the beam radiated from transmitter 12 is pointed directly toward target 15. Target 15 is adapted to transmit the maximum power it receives from transmitter 12 when transmitter 12 is in a scan mode. The beam direction θ2 of transmitter 12 giving rise to the maximum received signal by target 20 is also used as a parameter in determining the range of target 15.
The two angles θ1 and θ2, obtained as described above, define the parallax angle Δθ=θ1−θ2. Using the geometry of the arrangement, these two angles are then used to calculate the range of target 15 from transmitters 10, 12, as described further below. Applying the law of sines to the triangle formed by transmitters 10, 12, and the target 15 yields the following:
Distances R1 and R2, i.e. the range from transmitters 10, 12 to the target, respectively, are obtained as:
To determine the range of target 15 and generate a 3D/4D map, while one of the transmitters is activated to scan the environment, the other transmitter is deactivated. The scanning of the environment by the transmitters is carried out in both elevation and azimuth directions. For example, when two-dimensional transmitter 30 is activated to scan the environment, transmitter 32 remains deactivated. Conversely, when transmitter 12 is activated to scan the environment, transmitter 10 is deactivated.
During an active scan by either of the transmitters, the strength of the signal reflected by target 15 and captured by receiver 20 is at a maximum value when the active transmitter's beam is pointed toward the target. For example, assume transmitter 30 is in a scan mode to scan the environment while transmitter 32 is off. The signal received by receiver 20 as a result of the reflection from target 15 reaches a maximum value when the beam radiated from transmitter 30 is directed at {θ=θ1, φ=φ1}, as shown. Similarly, the signal received by receiver 20 as a result of the reflection by target 15 of the signal transmitted by transmitter 32 when transmitter 30 is off, reaches a maximum value when the beam radiated from transmitter 32 is directed at {θ=θ2, φ=φ2}, as shown. Using these measured values and by taking advantage of the placement of the transmitters and receiver, values of sin α1, cos α1, sin α2, cos α2, and sin(α1−α2) may be calculated as shown below:
Therefore, distances R1, R2 and R0 may be determined using the following expressions:
In one embodiment, target 15 is an active target that includes circuitry for receiving the RF signals transmitted by the transmitters 30, 32, and modulating and/or encoding the signal that target 15 subsequently transmits to receiver 20 to help determine the distances computed by the computer.
To determine the range of target 15 and generate a 3D/4D map, while one of the transmitters is activated to scan the environment, the other transmitter is deactivated. The scanning of the environment by the transmitters is carried out in both elevation and azimuth directions. For example, when two-dimensional transmitter 30 is activated to scan the environment, transmitter 32 remains deactivated. Conversely, when transmitter 12 is activated to scan the environment, transmitter 10 is deactivated.
During an active scan by either of the transmitters, the strength of the signal reflected by target 15 is at a maximum value when the active transmitter's beam is pointed toward the target. For example, assume transmitter 30 is in a scan mode to scan the environment while transmitter 32 is off. The signal received by target 15 reaches a maximum value when the beam radiated from transmitter 30 is directed at {θ=θ1, φ=φ1}, as shown. Target 15 is adapted to transmit the maximum power it receives from transmitter 30 while transmitter 30 is in a scan mode. Similarly, the signal received by target 15 reaches a maximum value when the beam radiated from transmitter 32 is directed at {θ=θ2, φ=φ2}, as shown. Target 15 is adapted to transmit the maximum power it receives from transmitter 32 while transmitter 32 is in a scan mode. Therefore the direction of the beam radiated by transmitter 30 and defined by angles {θ=θ1, φ=φ1}, and which corresponds to the maximum power received by target 15 and communicated back to transmitter 30 is determined. Similarly, the direction of the beam radiated by transmitter 32 and defined by angles {θ=θ2, φ=φ2}, and which corresponds to the maximum power received by target 15 and communicated back to transmitter 32 is determined. Using these measured values and by taking advantage of the placement of the transmitters, values of sin α1, cos α1, sin α2, cos α2, and sin(α1−α2)may be calculated as shown below:
Therefore, distances R1, R2 and may be determined using the following expressions:
To determine the range of target 15, as transmitter 10 scans the area by sweeping the angle θ, the signals received by receivers 20 and 22 both reach maximum values when angle θ reaches a specific value shown in
where PTX represents the power of the signal transmitted by transmitter 10, GTX(θ) represents the gain pattern of the transmitter 10 antenna, and σ(θ) represents the radar cross-section of target 15.
