CROSS-REFERENCE TO RELATED APPLICATION(S)This application claims priority to Chinese Utility Model Patent Application No. 201721111845.3, filed on Sep. 1, 2017 in the State Intellectual Property Office of the People's Republic of China and Chinese Patent Application No. 201710875131.8, filed on Sep. 25, 2017 in the State Intellectual Property Office of the People's Republic of China, the disclosures of which are hereby incorporated by reference in their entireties.
BACKGROUND OF THE INVENTIONConventional radar transmitting and receiving devices utilize non-directional or omnidirectional transmitting. However, conventional radar is susceptible to errors, such as false triggering and false operation, especially when such conventional radar transmitting and receiving techniques are used to trigger a switch to control electrical appliances. For example, in the context of controlling lights, two adjacent rooms that were both equipped with switches that utilize non-directional or omnidirectional radar transmitting often both light up when someone enters just one of the rooms. This is because when the radar detector in one room senses the person entering the room and triggers the switch to activate the light, the radar detector in the next room would also be triggered falsely, thus activating the light in the next room, causing the next room to be illuminated, even though there was no motion in the next room. Additionally, comparative directional radar transmitting and receiving devices are not sufficiently robust when transmitting and receiving signals. Thus, the use of the comparative available switch controls that utilize directional radar transmitting and receiving is limited due to these technical issues.
SUMMARY OF THE INVENTIONAspects of embodiments of the present invention relate to a directional radar transmitting and receiving device that transmits and receives radar signals, avoids false triggering, and provides stability and adapts to different environments.
In some embodiments, the directional radar transmitting and receiving device includes a sensor circuit board. In some aspects, the sensor circuit board includes an integrated microwave oscillator with a first wire mounted on a first face of the sensor circuit board. The first wire may be configured to operate as an integrated transmitting antenna configured to transmit a high-frequency microwave signal. In some embodiments, the sensor circuit board includes a second wire mounted on the first face of the sensor circuit board. The second wire may be configured to operate as an integrated receiving antenna configured to receive a frequency-shifted signal, which is a reflection of the high-frequency microwave signal transmitted by the integrated transmitting antenna. In some embodiments, the device further includes a main control board. In some aspects, the main control board is mounted facing a second face of the sensor circuit board which is opposite the first face of the sensor circuit board, the main control board being configured to supply the high-frequency microwave signal to the first wire and to process the frequency-shifted signal received by the second wire.
In some embodiments, the sensor circuit board is provided with a plurality of first recesses distributed at intervals along the first wire. In some aspects, a plurality of first pillars is embedded in the plurality of first recesses, where the first wire electrically connects the first pillars. In some embodiments, the sensor circuit board is provided with a plurality of second recesses distributed at intervals along the second wire. In some embodiments, a plurality of second pillars is embedded in the second recesses, where the second wire electrically connects the second pillars.
In some embodiments, the first wire is laid along the edge of the sensor circuit board. In some aspects, the first wire is laid along the edge of the sensor circuit board to form a closed loop. In some embodiments, the first wire is in a shape of a frame.
In some embodiments, the second wire is located in the middle of the sensor circuit board. In some embodiments, the second wire is surrounded by the first wire to form a closed loop. In some embodiments, the second wire is in an S-shaped layout. In some embodiments, the second wire is in a U-shaped layout.
In some embodiments, the device includes a shielding board that is mounted facing the second face of the sensor circuit board, In some aspects, the shielding board is configured to direct the high-frequency microwave signal transmitted by the transmitting antenna and to direct the reflected frequency-shifted signal to the receiving antenna.
In some embodiments, the main control board includes a power supply circuit, a signal amplifier, a main control chip and a switch.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 is a plan view of a radar transmitting and receiving device according to one embodiment of the present invention.
FIG. 2 is a sectional view of the radar transmitting and receiving device ofFIG. 1 along the line B-B.
FIG. 3 is a sectional view of the radar transmitting and receiving device ofFIG. 1 along the line C-C.
