A low-cost, simple ultrasonic sensing system has an increased detection range. The ultrasonic sensing system may be implemented as part of a load control system for controlling the power delivered from an AC power source to an electrical load. The load control system may comprise a load control device for controlling the power delivered to the electrical load, an ultrasonic receiver for receiving ultrasonic waves characterized by an ultrasonic frequency, and an ultrasonic transmitter located remotely from the ultrasonic receiver. The load control device controls the power delivered to the electrical load in response to the ultrasonic waves received by the ultrasonic receiver. The load control device may include the ultrasonic receiver and may be a wall-mounted load control device. The ultrasonic receiver may be a wireless ultrasonic receiver for transmitting wireless signals to the load control device in response to the ultrasonic waves received by the ultrasonic receiver.
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0. 32. A system comprising:
a plurality of remote ultrasonic transmitters, each configured to transmit ultrasonic waves characterized by an ultrasonic frequency, wherein each of the plurality of remote ultrasonic transmitters does not include a receiver for receiving ultrasonic waves; and
a sensor comprising:
a sensor communication circuit;
a local ultrasonic transmitter disposed proximate the ultrasonic receiver;
an ultrasonic receiver configured to:
receive ultrasonic waves, wherein the received ultrasonic waves comprise attenuated ultrasonic waves transmitted by the plurality of remote ultrasonic transmitters and reflected ultrasonic waves from the local ultrasonic transmitter; and
convert at least one of: a change in amplitude of the attenuated ultrasonic waves received from the remote ultrasonic transmitter or the change in frequency of the received reflected ultrasonic waves from the local transmitter to a voltage signal; and
a control circuit operatively coupled to the sensor communication circuit and the ultrasonic receiver, the control circuit configured to:
receive the voltage signal generated by the ultrasonic receiver;
determine whether the voltage signal is at least one of: greater than upper voltage threshold value or less than a lower voltage threshold value;
determine an occupancy condition exists responsive to at least one of: the voltage signal being greater than the upper voltage threshold value or the voltage signal being less than a lower voltage threshold value;
transmit a command via the sensor communication circuit that indicates the space is occupied in response to the determination that an occupancy condition exists within the space;
wherein each of the plurality of remote ultrasonic transmitters and the sensor are separate devices.
0. 25. A system comprising:
a remote ultrasonic transmitter configured to transmit ultrasonic waves characterized by an ultrasonic frequency, wherein the remote ultrasonic transmitter does not include a receiver for receiving ultrasonic waves transmitted by the remote ultrasonic transmitter; and
a sensor comprising:
a sensor communication circuit;
a local ultrasonic transmitter configured to transmit ultrasonic waves at the ultrasonic frequency;
an ultrasonic receiver configured to:
receive ultrasonic waves, wherein the received ultrasonic waves comprise attenuated ultrasonic waves transmitted by the remote ultrasonic transmitter and reflected ultrasonic waves transmitted by the local ultrasonic transmitter;
convert a change in amplitude of the attenuated ultrasonic waves received from the remote ultrasonic transmitter and the change in frequency of the received reflected ultrasonic waves from the local transmitter to a voltage signal;
generate one or more ultrasonic sense signals in response to determining whether there are periods of frequency modulation in the received ultrasonic waves; and
a control circuit operatively coupled to the sensor communication circuit and the ultrasonic receiver, the control circuit configured to:
receive the voltage signal generated by the ultrasonic receiver;
determine whether the voltage signal is at least one of: greater than upper voltage threshold value or less than a lower voltage threshold value;
determine an occupancy condition exists responsive to at least one of: the voltage signal being greater than the upper voltage threshold value or the voltage signal being less than a lower voltage threshold value;
transmit a command via the sensor communication circuit that indicates the space is occupied in response to the determination that an occupany condition exists within the space;
wherein the remote ultrasonic transmitter and the sensor are separate devices.