Assuming, R0>>D, then both θ1 and θ2 may be approximated by θ0, and σ(θ1)=σ(θ2)=σ(θ0). Due to the arrangement of the receivers, transmitter and the target shown in
By using Taylor expansion of GRX(θ)cos2 θ around θ=θ0, the following is achieved:
Therefore, the difference between the two received signals PRX
The average of the two received signals PRX
In the immediately above equation,
represents the signal strength received by a hypothetical receiver positioned at the same location as transmitter 10.
Assuming that target 15 is positioned sufficient far from the mapping system such that condition (R0>>D) is satisfied if |D1−D2|<<D then (θ1−θ0)≈(θ0−θ2), as a consequence of which the following expression is obtained:
(PRX
Therefore, by dividing the difference (PRX
where the only unknown is the parallax angle difference Δθ=θ1−θ2. Therefore, the above equation directly relates the measured power of the reflected signal received by the two receivers to the parallax angle. Accordingly, by determining Δθ, the range R0 of the target from transmitter 10 may be readily determined using the following:
If D1=D2=D/2, the above equation may be simplified to:
In one embodiment, target 15 is an active target that includes circuitry for receiving the RF signals transmitted by transmitter 10, and modulating and/or encoding the signal that target 15 subsequently transmits to receivers 20, 22 to help determine the distances computed by the computer.
Parameter P0, defined above, may be calculated as:
Therefore θ2, and consequently Δθ=θ1−θ2, may be calculated as shown below:
Accordingly, the range, R1=R0, may be obtained as shown below:
The signals received at receivers 40, 42, namely signals PRX
By transforming variables θ and φ to new variables α and β, as shown in
As is seen from
These equations may be used to transform the known gain pattern of the receiver units GRX(θ,φ)—defined in terms of angles θ,φ—to a gain pattern ĜRX(α,β)—defined in terms of angles α and β. Using this transformation, the following is obtained:
This equation provides the parallax angle, Δα=α1−α2, which in turn, provides the range, as shown below:
If transmitter 10 is placed at exactly the midpoint between receivers 40, 42, i.e., D1=D2=D/2. the above equations simplifies to:
In one embodiment, target 15 is an active target that includes circuitry for receiving the RF signals transmitted by transmitter 10, and modulating and/or encoding the signal that target 15 subsequently transmits to receivers 40, 42 to help determine the distances computed by the computer.
Conventional CW radars often use the Doppler shift to detect a moving target's radial velocity. Embodiments of the present invention, described above, may also be used to determine the range of moving objects by measuring the reflected signal while also detecting the velocity using the Doppler shift.
In a manner similar to embodiment 300 described above with reference to
The range of the target from transmitter 10 may then be obtained using the following expression:
In one embodiment, target 15 is an active target that includes circuitry for receiving the RF signals transmitted by transmitter 10, and modulating and/or encoding the signal that target 15 subsequently transmits to receivers 20, 22 to help determine the distances computed by the computer.
Each transmitter scans the area when the other transmitter is off and finds the direction at which the maximum Doppler signal is captured by the receiver, thereby to determine angles θ1 and θ2, as shown. The range may then be determined as shown below:
In one embodiment, target 15 is an active target that includes circuitry for receiving the RF signals transmitted by transmitters 10, 12, and modulating and/or encoding the signal that target 15 subsequently transmits to receivers 20 to help determine the distances computed by the computer.
Any number of techniques may be used to form a transmitter/scanner and implement the required displacement between two transmitter units. In one embodiment, shown in
In another embodiment, each transmitter/scanner may be a phased array having multiple transmit elements/antennas which electronically controls the direction of the radiated beam by varying the relative phases of each antenna element to scan the entire desired area.
In accordance with yet another embodiment, each transmitter/scanner may be a sub-array of a phased array having multiple transmit elements/antennas. Each sub-array steers its beam electronically and independent of the other sub-array. The effective displacement required for parallax is equal to the distance between the centers of the sub-arrays. Figure IOC shows an exemplary phased arrays 60 having a two-dimensional arrays of 3×14 transmit elements/antennas. Phased array 60 is shown as being divided into 2 subarrays, 62 and 64, each having a two-dimensional array of 3×7 transmit elements/antennas. The distance between the centers of the two subarrays is shown as being equal to D.
The above embodiments of the present invention are illustrative and not limitative. Other additions, subtractions or modifications are obvious in view of the present disclosure and are intended to fall within the scope of the appended claims.
The present application claims benefit under 35 USC 119(e) of U.S. Application Ser. No. 62/613,704, filed Jan. 4, 2018, the content of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
---|---|---|---|
62613704 | Jan 2018 | US |