PHASED-ARRAY DOPPLER RADAR USING AN INJECTION-LOCKING TECHNIQUE

Abstract

A phased-array Doppler radar includes a two-way splitter, a transmit antenna, a receive antenna array, an ILO, a demodulation unit and a digital signal processing unit. A reference signal is split by the two-way splitter to the transmit antenna for transmission to targets and the ILO for injection locking. Signals reflected by the targets are received by the receive antenna array as received signals. An injection-locked signal generated by the ILO and the received signals received by the receive antenna array are delivered to the demodulation unit. The received signals are demodulated into baseband I/Q signals by the demodulation unit that uses the injection-locked signal as a local oscillator signal. The baseband I/Q signals are processed by the digital signal processing unit to obtain a digital beamforming pattern.

Claims

1. A phased-array Doppler radar comprising: a two-way splitter configured to receive and split a reference signal into two parts; a transmit antenna electrically connected to the two-way splitter and configured to transmit one part of the reference signal to an area as a transmitted signal, a plurality of reflected signals is reflected from the area; a receive antenna array configured to receive the plurality of reflected signals as a plurality of received signals; an injection-locked oscillator (ILO) electrically connected to the two-way splitter, the ILO is configured to receive and be injected with the other part of the reference signal and configured to generate an injection-locked signal; a demodulation unit electrically connected to the receive antenna array and the ILO, the demodulation unit is configured to receive the plurality of received signals and the injection-locked signal and configured to demodulate the plurality of received signals into a plurality of baseband I/Q signals by using the injection-locked signal as a local oscillator signal; and a digital signal processing unit electrically connected to the demodulation unit, the digital signal processing unit is configured to receive and process the plurality of baseband I/Q signals to obtain a digital beamforming pattern.

2. The phased-array Doppler radar in accordance with claim 1, wherein the reference signal is a radio signal that is configured to be delivered from a radio communication device to the two-way splitter via wire or wireless transmission.

3. The phased-array Doppler radar in accordance with claim 1, wherein the receive antenna array includes a plurality of receive antennas that are configured to receive the plurality of reflected signals as the plurality of received signals, the receive antenna array is configured to be placed horizontally.

4. The phased-array Doppler radar in accordance with claim 3, wherein the demodulation unit includes a multi-way splitter and a plurality of quadrature demodulators, the multi-way splitter that has a plurality of output ports is electrically connected to the ILO and configured to receive and split the injection-locked signal into a plurality of parts, each of the plurality of quadrature demodulators is electrically connected to one of the plurality of receive antennas and one of the plurality of output ports of the multi-way splitter and configured to receive one of the plurality of received signals and one of the plurality of parts of the injection-locked signal, each of the plurality of quadrature demodulators is further configured to demodulate one of the plurality of received signals using one of the plurality of parts of the injection-locked signal as the local oscillator signal into one of the plurality of baseband I/Q signals.

5. The phased-array Doppler radar in accordance with claim 4, wherein the digital beamforming pattern is derived from the following equation: $P\left(\varphi \right)=\underset{n=0}{\overset{N-1}{.Math.}}{S}_n{e}^{j\frac{2\pi }{\lambda }\left({\mathrm{nd}}_r\cos \varphi \right)}$ where P(ϕ) is the digital beamforming pattern as a function of azimuth angle ϕ, N is the number of the plurality of receive antennas, S.sub.n is the nth one of the plurality of baseband I/Q signals in digital complex form, λ is a wavelength of the plurality of received signals, and d.sub.τ is a distance between two adjacent ones of the plurality of receive antennas.

6. The phased-array Doppler radar in accordance with claim 5, wherein the digital signal processing unit is configured to extract vital signs of at least one target in the area from the digital beamforming pattern.

