WO2020051942A1 - 监控设备 - Google Patents
监控设备 Download PDFInfo
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- WO2020051942A1 WO2020051942A1 PCT/CN2018/106930 CN2018106930W WO2020051942A1 WO 2020051942 A1 WO2020051942 A1 WO 2020051942A1 CN 2018106930 W CN2018106930 W CN 2018106930W WO 2020051942 A1 WO2020051942 A1 WO 2020051942A1
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- WIPO (PCT)
- Prior art keywords
- monitoring
- microwave
- component
- area
- sub
- Prior art date
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Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/50—Systems of measurement based on relative movement of target
- G01S13/52—Discriminating between fixed and moving objects or between objects moving at different speeds
- G01S13/56—Discriminating between fixed and moving objects or between objects moving at different speeds for presence detection
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/50—Systems of measurement based on relative movement of target
- G01S13/58—Velocity or trajectory determination systems; Sense-of-movement determination systems
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/02—Systems using reflection of radio waves, e.g. primary radar systems; Analogous systems
- G01S13/50—Systems of measurement based on relative movement of target
- G01S13/58—Velocity or trajectory determination systems; Sense-of-movement determination systems
- G01S13/62—Sense-of-movement determination
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N7/00—Television systems
- H04N7/18—Closed-circuit television [CCTV] systems, i.e. systems in which the video signal is not broadcast
Definitions
- the invention relates to the field of microwave monitoring, and more particularly to a monitoring device, wherein the monitoring system can monitor the monitored object by means of partition monitoring.
- the existing surveillance systems use two methods to monitor the monitored objects. One is to use microwave monitoring to monitor the monitored objects. One is to monitor the monitored object by using pictures.
- the size of the monitoring area is usually fixed after the monitoring system is debugged and installed.
- a monitoring system that uses a microwave monitoring method to monitor a monitored object is often unable to be monitored.
- a monitored object when a monitored object is monitored in a microwave manner, it can only be monitored whether the monitored object is in a monitoring area, and the approximate position of the monitored object in the monitored area cannot be further monitored. In some cases, if the approximate position of the monitored object in the monitored area and the relative movement direction of the monitored object cannot be obtained, it may cause unnecessary losses to the user.
- reversing radar installed on a car can often only monitor whether there is an obstacle in a predetermined monitoring area behind the vehicle. As for where the obstacle is located in the monitoring area behind the vehicle, it cannot be known through the reversing radar. At this time, the user can only make judgments by observing the rearview mirror. When the vehicle is traveling in an area with insufficient light, the results obtained through the rearview mirror observation often deviate, and a vehicle collision accident is prone to occur.
- While monitoring the monitored object in order to know the relative position and picture of the monitored object, users often use the method of image acquisition to monitor the monitored object.
- the monitoring system needs to keep working. In other words, no matter whether the monitored object appears in the monitored area, the monitoring system will present the objects appearing in the monitored area in the form of pictures. For some users, they do not want their private places such as houses and offices to be taken as pictures by the monitoring system for a long time, because this will easily expose their privacy, but these users also want to be able to The monitoring system can monitor these sudden conditions when the occurrence of the situation occurs. Obviously, the monitoring system in the prior art cannot solve the above problems.
- An object of the present invention is to provide a monitoring device, wherein the monitoring device can form a monitoring area and a concealed area to enable monitoring of a monitored object located in the monitoring area.
- Another object of the present invention is to provide a monitoring device, wherein the monitoring device is capable of the ring-shaped monitoring area and the hidden area surrounded by the monitoring area.
- Another object of the present invention is to provide a monitoring device, wherein the size of at least one of the monitoring area and the concealed area can be adjusted.
- Another object of the present invention is to provide a monitoring device, wherein the monitoring area formed by the monitoring device is divided into at least three areas after being partitioned, so by determining which of the sub-monitoring areas the monitored object is located , And further, it can be determined that the monitored object is located at a specific position in the monitoring area.
- Another object of the present invention is to provide a monitoring device, wherein the monitoring device includes at least two microwave monitoring components, wherein each of the microwave monitoring components forms a sub-monitoring area, and two adjacent microwave monitoring components The overlapping portion between the sub-monitoring areas formed by the components forms an overlapping sub-monitoring area, and the non-overlapping portions of the sub-monitoring areas formed by two adjacent microwave monitoring components each form a non-overlapping sub-monitoring area.
- the monitoring device can further perform partition monitoring on the monitored object.
- Another object of the present invention is to provide a monitoring device, wherein the monitoring device can adjust the horizontal direction of the sub-monitoring area formed by at least one of the microwave monitoring components, and can further adjust the concealment formed by the monitoring device. The extent size of the area.
- Another object of the present invention is to provide a monitoring device, wherein the monitoring device can adjust the angle between a wave tuning plate of at least one of the microwave monitoring components and a ground reference component of the microwave monitoring component, thereby enabling Adjusting the size of the monitoring area.
- Another object of the present invention is to provide a monitoring device, wherein the monitoring device can adjust the size of the monitoring area formed by the microwave monitoring device by adjusting the number of a radiation source of at least one of the microwave monitoring components. .
- Another object of the present invention is to provide a monitoring device, wherein the monitoring device is capable of adjusting the monitoring area formed by the microwave monitoring device by adjusting the arrangement of the radiation sources of at least one of the microwave monitoring components. the size of.
- the present invention provides a monitoring device, which includes:
- a device body A device body
- At least two microwave monitoring components each of which is mounted on the main body of the device, wherein the microwave monitoring components can jointly form a monitoring area and a hidden area.