FIG. 4 is an exploded view of a radar transmitting and receiving device according to one embodiment of the present invention.
FIG. 5 is a perspective view of transmitting antenna and receiving antenna portions of a radar transmitting and receiving device according to one embodiment of the present invention.
FIG. 6 is a circuit block diagram of a sensor circuit board according to one embodiment of the present invention.
FIG. 7 is a circuit block diagram of a main control board according to one embodiment of the present invention.
DETAILED DESCRIPTIONAspects of embodiments of the present invention relate to a directional radar transmitting and receiving device that transmits and receives radar signals, reduces or avoids false triggering, and provides stable operation that adapts to different environments. In some embodiments, the device includes a sensor circuit board integrated with a microwave oscillator, a transmitting antenna and a receiving antenna. The sensor circuit board includes a first copper wire and a second copper wire as transmitting antenna and receiving antenna, respectively. The transmitting antenna transmits a high-frequency microwave signal, while the receiving antenna receives the frequency-shifted reflection of the transmitted microwave signal. In some aspects, a shielding board is mounted on or facing one face of the sensor circuit board, wherein the shielding board and the transmitting antenna/receiving antenna are on the two faces (e.g., opposite faces, such as the top and bottom faces with respect to the orientation shown inFIG. 4, although embodiments of the present invention are not limited to any particular orientation of the structure—for example, if the structure were rotated such that the planes extended in a vertical direction, the faces may be referred to left and right faces, furthermore, the top and bottom faces may also be referred to as the top and bottom sides) of the sensor circuit board. In some embodiments, the shielding board is made of metal and directs the transmitting antenna to make directional the transmitting of high-frequency microwave signals, and directs the receiving antenna to make directional the receiving of the frequency-shifted signal reflected back.
In some embodiments, the sensor circuit board is provided with a plurality of first recesses (e.g., indentations) distributed at intervals along the first copper wire of the transmitting antenna. A plurality of first copper pillars (or electrically conductive protrusions) are embedded in the first recesses. The first copper wire electrically connects these first copper pillars so that the first copper wire and these first copper pillars are combined to improve the high-frequency microwave signal transmitting of the transmitting antenna.
In some embodiments, the sensor circuit board is provided with a plurality of second recesses distributed at intervals along the second copper wire of the receiving antenna. A plurality of second copper pillars (or electrically conductive protrusions) are embedded in the second recesses. The second copper wire electrically connects these second copper pillars so that the second copper wire and these second copper pillars are combined to make the receiving antenna have a strengthened receiving of the frequency-shifted signal reflected back.
In some embodiments, a first copper wire that is being used as the transmitting antenna is laid along the edge of the sensor circuit board to form a closed loop, wherein the first copper wire is in a shape of frame or rectangle. In some embodiments, the second copper wire of the receiving antenna is in an S-shaped layout or in a U-shaped layout, located in the middle of the sensor circuit board, wherein the second copper wire is surrounded by the first copper wire forming a closed loop.
In some embodiments, a main control board is mounted facing the second face of the sensor circuit board, and the main control board and the sensor circuit board are located facing the same face of the shielding board. In some embodiments, a non-conductive film is mounted on a face of the shielding board facing the main control board, and, in some embodiments, the non-conductive film contacts the main control board. In one embodiment, the main control board is arranged with a power supply circuit, a signal amplifying circuit, a main control chip (e.g., a microcontroller) and a switch circuit.
Aspects of embodiments of the present invention relate to technical solutions and improvements that make a directional radar transmitting and receiving device more reliable. Aspects of the present invention will be described in more detail using the following examples, which may describe more than one relevant embodiment falling within the scope of the present invention.
