This invention generally relates to vital sign sensing method and system, and more particularly to vital sign sensing method and system using a communication device.
Conventional noncontact vital-sign sensor exploits the Doppler Effect between wireless signals emitted from radar and human body to detect vital signs (e.g. respiration and heartbeat). However, it is difficult to identify the Doppler phase shifts in the wireless signals because the vibration caused by vital sign of the human body is tiny. In order to monitor tiny vibration of vital sign, conventional radar equipped with additional active circuit for pure sine wave generation is required, but construction costs and power consumption may be increased.
U.S. Pat. No. 9,846,226, entitled “Motion detection device”, discloses a motion detection device capable of detecting gesture by using the surrounding communication signals. With reference to FIG. 3 of U.S. Pat. No. 9,846,226, the wireless signal received by the antenna 110 and coupled by the coupler 150 is injected into the voltage-controlled oscillator 130 to allow the voltage-controlled oscillator 130 to operate in the injection-locked state and has a frequency variation, such that the sensitivity of the radar for sensing the Doppler phase shift of the communication signal caused by the gesture can be increased. U.S. Pat. No. 9,846,226 also discloses the motion detection device can serve as a sensor for short-distance vital sign detection in column 13 lines 45-62, nevertheless, it cannot be used as a vital sign sensor for long-distance detection or under the situation that a barrier exists between receiver and human body.
By performing EVM (Error vector magnitude) algorithm on demodulated 1-phase and Q-phase signals, vital sign sensing method and system disclosed in the present invention allows any communication device to be used as highly sensitive sensor of tiny vibration such that vital sign detection is available.
A vital sign sensing method of the present invention includes steps of: transmitting a transmitted signal to a subject by using a transmitter; receiving a reflected signal reflected from the subject as a received signal by using a receiver, an IQ demodulator of the receiver is configured to demodulate the received signal to obtain a demodulated in-phase signal and a demodulated quadrature-phase signal; and receiving the demodulated in-phase signal and the demodulated quadrature-phase signal by using a compute unit, the compute unit is configured to perform an error vector magnitude algorithm on the demodulated in-phase signal and the demodulated quadrature-phase signal to extract a vital-sign signal of the subject.
A vital sign sensing system of the present invention includes a transmitter, a receiver and a compute unit. The transmitter is configured to transmit a transmitted signal to a subject. The receiver includes a receive antenna and an IQ demodulator, the receive antenna is configured to receive a reflected signal reflected from the subject as a received signal, the IQ demodulator is coupled to the receive antenna for receiving the received signal and configured to demodulate the received signal to obtain a demodulated in-phase signal and a demodulated quadrature-phase signal. The compute unit is coupled to the receiver for receiving the demodulated in-phase signal and the demodulated quadrature-phase signal, and configured to perform an EVM algorithm on the demodulated in-phase signal and the demodulated quadrature-phase signal to extract a vital-sign signal of the subject.
In order to extract the vital sign of the subject, the EVM algorithm is performed on the in-phase and quadrature-phase signals demodulated by the IQ demodulator. The present invention can utilize current wireless communication signals to detect vital signs directly, and any current communication device still preserves communication function while being used as vital sign sensor. Signal interference between the vital sign sensing system of the present invention and the communication device is avoided. Furthermore, the present invention overcomes the disadvantages of high costs and high power consumption.
With reference to
The transmitter 110 of the first embodiment includes a signal generation unit 111 and a transmit antenna 112. The signal generation unit 111 having signal generator, mixer and modulator is configured to generate and transmit a modulated signal SM to the transmit antenna 112, and the transmit antenna 112 is configured to transmit the modulated signal SM to the environment as a transmitted signal ST. The transmitted signal ST is represented as follows:
S
Tx(t)=[ITx(t)+jQTx(t)]ejω
where STx (t) is the transmitted signal ST, ITx (t) and QTX (t) denote the transmitted in-phase and quadrature-phase baseband signals, respectively; and ωc is the carrier frequency of communication signal. The transmitted signal ST is transmitted toward a subject O in the environment, and a reflected signal SR is reflected from the subject O. When the subject O has a motion relative to the transmit antenna 112, the motion of the subject O generates the Doppler effect on the transmitted signal ST such that the reflected signal SR contains the Doppler phase shifts. If the motion of the subject O is caused by vital signs, such as respiration and heartbeat, the reflected signal SR contains the Doppler phase shifts caused by the vital signs.
In the first embodiment, the transmitted signal ST from the transmitter 110 is a wireless communication signal and can be a phase-shift keying signal (e.g. BPSK, QPSK, OQPSK, DQSK, 4/π PSK, 8-PSK, 16-PSK, 32-PSK or is 64-PSK) or a quadrature amplitude modulation signal (e.g. 4-QAM, 8-QAM, 16-QAM, 32-QAM, 128-QAM, 256-QAM or 1024-QAM) available for EVM calculation.