1. A load control system for controlling power delivered from a power source to an electrical load, the system comprising:
a load control device configured to be coupled in series between the power source and the electrical load for controlling the power to the electrical load via a switching circuit, the load control device comprising a load control device communication circuit;
a remote ultrasonic transmitter configured to transmit ultrasonic waves characterized by an ultrasonic frequency and an amplitude, wherein the remote ultrasonic transmitter does not include a receiver for receiving ultrasonic waves transmitted by the remote ultrasonic transmitter; and
a sensor comprising:
a sensor communication circuit;
a local ultrasonic transmitter configured to transmit ultrasonic waves at the ultrasonic frequency;
an ultrasonic receiver configured to receive attenuated ultrasonic waves from the remote ultrasonic transmitter and configured to:
receive reflections of the ultrasonic waves transmitted by the local ultrasonic transmitter;
convert a change in amplitude of the attenuated ultrasonic waves received from the remote ultrasonic transmitter and the change in frequency of the received reflected ultrasonic waves from the local transmitter to a voltage signal; and
a control circuit coupled to the sensor communication circuit and to the ultrasonic receiver, the control circuit configured to:
receive, via the ultrasonic receiver, signals representing the attenuated ultrasonic waves and the reflected ultrasonic waves;
determine occupancy from the received signals based on at least one of (i) a change in amplitude between the attenuated ultrasonic waves and the characterized amplitude and (ii) a change in frequency between the reflected ultrasonic waves and the characterized ultrasonic frequency
determine whether the voltage signal is at least one of: greater than upper voltage threshold value or less than a lower voltage threshold value;
determine an occupancy condition exists responsive to at least one of: the voltage signal being greater than the upper voltage threshold value or the voltage signal being less than a lower voltage threshold value; and
transmit a command via the sensor communication circuit to the load control device based on the determination of occupancy;
wherein the load control device, the remote ultrasonic transmitter device, and the sensor are each separate devices; and
further wherein the load control device is configured to receive the command via the communication circuit of the load control device and to control the power delivered via the switching circuit to the electrical load in response to the command.
22. A load control system for controlling the power delivered from a power source to an electrical load, the system comprising:
a remote ultrasonic transmitter configured to transmit ultrasonic waves characterized by an ultrasonic frequency, wherein the remote ultrasonic transmitter does not include a receiver for receiving ultrasonic waves transmitted by the remote ultrasonic transmitter, and wherein the remote ultrasonic transmitter is configured to be plugged into an electrical outlet; and
a load control device that is a separate device from the remote ultrasonic transmitter and that is adapted to be coupled in series electrical connection between the power source and the electrical load for controlling the power delivered to the electrical load via a switching circuit, the load control device comprising a load control device communication circuit; and
a sensor comprising:
a sensor communication circuit;
a local ultrasonic transmitter configured to transmit ultrasonic waves at the ultrasonic frequency;
an ultrasonic receiver configured to:
receive ultrasonic waves from the remote ultrasonic transmitter and to:
receive ultrasonic waves from the local ultrasonic transmitter;
convert a change in amplitude of the attenuated ultrasonic waves received from the remote ultrasonic transmitter and the change in frequency of the received reflected ultrasonic waves from the local transmitter to a voltage signal; and
a control circuit operatively coupled to the ultrasonic receiver, the control circuit configured to:
(i) detect occupancy based on the received ultrasonic waves by at least one of:
(a) detecting a period of amplitude modulation from the ultrasonic waves received from the remote ultrasonic transmitter, and
(b) detecting a Doppler shift of the ultrasonic frequency from the ultrasonic waves received from the local ultrasonic transmitter;
determine whether the voltage signal is at least one of: greater than upper voltage threshold value or less than a lower voltage threshold value;
determine an occupancy condition exists responsive to at least one of: the voltage signal being greater than the upper voltage threshold value or the voltage signal being less than a lower voltage threshold value; and
(ii) transmit a command via the sensor communication circuit to the load control device based on the determination of occupancy;
wherein the sensor is separate from the load control device and the remote ultrasonic transmitter device;
further wherein the load control device is configured to receive the command via the communication circuit of the load control device and to control the power delivered via the switching circuit to the electrical load in response to the command.
2. The system of
3. The system of
4. The system of
5. The system of
6. The system of
an external power supply configured to generate a DC voltage from an AC line voltage of an AC power source;
wherein the power supply of the remote ultrasonic transmitter is configured to generate the supply voltage from the DC voltage of the external power supply.
7. The system of
8. The system of
9. The system of
10. The system of
13. The system of
16. The system of
18. The system of
wherein the at least two remote ultrasonic transmitters and the sensor are placed in a room such that the respective ultrasonic coverage patterns of each of the at least two remote ultrasonic transmitters and the sensor overlap to substantially fill the room with ultrasonic waves.