In one embodiment, as shown inFIGS. 1, 2, 3, 4, 5, 6 and 7, the directional radar transmitting and receiving device includes asensor circuit board1 integrated with amicrowave oscillator8, a transmittingantenna9, and areceiving antenna10. Afirst copper wire2 and asecond copper wire3 are laid on thesensor circuit board1 and used as the transmittingantenna9 and the receivingantenna10 respectively. The transmittingantenna9 is configured to transmit a high-frequency microwave signal into an environment (e.g., a room), while thereceiving antenna10 receives the high-frequency microwave signal as reflected back from the environment. In some aspects, ashielding board4 is mounted facing one face of thesensor circuit board1. Theshielding board4 and the transmitting antenna/receiving antenna are on the two (e.g., opposite) faces of the sensor circuit board1 (e.g., the top and bottom faces or top and bottom sides, with respect to the orientation shown inFIG. 4, although embodiments of the present invention are not limited to any particular orientation of the structure—for example, if the structure were rotated such that the planes extended in a vertical direction, the faces may be referred to left and right faces), wherein theshielding board4 includes metal and directs the transmittingantenna9 to transmit directional high-frequency microwave signals (e.g., by reflecting signals emitted by the transmitting antenna9). (For example, the transmitting antenna and receiving antenna are on a first face of the sensor circuit board and theshielding board4 faces a second face of the sensor circuit board, the second face being opposite the first face.) Additionally, the shieldingboard4 directs the receivingantenna10 to receive the frequency-shifted signals that are reflected back.
In some embodiments, afirst copper wire2 and asecond copper wire3 are laid on the sensor circuit board1 (e.g., the first face of the sensor circuit board) and used as the transmittingantenna9 and the receivingantenna10 respectively. The transmittingantenna9 transmits the high-frequency microwave signal, while the receivingantenna10 receives the frequency-shifted signal reflected back by the transmitted microwave. A shieldingboard4 is mounted on one face of thesensor circuit board1. The shieldingboard4 and thefirst copper wire2 and thesecond copper wire3 are on the two opposite faces of thesensor circuit board1. Thefirst copper wire2 and thesecond copper wire3 are used as the transmittingantenna9 and the receivingantenna10 respectively. During operation, the shieldingboard4 directs the signals emitted by the transmittingantenna9 to form directional high-frequency microwave signals (e.g., a directional antenna pattern). The shieldingboard4 reflects high-frequency microwave signals to create a directional receiving antenna, improving or optimizing the use of directional transmitting and directional receiving of radar signals, reducing or avoiding false triggering, improving stability, and adapting to many kinds of application environments.
In some embodiments, thesensor circuit board1 is provided with a plurality offirst recesses11 distributed at intervals along afirst copper wire2 of the transmitting antenna9 (e.g., along the edges of the board, where thefirst copper wire2 is disposed). A plurality offirst copper pillars5 is embedded in the first recesses11. Thefirst copper wire2 electrically connects thesefirst copper pillars5 so that thefirst copper wire2 and thesefirst copper pillars5 are combined to improve the high-frequency microwave signal transmitting efficiency of the transmittingantenna9. In some embodiments, thesensor circuit board1 as described above is further provided with a plurality of second recesses12 distributed at intervals along asecond copper wire3 of the receiving antenna10 (e.g., in a central portion of thesensor circuit board1, where thesecond copper wire3 is disposed). A plurality ofsecond copper pillars6 is embedded in the second recesses12, wherein thesecond copper wire3 electrically connects thesesecond copper pillars6. Thesecond copper wire3 and thesecond copper pillars6 are combined so that the receivingantenna10 has a strengthened receiving of the frequency-shifted signal reflected back.
In some embodiments, the length of the transmittingantenna9 at the edge of thesensor circuit board1 may be elongated to broaden the transmitting antenna coverage. In some aspects, the length of the S-shaped (or U-shaped) receivingantenna10 is extended to increase its sensitivity and coverage. In some embodiments, a protrudedfirst copper wire5 and a protrudedsecond copper wire6 are arranged on the transmitting antenna at the edge of thesensor circuit board1 and on the S-shaped (or U-shaped) receivingantenna10 respectively to provide robust transmitting and receiving signals.