7. The phased-array Doppler radar in accordance with claim 1 comprising a plurality of transmit antennas forming a transmit antenna array and a switch, wherein the switch is electrically connected to the two-way splitter to receive one part of the reference signal, the plurality of transmit antennas are electrically connected to the switch to transmit one part of the reference signal via the switch to the area as the transmitted signal. The transmitted signal is transmitted from different ones of the plurality of transmit antennas at different times.

8. The phased-array Doppler radar in accordance with claim 7, wherein the transmit antenna array is configured to be placed vertically, the digital beamforming pattern is derived from the following equation: $P\left(\theta ,\varphi \right)=\underset{m=0}{\overset{M-1}{.Math.}}\underset{n=0}{\overset{N-1}{.Math.}}{S}_{\mathrm{mn}}{e}^{j\frac{2\pi }{\lambda }\left({\mathrm{md}}_t\cos \theta +{\mathrm{nd}}_r\cos \varphi \right)}$ where P (θ, ϕ) is the digital beamforming pattern as a function of elevation angle and azimuth angle, S.sub.mn is the nth one of the plurality of baseband I/Q signals in digital complex form during the transmission period of the mth one of the plurality of transmit antennas, and d.sub.t is a distance between two adjacent ones of the plurality of transmit antennas.

9. The phased-array Doppler radar in accordance with claim 8, wherein the digital signal processing unit is configured to construct images of different parts of at least one target in the area from the digital beamforming pattern.

Description

DESCRIPTION OF THE DRAWINGS

[0007] FIG. 1 is a circuit diagram illustrating a phased-array Doppler radar in accordance with a first embodiment of the present invention.

[0008] FIG. 2 shows a digital beamforming pattern produced by the phased-array Doppler radar in accordance with the first embodiment of the present invention.

[0009] FIGS. 3a to 3c show the detected vital signs of different targets using the phased-array Doppler radar in accordance with the first embodiment of the present invention.

[0010] FIG. 4 is a circuit diagram illustrating a phased-array Doppler radar in accordance with a second embodiment of the present invention.

[0011] FIG. 5 is a diagram illustrating an equivalent two-dimensional phased array in accordance with the second embodiment of the present invention.

[0012] FIG. 6 shows the detected image of the target using the phased-array Doppler radar in accordance with the second embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0013] FIG. 1 is a circuit diagram illustrating a phased-array Doppler radar 100 in accordance with a first embodiment of the present invention. The phased-array Doppler radar 100 includes a two-way splitter 110, a transmit antenna 120, a receive antenna array 130, an injection-locked oscillator (ILO) 140, a demodulation unit 150 and a digital signal processing unit 160. In this embodiment, the receive antenna array 130 is placed horizontally.

[0014] The two-way splitter 110 of the first embodiment receives and divides a reference signal S.sub.ref into two parts. The reference signal S.sub.ref is preferably received by the two-way splitter 110 from a radio communication device 170 so that it contains communication information. For instance, the reference signal S.sub.ref is a Wi-Fi signal from a mobile device or an access point and is received by the two-way splitter 110 via wire or wireless transmission.

[0015] The transmit antenna 120 is electrically connected to the two-way splitter 110 to transmit one part of the reference signal S.sub.ref to an area A as a transmitted signal S.sub.T. There is (are) a (multiple) target(s) O in the area A, and a plurality of reflected signals S.sub.R are reflected from the target(s) O. The receive antenna array 130 includes a plurality of receive antennas 131 that are provided to receive the plurality of reflected signals S.sub.R as a plurality of received signals S.sub.r1˜S.sub.rN. While the target(s) O has (have) movements with respect to the transmit antenna 120, the plurality of received signals S.sub.r1˜S.sub.rN contains the Doppler phase shifts caused by the movements of the target(s) O.