19. The system of
20. The system of
a first, wall including the sensor;
a second wall including at least one remote transmitter; and
a third wall, wherein each wall has at least one of: the at least two including at least one remote ultrasonic transmitters and the sensor transmitter.
21. The system of
23. The system of
24. The system of
0. 26. The system of claim 25, further comprising:
wherein the remote ultrasonic transmitter comprises a first remote ultrasonic transmitter, the system further comprising a second remote ultrasonic transmitter configured to transmit ultrasonic waves characterized by the ultrasonic frequency; and
wherein the ultrasonic receiver is further configured to:
receive ultrasonic waves transmitted by the local ultrasonic transmitter; and
determine whether there are periods of frequency modulation in the received ultrasonic waves transmitted by the local ultrasonic transmitter.
0. 27. The system of claim 25,
wherein each of the plurality of remote ultrasonic transmitters further comprises an ultrasonic transmitting element, a drive circuit configured to energize the ultrasonic transmitting element, and a low phase-noise oscillator circuit configured to directly drive the drive circuit to cause the ultrasonic transmitting element to transmit the ultrasonic waves at the ultrasonic frequency.
0. 28. The system of claim 27,
wherein each of the plurality of remote ultrasonic transmitters further comprises a power supply configured to generate a supply voltage for powering the low phase-noise oscillator circuit and the drive circuit.
0. 29. The system of claim 28, wherein the power supply of each of the plurality of remote ultrasonic transmitters is further configured to generate the supply voltage from an AC line voltage of an AC power source.
0. 30. The system of claim 27,
wherein each of the plurality of remote ultrasonic transmitters is further configured to power the low phase-noise oscillator circuit and the drive circuit from a battery.
0. 31. The system of claim 25, wherein the sensor is configured to be mounted to a ceiling.
0. 33. The system of claim 32,
wherein each of the plurality of remote ultrasonic transmitters further comprises an ultrasonic transmitting element, a drive circuit configured to energize the ultrasonic transmitting element, and a low phase-noise oscillator circuit configured to directly drive the drive circuit to cause the ultrasonic transmitting element to transmit the ultrasonic waves at the ultrasonic frequency.
0. 34. The system of claim 33,
wherein each of the plurality of remote ultrasonic transmitters further comprises a power supply configured to generate a supply voltage for powering the low phase-noise oscillator circuit and the drive circuit.
0. 35. The system of claim 34, wherein the power supply of each of the plurality of remote ultrasonic transmitters is further configured to generate the supply voltage from an AC line voltage of an AC power source.
0. 36. The system of claim 33, wherein each of the plurality of remote ultrasonic transmitters is further configured to power the low phase-noise oscillator circuit and the drive circuit from a battery.
0. 37. The system of claim 32, wherein the sensor is configured to be mounted to a ceiling.
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This application is a reissue of U.S. Pat. No. 10,054,916, issued Aug. 21, 2018 from U.S. patent application Ser. No. 14/569,618, filed Dec. 12, 2014, which is hereby incorporated by reference in its entirety. U.S. Pat. No. 10,054,916 claims the benefit of U.S. Provisional Application No. 61/918,008, filed Dec. 12, 2013, which is incorporated by reference herein as if fully set forth.
Occupancy and vacancy sensors are often used to detect occupancy and/or vacancy conditions in a space in order to control an electrical load, such as a lighting load. An occupancy sensor typically operates to turn on the lighting load when the occupancy sensor detects the presence of a user in the space (i.e., an occupancy event) and then to turn off the lighting load when the occupancy sensor detects that the user has left the space (i.e., a vacancy event). A vacancy sensor may only operate to turn off the lighting load when the vacancy sensor detects a vacancy in the space. Therefore, when using a vacancy sensor, the lighting load must be turned on manually (e.g., in response to a manual actuation of a control actuator).
Occupancy and vacancy sensors have often been provided in wall-mounted load control devices that are coupled between an alternating-current (AC) power source and an electrical load for control of the amount of power delivered to the electrical load. Some occupancy and vacancy sensors have been provided as part of lighting control systems. These sensors are often coupled via a wired control link to a lighting controller (e.g., a central processor), which then controls the lighting loads accordingly. Alternatively, the sensors may be battery-powered and may be operable to transmit wireless signals, such as radio-frequency (RF) signals, to load control devices, such as dimmer switches. These occupancy and vacancy sensors are not required to be mounted in electrical wallboxes, but may be mounted to the ceiling or high on a wall. Therefore, the occupancy and vacancy sensors may be positioned optimally to detect the presence of the user in all areas of the space.