In some embodiments, amain control board7 is mounted on one face of the shieldingboard4, where themain control board7 faces the second face of the sensor circuit board1 (e.g., the face opposite the face on which thefirst copper wire2 and thesecond copper wire3 are located). The shieldingboard4 may be made of metal and may include a non-conductive film mounted on a face of the shielding board facing (e.g., in contact with) themain control board7. In some embodiments of the present invention, themain control board7 is between the shieldingboard4 and thesensor circuit board1. In some embodiments of the present invention, the shieldingboard4 is between themain circuit board7 and thesensor circuit board1.
In some embodiments, thesensor circuit board1 is provided with a plurality of second recesses12 distributed at intervals along thesecond copper wire3 of the receivingantenna10. A plurality ofsecond copper pillars6 are embedded in the second recesses12. Asecond copper wire3 electrically connects thesecond copper pillars6 so that thesecond copper wire3 and thesecond copper pillars6 are combined to improve the sensitivity of the receiving antenna in detecting the frequency-shifted signals that are reflected back (e.g., from the environment, such as a room).
In some embodiments, afirst copper wire2 used as the transmittingantenna9 is laid along the edge of thesensor circuit board1 to form a closed loop. Thesecond copper wire3 is in a shape of a frame or border. Thesecond copper wire3 of the receivingantenna10 is located in the middle of the sensor circuit board1 (e.g., in a central portion of thesensor circuit board1, away from the edges). Thesecond copper wire3 is surrounded byfirst copper wire2 forming a closed loop, and thesecond copper wire3 is in a S-shaped layout or in a U-shaped layout. This arrangement results in stronger transmitting signals and increased sensitivity when receiving radar signals. In some embodiments, amain control board7 is mounted on one face of the shieldingboard4, with a non-conductive film of the shieldingboard4 facing the main control board. Themain control board7 and thesensor circuit board1 face (or are on) the same face (or side) of the shieldingboard4. As shown inFIG. 7, apower supply circuit15, asignal amplifying circuit16, amain control chip17 and aswitch circuit19 are arranged on themain control board7. Thesignal amplifying circuit16 is configured to amplify an output signal from the sensor circuit board1 (e.g., from the receiving antenna10). The amplified signal is supplied to themain control chip17, which is configured to control theswitch circuit19 based on the output signal from the sensor circuit board1 (e.g., to close or connect a switch of theswitch circuit19 when the frequency shifted signal is detected and to open or disconnect the switch when the frequency shifted signal is no longer detected). When theswitch19 is closed, power is supplied to one ormore load appliances18, e.g., from AC mains.
In some embodiments, during operation, a high-frequency microwave signal of about 5.8 GHz is transmitted by the microwave oscillator of thesensor circuit board1 and is transmitted out into an environment (e.g., a room) by the transmitting antenna9 (a combination offirst copper wire2 and first copper pillars5) distributed around the sensor circuit board1 (e.g., located at the edges of the sensor circuit board). The S-shaped (or U-shaped) receiving antenna10 (a combination of thesecond copper wire3 and the second copper pillars6) receives the frequency-shifted signal reflection of the transmitted microwave due to triggering events, such as the movement of humans, cars and other large objects in the environment. Through frequency mixing and wave detection and other operations applied to the signal, the signal is output to the signal amplifying circuit and then is connected to the main control chip for analysis. Themain control board7 controls the operation of the switch circuit, so as to control the turning on of the load appliances.
Finally, it should be noted that the foregoing embodiment is merely intended for describing the technical solution of embodiments of the present invention, but embodiments of the present invention are not limited thereto. Although aspects of embodiments of the present invention are described in detail with reference to the foregoing example embodiments, it should be understood by those of ordinary skill in the art that the technical solution described with reference to the foregoing example embodiments may be modified or equivalent replacements may be made to some of the technical features therein. It will also be apparent to the skilled artisan that the embodiments described above are specific examples of a single broader invention that may have greater scope than any of the singular descriptions without departing from the spirit and scope of the present invention.