[0016] The ILO 140 is electrically connected to the two-way splitter 110 to receive and be injected with the other part of the reference signal S.sub.ref so that it enters an injection-locked state and thus outputs an injection-locked signal S.sub.IL. The reference signal S.sub.ref, if delivered from the radio communication device 170, may contain a phase modulation component. The ILO 140 under the injection-locked state is equivalent to a cascade of a bandpass filter and a phase-modulation amplifier, which amplifies the phase modulation component of the reference signal S.sub.ref within an injection-locking bandwidth of the ILO 140. The injection-locking bandwidth of the ILO 140 is usually very small so most of the phase modulation component of the reference signal S.sub.ref is filtered out. Therefore, the injection-locked signal S.sub.IL functions as a local oscillator signal with low phase variation for demodulating the plurality of received signals S.sub.r1˜S.sub.rN.

[0017] The demodulation unit 150 of the first embodiment includes a multi-way splitter 151 and a plurality of quadrature demodulators 152. The multi-way splitter 151 has a plurality of output ports and it is electrically connected to the ILO 140 to receive and split the injection-locked signal S.sub.IL into a plurality of parts. Each of the plurality of quadrature demodulators 152 is electrically connected to one of the plurality of receive antennas 131 to receive one of the plurality of received signals S.sub.r1˜S.sub.rN and also electrically connected to one of the plurality of output ports of the multi-way splitter 151 to receive one of the plurality of parts of the injection-locked signal S.sub.IL. The number of the plurality of quadrature demodulators 152 is the same as that of the plurality of receive antennas 131 and also that of the plurality of output ports of the multi-way splitter 151. Each of the plurality of quadrature demodulators 152 is provided to demodulate one of the plurality of received signals S.sub.r1˜S.sub.rN using one of the plurality of parts of the injection-locked signal S.sub.IL as the local oscillator signal into one of a plurality of baseband I/Q signals I.sub.1/Q.sub.1˜I.sub.N/Q.sub.N.

[0018] Preferably, the plurality of received signals S.sub.r1˜S.sub.rN and the injection-locked signal S.sub.IL are amplified by amplifiers. Moreover, since the plurality of received signals S.sub.r1˜S.sub.rN contains the Doppler phase shifts caused by the movements of the target(s) O and the phase modulation component of the reference signal S.sub.ref, the mixing operation of the plurality of received signals S.sub.r1˜S.sub.rN with the plurality of parts of the injection-locked signal S.sub.IL in the demodulation unit 150 cancels the phase modulation component within the injection-locking bandwidth. Therefore, the plurality of baseband I/Q signals I.sub.1/Q.sub.1˜I.sub.N/Q.sub.N contains the Doppler phase shifts caused by the movements of the target(s) O and the phase modulation component outside the injection-locking bandwidth, where the former is preserved for use and the latter is filtered out in the digital signal processing unit 160.

[0019] The digital signal processing unit 160 is electrically connected to the demodulation unit 150 to receive and process the plurality of baseband I/Q signals I.sub.1/Q.sub.1˜I.sub.N/Q.sub.N to obtain a digital beamforming pattern P. In this embodiment, the digital beamforming pattern P is derived from the following equation:

[00001]$P\left(\varphi \right)=\underset{n=0}{\overset{N-1}{.Math.}}{S}_n{e}^{j\frac{2\pi }{\lambda }\left({\mathrm{nd}}_r\cos \varphi \right)}$

where P(ϕ) is the digital beamforming pattern P as a function of azimuth angle ϕ, N is the number of the plurality of receive antennas 131, S.sub.n is the nth one of the plurality of baseband I/Q signals I.sub.1/Q.sub.1˜I.sub.N/Q.sub.N in digital complex form, λ is a wavelength of the plurality of received signals S.sub.r1˜S.sub.rN, and d.sub.τ is a distance between two adjacent ones of the plurality of receive antennas 131. The digital beamforming pattern P results from the detection of the target(s) O in the area A with the phased-array Doppler radar 100 of the first embodiment. The azimuth angles of the target(s) O in the area A can be thus identified at the peaks of the digital beamforming pattern P.