Occupancy and vacancy sensors typically include internal detectors, such as a pyroelectric infrared (PIR) detector and a lens for directing energy to the PIR detector for detecting the presence of the user in the space. Some occupancy and vacancy sensors have included ultrasonic transmitting and receiving circuits for detecting the presence of the user in the space. Ultrasonic sensors transmit ultrasonic waves at a predetermined frequency and analyze received ultrasonic waves to determine if there is an occupant in the space. The received ultrasonic waves that are reflected off of moving objects will be characterized by a Doppler shift with respect to the transmitted ultrasonic waves, while the received ultrasonic waves that are produced by reflections off of the walls, ceiling, floor, and other stationary objects of the room will not have a Doppler shift. Therefore, ultrasonic occupancy and vacancy sensors are able to determine if there is an occupant in the space if there is a Doppler shift between the frequencies of the transmitted and received ultrasonic waves.
Generally, the size of the objects that produce the ultrasonic waves having the Doppler shift (i.e., a moving hand) are very small and produce reflected ultrasonic waves having small magnitudes. One of the issues with detecting ultrasonic waves having a Doppler shift is that these received ultrasonic waves can be difficult to distinguish from the received ultrasonic waves that do not have a Doppler shift. A figure of merit for occupancy detection limits can be described using the signal-to-interference ratio (SIR), which is the ratio of the Doppler-shifted ultrasonic waves expressed in sound pressure level (SPL) to the non-Doppler-shifted ultrasonic waves.
One prior art implementation for detecting Doppler shifts in ultrasonic waves uses a phase-lock-loop (PLL) integrated circuit (IC), such as part number CD74HC7046, manufactured by Texas Instruments Incorporated. In this implementation, the received ultrasonic waves are amplified by a pre-amplifier and then compared with a single fixed threshold (e.g., 100 mV) using a comparator to yield a binary waveform. The binary waveform is then applied to an exclusive- or (XOR) gate where the second input to the XOR is a clock input (e.g., a 40-kHz clock signal) that also drives the ultrasonic transmitting circuit. The resulting signal is then passed through a band-pass filter to extract the Doppler signal. The resulting Doppler signal is then compared to a fixed threshold using another comparator to detect an occupancy or vacancy condition. A drawback of this implementation is that the circuit is very sensitive to the thresholds of the comparators and only works on signals with an SIR greater than approximately −40 dB.
Another prior art implementation for detecting Doppler shift utilizes the detection algorithm primarily within a microcontroller. In this implementation, the received ultrasonic waves are amplified by a preamplifier and then sampled using an analog-to-digital converter (e.g., an 8- to 12-bit ADC) in the microcontroller. The remainder of the algorithm is essentially the same as in the first form for detecting Doppler shift described above, except that the remainder of the algorithm of the second form is executed in the software of the microcontroller. This implementation depends on the accuracy of the ADC of the microcontroller and is limited by numerical noise due to the ADC quantization and the numerical precision used to calculate the results, which thus limits the ability to detect small-magnitude ultrasonic waves that have a Doppler shift.
An amplitude-modulation (AM) demodulator may be used to detect Doppler shift. An AM demodulator, in its simplest form, uses a diode and a low-pass filter to form an envelope detector. The limitation of this circuit is that the received ultrasonic signal must have a minimum amplitude to render the diode conductive, thereby reducing the ability of the circuit to detect small-magnitude ultrasonic waves that have a Doppler shift.
As described herein, a low-cost, simple ultrasonic sensing system may have an increased detection range. The ultrasonic sensing system may be implemented as part of a load control system for controlling the power delivered from an AC power source to an electrical load. The load control system may include a load control device adapted to be coupled in series electrical connection between the AC power source and the electrical load for controlling the power delivered to the electrical load, an ultrasonic receiver for receiving ultrasonic waves characterized by an ultrasonic frequency, and an ultrasonic transmitter located remotely from the ultrasonic receiver. The ultrasonic transmitter is operable to transmit ultrasonic waves at approximately the ultrasonic frequency. The load control device is configured to control the power delivered to the electrical load in response to the ultrasonic waves received by the ultrasonic receiver. For example, the load control device may include the ultrasonic receiver and may be a wall-mounted load control device. Alternatively, the ultrasonic receiver may be a wireless ultrasonic receiver for transmitting wireless signals to the load control device in response to the ultrasonic waves received by the ultrasonic receiver.