The receiver 120 includes an IQ demodulator 121 and a receive antenna 122 which is configured to receive the reflected signal SR from the subject O as a received signal Sr, the received signal Sr is represented as follows:
where Srx(t) is the received signal Sr, G is the magnitude variation between the transmitted signal ST and the received signal Sr, τ1 is the propagation time between the transmitter 110 and the receiver 120, τ2 is the propagation time between the subject O and the receiver 120, and θd is the Doppler phase shifts caused by the motion of the subject O.
The IQ demodulator 121 is electrically connected to the receive antenna 122 for receiving the received signal Sr and configured to demodulate the received signal Sr to obtain a demodulated in-phase signal I and a demodulated quadrature-phase signal Q. The IQ demodulator 121 includes power splitter, quadrature power splitter and mixer. The circuits in the IQ demodulator 121 is conventional and will not be described here. The demodulated in-phase signal I and the demodulated quadrature-phase signal Q are represented as follows:
I
rx(t)=GITx(t−τ1)cos[θd(t−τ2)]−GQTx(t−τ1)sin[θd(t−τ2)]
Q
rx(t)=GQTx(t−τ1)cos[θd(t−τ2)]+GITx(t−τ1)sin[θd(t−τ2)]
where Irx(t) and Qrx(t) are the demodulated in-phase signal I and the demodulated quadrature-phase signal Q, respectively. And the Doppler phase shifts caused by the motion of the subject O is represented as follows:
where xd (t) denotes the motion of the subject O, λ denotes the wavelength of the transmitted signal ST in air, xh and xr denote the motion of the subject O due to the heartbeat and respiration, respectively, ωh and ωr denote the frequency of the heartbeat and respiration, respectively. When the motion of the subject O caused by the heartbeat and the respiration is much smaller than the wavelength of the transmitted signal ST
cos[θd(t−τ2)]≃1
sin[θd(t−τ2)]θd(t−τ2)
the demodulated in-phase signal I and the demodulated quadrature-phase signal Q can be simplified as follows:
I
rx(t)≃GITx(t−τ1)−GQTx(t−τ1)θd(t−τ2)
Q
rx(t)≃GQTx(t−τ1)+GITx(t−τ1)θd(t−τ2)
the first terms GITx(t−τ1) and GQTx(t−τ1) in the above equations describe the communication signals, and the second terms GQTx(t−τ1)θd(t−τ2) and GITTx(t−τ1)θd(t−τ2) in the above equations describe the system noise that is caused by the vital sign of the subject O.
With reference to
I
rx,i(t)=GITx(t−τ1)
Q
rx,i(t)=GQTx(t−τ1)
where Irx,i(t) and Qrx,i(t) are the instantaneous in-phase ideal vector and the instantaneous quadrature-phase ideal vector, respectively. And the instantaneous in-phase error vector and the instantaneous quadrature-phase error vector are represented as follows:
ΔIrx(t)=−GQTx(t−τ1)θd(t−τ2)
ΔQrx(t)=GITx(t−τ1)θd(t−τ2)
where ΔIrx(t) is the instantaneous in-phase error vector and ΔQrx (t) is the instantaneous quadrature-phase error vector. The ideal vector is synthesized from the instantaneous in-phase ideal vector and the instantaneous quadrature-phase ideal vector, and the error vector is synthesized from the instantaneous in-phase error vector and the instantaneous quadrature-phase error phase. The magnitudes of the ideal vector and the error vector are, respectively,
A
rx,i(t)=√{square root over (Irx,i2(t)+Qrx,i2(t))}=G√{square root over (ITx2(t−τ1)+QTx2(t−τ1))}
ΔArx(t)=√{square root over (ΔIrx2(t)+ΔQrx2(t))}=Gθd(t−τ2)√{square root over (ITx2(t−τ1)+QTx2(t−τ1))}
where Arx,i(t) and ΔArx (t) denote the magnitudes of the ideal vector and the error vector, respectively. Another step of the EVM algorithm is to calculate a phase variation signal according to the ideal vector and the error vector by using the compute unit 130. The calculation is represented as follows:
where θd(t−τ2) is the phase variation signal. The phase variation signal caused by the motion of the subject O with respect to the transmitter 110 is found by dividing the magnitude of the error vector by the magnitude of the ideal vector. Consequently, the compute unit 130 can perform a spectrum analysis on the phase variation signal, such as fast Fourier transform, to extract the vital-sign signal VS of the subject O.
With reference to
The vital sign sensing 100 as shown in
Second scenario layout of the present invention is shown in
In the present invention, the EVM algorithm is performed on the in-phase signal I and the quadrature-phase signal Q demodulated by the IQ demodulator 120 to extract the vital-sign signal VS of the subject O. The current wireless communication signals are available to detect the vital-sign signal VS and any communication device can preserve communication function without any signal interference while being used as a vital-sign sensor. Consequently, the vital sign sensing system 100 of the present invention has the advantages of low cost and lower power consumption.
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.
Number | Date | Country | Kind |
---|---|---|---|
109107018 | Mar 2020 | TW | national |