[0020] FIG. 2 shows the digital beamforming pattern P that is produced by the phased-array Doppler radar 100 of the first embodiment. The targets O are three seated adults who face the radar and are located at a distance of 1 meter and azimuth angles of 50°, 90° and 130° from the radar. It can be seen from FIG. 2 that there are three peaks at the azimuth angles of 50°, 90° and 130°, which agrees with the azimuth angles of the targets O.

[0021] The digital signal processing unit 160 can further extract vital signs of the targets O in the area A from the time variations in the digital beamforming pattern P at those peak azimuth angles (i.e., 50°, 90° and 130°). As a result, FIGS. 3a to 3c show the Fourier spectra of the extracted vital signs of the three seated adults, where their respiration and heartbeat frequencies can be clearly identified in their corresponding spectra. This result demonstrates that the phased-array Doppler radar 100 of the first embodiment is able to capture the vital signs of different targets.

[0022] A phased-array Doppler radar 100 of a second embodiment of the present invention shown in FIG. 4 differs from that of the first embodiment of the present invention by including a transmit antenna array 120 and a switch 180. The switch 180 is electrically connected to the two-way splitter 110 to receive one part of the reference signal S.sub.ref. The transmit antenna array 120 includes a plurality of transmit antennas 121 that are electrically connected to the switch 180 to transmit one part of the reference signal S.sub.ref via the switch 180 to the area A as the transmitted signal S.sub.T. The transmitted signal S.sub.T is transmitted from different ones of the plurality of transmit antennas at different times. In this embodiment, the transmit antenna array 120 is placed vertically.

[0023] In the second embodiment, the axes of the transmit antenna array 120 and the receive antenna array 130 are perpendicular to each other. Such a combination of the transmit antenna array 120 and the receive antenna array 130 is equivalent to a two-dimensional phased array based on time division multiplexing principle, as shown in FIG. 5, where M and N denote the number of the plurality of transmit antennas 121 and the plurality of receive antennas 131, respectively. In this embodiment, the digital beamforming pattern P is derived from the following equation:

[00002]$P\left(\theta ,\varphi \right)=\underset{m=0}{\overset{M-1}{.Math.}}\underset{n=0}{\overset{N-1}{.Math.}}{S}_{\mathrm{mn}}{e}^{j\frac{2\pi }{\lambda }\left({\mathrm{md}}_t\cos \theta +{\mathrm{nd}}_r\cos \varphi \right)}$

where P (θ, ϕ) is the digital beamforming pattern P as a function of elevation angle θ and azimuth angle ϕ, S.sub.mn is the nth one of the plurality of baseband I/Q signals I.sub.1/Q.sub.1˜I.sub.N/Q.sub.N in digital complex form during the transmission period of the mth one of the plurality of transmit antennas 121, and d.sub.t is a distance between two adjacent ones of the plurality of transmit antennas 121. This equation indicates that the digital beamforming pattern P is two-dimensional so it can be used to capture the images of different parts of the target(s) O in the area A.

[0024] FIG. 6 shows the digital beamforming pattern P that is produced by the phased-array Doppler radar 100 of the second embodiment. The target 0 is an adult seated about 1.5 m from the radar placed on his left side. It is seen from FIG. 6 that the sitting posture of the target O is well recognized based on the captured images of head, neck, chest, butt and legs. This result demonstrates that the phased-array Doppler radar 100 of the second embodiment is able to capture the images of different parts of the target O.

[0025] In the phased-array Doppler radar of the present invention, the digital beamforming pattern P is provided to capture the vital signs or images of the target(s) O in the area A, and the ILO 140 is provided to enable the phased-array Doppler radar 100 to detect the target(s) O with an external radio signal rather than an internal source signal. To sum up, the present invention has not only high detection performance but also great potential to facilitate a joint radar and communication system.

[0026] While this invention has been particularly illustrated and described in detail with respect to the preferred embodiments thereof, it will be clearly understood by those skilled in the art that is not limited to the specific features shown and described and various modified and changed in form and details may be made without departing from the spirit and scope of this invention.