An ultrasonic transmitter, as described herein, may include: (1) an ultrasonic transmitting element for transmitting ultrasonic waves; (2) a drive circuit coupled to the ultrasonic transmitting element for energizing the ultrasonic transmitting element; and (3) a low phase-noise oscillator circuit generating an oscillating signal. The oscillator circuit direct drives the drive circuit to cause the ultrasonic transmitting element to transmit the ultrasonic waves at an ultrasonic transmission frequency.
As shown in
The load control device 210 may operate as an occupancy sensor to turn the lighting load 204 on in response to the presence of an occupant in the vicinity of the load control device (e.g., an occupancy condition), or off in response to the absence of the occupant (e.g., a vacancy condition). The load control device 210 may include an internal ultrasonic occupancy detection circuit operable to transmit and receive ultrasonic waves 206 via an acoustic grill 216 (e.g., a vent) for detecting the presence or absence of the occupant. The load control device 210 may be operable to determine whether an occupancy condition or a vacancy condition is presently occurring in the space in response to the ultrasonic waves received by the ultrasonic occupancy detection circuit, as will be described in greater detail below. The load control device 210 may operate as a vacancy sensor. When operating as a vacancy sensor, the load control device 210 may only operate to turn off the lighting load 204 in response to detecting a vacancy condition in the space. For example, the load control device 210 would not turn on the lighting load 204 in response to detecting an occupancy condition. When the load control device 210 operates as a vacancy sensor, the lighting load 204 must be turned on manually (e.g., in response to a manual actuation of the on button 212).
The load control device 210 may include an internal passive infrared (PIR) occupancy detection circuit for detecting the presence or absence of the occupant, i.e., the load control device 210 may be a dual-tech occupancy sensor. The load control device 210 may include a lens 218 for directing the infrared energy from the occupant to the internal PIR occupancy detection circuit. Examples of occupancy and vacancy sensors having PIR occupancy detection circuits are described in greater detail in commonly-assigned U.S. Pat. No. 8,009,042, issued Aug. 30, 2013, entitled RADIO-FREQUENCY LIGHTING CONTROL SYSTEM WITH OCCUPANCY SENSING, the entire disclosure of which is hereby incorporated by reference. The load control device 210 may include a microwave detector, or any suitable detector or combination of detectors, for detecting the presence or absence of the occupant.
The load control system 200 may include an electrical outlet 220 that is coupled in parallel with the AC power source 202 and has, for example, two electrical receptacles 222. The remote ultrasonic transmitter 230 may be plugged into one of the electrical receptacles 222 of the electrical outlet 220 as shown in
The ultrasonic transmitters 712 are simple, low-cost devices and operate to transmit the ultrasonic waves. The ultrasonic transmitters 712 may be spaced about the room 700 and may be, for example, plugged into electrical outlets in the room. The ultrasonic transmitters 712 may be located on a surface, such as a tabletop or a chair, or in a wallbox housing a switch for an LED light bulb (e.g., as described with reference to
The load control device 800 may include a controllably conductive device 810 coupled in series electrical connection between the hot terminal 802 and the load terminal 804 for controlling the power delivered to the electrical load. The controllably conductive device 810 may include, for example, a relay, a bidirectional semiconductor switch (such as, a triac, a FET in a rectifier bridge, two FETs in anti-series connection, or one or more insulated-gate bipolar junction transistors), or any other suitable switching circuit.
The load control device 800 may include a control circuit 820 that is coupled to the controllably conductive device 810 for rendering the controllably conductive device conductive and/or non-conductive to control the power delivered to the electrical load. For example, the control circuit 820 may include a microcontroller, a programmable logic device (PLD), a microprocessor, an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), or any suitable processing device, controller, or control circuit. The control circuit 820 may receive inputs from actuators 822 (e.g., the on button 212 and the off button 214 of the load control device of
A zero-cross detect circuit 826 may be coupled between the hot terminal 802 and the load terminal 804. The zero-cross detect circuit 826 may generate a zero-cross control signal VZC. The zero-cross control signal VZC may be representative of the zero-crossings of an AC source voltage of the AC power source. A zero-crossing may be defined at the time at which the AC source voltage transitions from positive to negative polarity, at the time at which the AC source voltage transitions from negative to positive polarity, or at the beginning of each half-cycle. The zero-cross control signal VZC may be received by the control circuit 820. The control circuit 820 may control the controllably conductive device 810 to be conductive and/or non-conductive at predetermined times relative to the zero-crossing points of the AC source voltage.
The load control device 800 may include a wireless communication circuit 828, for example, including a radio-frequency (RF) transceiver coupled to an antenna for transmitting and receiving wireless signals (e.g., RF signals from a remote ultrasonic receiver or a remote ultrasonic transmitter). The communication circuit 828 may comprise an RF transmitter for transmitting RF signals, an RF receiver for receiving RF signals, or an infrared (IR) transmitter and/or receiver for transmitting and/or receiving IR signals. The wireless communication circuit 828 may be in electrical communication with the control circuit 820 of the load control device 800, such that one or more wireless signals received from the ultrasonic receiver may cause the load control device to adjust the lighting on or off. The antenna of the wireless communication circuit 828 may be enclosed in the housing of the load control device 800 or coupled to the exterior portion of the housing.
The control circuit 820 may be coupled to a low phase-noise oscillator circuit 530 for setting an internal operating frequency for of the control circuit (e.g. approximately 40 kHz±2 Hz). The low phase-noise oscillator circuit 830 may include, for example, a Pierce oscillator circuit (as shown in
The load control device 800 may include an ultrasonic sensing circuit 840 having an ultrasonic transmitting circuit 850 and an ultrasonic receiving circuit 860. The ultrasonic transmitting circuit 850 may include a drive circuit 854 (e.g., an H-bridge drive circuit). The drive circuit 854 may receive the second DC supply voltage VCC2 for energizing a piezoelectric element 852, for example, in order to transmit ultrasonic waves from the load control device 800 (e.g., via an acoustic grill, such as the acoustic grill 216 of the load control device 200 shown in
The ultrasonic receiving circuit 860 may include a piezoelectric element 862. The piezoelectric element 862 may generate a received ultrasonic input signal VIN in response to the received ultrasonic waves (e.g., the received ultrasonic waves shown in
A filter and amplifier circuit 868 (e.g., an anti-aliasing filter, such as a bandpass filter) may generate a filtered signal VFILT from the rectified signal VRECT. The filter and amplifier circuit 868 may have a bandwidth of approximately 50-500 Hz. The filter and amplifier 868 may be characterized by a gain of approximately 60 dB. The control circuit 820 may receive the filtered signal VFILT from the filter and amplifier circuit 868. The control circuit 820 may sample the filtered signal using, for example, an analog-to-digital converter (ADC). The control circuit 820 is operable to detect the presence of the occupant in the space, for example, if the magnitude of the filtered signal VFILT rises above an upper voltage threshold or falls below a lower voltage threshold. In addition, the control circuit 820 may be operable to digitally filter the filtered signal VFILT received from the filter and amplifier circuit 868 to provide additional filtering of the signal before determining if the space is occupied or unoccupied.
The load control device 800 may include a passive infrared (PIR) sensing circuit 870, e.g., comprising a pyro-electric infrared detector for receiving infrared energy of the occupant through a lens of the load control device (e.g., the lens 218 of the load control device 200 shown in
The ultrasonic transmitter 900 may include a low phase-noise oscillator circuit 920, such as for driving an ultrasonic transmitting circuit 930. The oscillator circuit 920 may generate an oscillating signal VOSC (e.g., a square wave) at an ultrasonic transmission frequency fUS (e.g., approximately 40 kHz±2 Hz) for driving the ultrasonic transmitting circuit 930. As shown in
The ultrasonic transmitting circuit 930 may include a drive circuit 932 for energizing a piezoelectric element 934, for example, to transmit ultrasonic waves from the ultrasonic transmitter 900 (e.g., through an acoustic grill, such as the acoustic grill 232 of the ultrasonic transmitter 230 shown in
The load control system 1000 of
The load control device 1100 may include a control circuit 1120 for controlling the controllably conductive device 1110 to be conductive and/or non-conductive to control the power delivered to the electrical load. For example, the control circuit 1120 may have a microcontroller, a programmable logic device (PLD), a microprocessor, an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), or any suitable processing device, controller, or control circuit. The control circuit 1120 may receive inputs from actuators 1122 (e.g., the on button 1012 and the off button 1014 of the load control device 1010 of
The load control device 1100 may have an ultrasonic sensing circuit 1140. The ultrasonic sensing circuit 1140 may include an ultrasonic receiving circuit 1160. For example, the ultrasonic sensing circuit 1140 may include an ultrasonic receiving circuit 1160.
The ultrasonic receiving circuit 1160 may have a piezoelectric element 1162. The piezoelectric element 1162 may generate a received ultrasonic input signal VIN, for example, in response to the received ultrasonic waves (e.g., the received ultrasonic waves shown in
The ultrasonic receiving circuit 1160 may include a synchronous rectifier 1166 (i.e., a lock-in amplifier). The synchronous rectifier 1166 may be responsive to signals having small magnitudes. The synchronous rectifier 1166 may receive the amplified signal VAMP from the amplifier circuit 1164. The synchronous rectifier 1166 may generate a rectified signal VRECT, for example, as shown in
The control circuit 1120 may receive the filtered signal VFILT from the bandpass filter 1168. The control circuit 1120 may sample the filtered signal using an ADC. The control circuit 1120 may be operable to detect the presence of the occupant in the space by comparing the magnitude of the filtered voltage VFILT to an upper voltage threshold VTH+ (e.g., approximately 0.25 volts) and a lower voltage threshold VTH− (as shown in
In
The load control system 1300 may include a remote load control device 1340. The remote load control device 1340 may be coupled in series electrical connection between an AC power source 1302 and an electrical load (e.g., a lighting load 1304), such as for controlling the intensity of the lighting load. The remote load control device 1340 may be electrically coupled to the neutral side of the AC power source 1302 or to an earth ground connection. The remote load control device 1340 may be adapted to be remotely mounted, for example, to a junction box above a ceiling or in an electrical closet, such that the remote load control device is not easily accessible by a user. The remote load control device 1340 may be configured to control the lighting load 1304 in response to digital messages transmitted by the wireless ultrasonic sensor 1310 via the RF signals 1308 (e.g., in a similar manner as the load control device 1100 of
The ultrasonic receiving circuit 1460 may include a piezoelectric element 1462. The piezoelectric element 1462 may generate a received ultrasonic input signal VIN in response to the received ultrasonic waves (e.g., the received ultrasonic waves shown in
The remote ultrasonic receiver 1400 may include a control circuit 1420. The control circuit 1420 may include a microcontroller, a programmable logic device (PLD), a microprocessor, an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), or any suitable processing device, controller, or control circuit. The remote ultrasonic receiver 1400 may include a wireless communication circuit 1422, for example, including a radio-frequency (RF) transceiver coupled to an antenna for transmitting and/or receiving wireless signals (e.g., RF signals). The communication circuit 1422 may comprise an RF transmitter for transmitting RF signals, an RF receiver for receiving RF signals, or an infrared (IR) transmitter and/or receiver for transmitting and/or receiving IR signals. The wireless communication circuit 1422 may be in electrical communication with the control circuit 1420, such that one or more wireless signals received from the ultrasonic transmitter may cause the ultrasonic receiver 1400 to transmit signals to a load control device (e.g., such as the remote load control device 1340 of
The load control devices 1510A, 1510B may be similar to the load control devices 210, 1010 shown in
The load control devices 1510A, 1510B may be operable to communicate with each other via the second electrical wire 1509, for example, to determine how to control the lighting load 1504 in response to detecting the presence or absence of an occupant. For example, the second load control device 1510B may establish itself as a master device in the load control system 1500. The first load control device 1510A may render its controllably conductive device conductive substantially fully conductive. The first load control device 1510A may transmit digital messages to the second load control device 1510B via the second electrical wire 1509 in response to detecting the presence or absence of an occupant. The second load control device 1510B may control its controllably conductive device to control the power delivered to the lighting load 1504 in response to its internal ultrasonic occupancy detection circuit and/or the digital messages received from the first load control device 1510A.
The load control system 1500 may include one or more ultrasonic transmitters (e.g., the ultrasonic transmitter 230 shown in
Steiner, James P., Sloan, Greg Edward
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