- At least two of the microwave monitoring components are radiated in one direction to form a sub-monitoring area.
- the sub-monitoring areas formed by two adjacent microwave monitoring components can form an overlapping sub-monitoring area and an non-overlapping sub-monitoring area of each of the microwave monitoring components.
- the monitoring device includes at least three microwave monitoring components, and at least three of the microwave monitoring components can collectively form a continuous monitoring area.
- At least three of the microwave monitoring components can form a ring-shaped monitoring area and the hidden area surrounded by the monitoring area.
- each of the microwave monitoring components includes a component body, at least one radiation source, and a ground reference element, wherein the radiation source is disposed on the ground reference element and forms at least one radiation gap.
- the ground reference element is provided on the component body, and wherein the component body is provided on the device body.
- each of the microwave monitoring components includes at least one wave-adjusting plate, wherein the wave-adjusting plate is held on the component body and forms a preset angle with the ground reference component.
- each of the microwave monitoring components includes at least one pair of the wave adjusting plates.
- a pair of the wave-adjusting plates of each of the microwave monitoring components is arranged on the component body at intervals in the vertical direction.
- At least one of the wave-adjusting plates of each of the microwave monitoring components is mounted on the component main body in a manner that the preset angle formed between the microwave modulation component and the reference ground element is adjustable.
- the wave-adjusting plate on the upper side of the radiation source in each of the microwave components is installed in a manner that the preset angle formed between the wave-adjusting plate and the ground reference element is adjustable.
- the component body is adjustable.
- the wave-adjusting plate on the lower side of the radiation source in each of the microwave components is installed in a manner that the preset angle formed between the wave-adjusting plate and the ground reference element is adjustable.
- the component body is adjustable.
- the monitoring device includes at least one driving component, wherein at least one of the wave-adjusting plates of each of the microwave monitoring components is rotatably connected to the driving component.
- the number of the radiation sources of at least one of the microwave monitoring components is set to at least two.
- At least two of the radiation sources of at least one of the microwave monitoring components are arranged on the ground reference element at intervals in the horizontal direction.
- At least two of the radiation sources of at least one of the microwave monitoring components are arranged on the ground reference element at intervals in the vertical direction.
- the component body of each of the microwave monitoring components is made of an integrally formed flexible board.
- the monitoring device includes at least one image acquisition component, wherein the image acquisition component is disposed on the device main body so as to face the monitoring area.
- the image acquisition component is connected to each of the microwave monitoring components, and when the microwave monitoring component detects an monitored object located in the monitoring area, the image acquisition component is Turn on to obtain an image of the monitored object.
- the monitoring device includes a processing unit, wherein the image acquisition unit and each of the microwave monitoring units are connected to the processing unit, and wherein the image acquisition unit is rotatably mounted on the processing unit.
- the device main body wherein when the processing unit receives at least one of the microwave monitoring units and monitors a monitored object located in the monitoring area, the processing unit controls the image acquisition unit to turn on and drives the image acquisition The component is rotated toward the monitored object.
- the device body includes a device body and an adjustable base, wherein each of the microwave monitoring components is installed on the device body, and the device body is connected to the adjustable base. On the upper end, when the adjustable base is adjusted, the microwave monitoring components installed on the device body are supported to different heights.
- the adjustable base is implemented as a telescopic rod.
- FIG. 1 is a schematic structural diagram of a monitoring device according to an embodiment of the present invention.
- FIG. 2A and FIG. 2B respectively show schematic diagrams of two different working states of the monitoring device in a case of the first embodiment of the present invention.
- 3A and 3B respectively show schematic diagrams of the monitoring device in two different working states in another case of the first embodiment of the present invention.
- FIG. 4 is a schematic diagram showing two different working states of the monitoring device controlling an image acquisition component for monitoring in a state of the first embodiment of the present invention.
- FIG. 5 shows a state diagram of a monitoring device according to a second embodiment of the present invention.
- FIG. 6 is a schematic diagram showing a state after at least one of the microwave monitoring components in the monitoring device according to the second embodiment of the present invention is rotated.
- FIG. 7A and FIG. 7B respectively show schematic diagrams of the monitoring device in two different working states according to a second embodiment of the present invention.
- FIG. 8 shows a state diagram of a monitoring device according to a third embodiment of the present invention.
- FIG. 9A shows a schematic diagram of a monitoring device according to a fourth embodiment of the present invention.
- FIG. 9B shows a schematic diagram of a wave-adjusting plate of a microwave monitoring component in the monitoring device of the fourth embodiment of the present invention after being adjusted.
- FIG. 10A is a schematic diagram of a monitoring device according to a fifth embodiment of the present invention.
- FIG. 10B is a schematic diagram of the monitoring device according to a modified embodiment of the fifth embodiment of the present invention.
- FIG. 11A shows a schematic diagram of a monitoring device according to a sixth embodiment of the present invention.
- FIG. 11B shows a schematic diagram of a wave-adjusting plate of a microwave monitoring component in the monitoring device of the sixth embodiment of the present invention after being adjusted.
- FIG. 11C shows a schematic diagram of another wave-adjusting plate of a microwave monitoring component in the monitoring device of the sixth embodiment of the present invention after being adjusted.
- FIG. 12 shows a schematic diagram of a monitoring device according to a seventh embodiment of the present invention.
- FIG. 13 shows a schematic diagram of the monitoring device according to the modified embodiment of the seventh embodiment of the present invention.
- FIG. 14 is a schematic structural diagram of a monitoring device with adjustable height according to the present invention.
- the term “a” should be understood as “at least one” or “one or more”, that is, in one embodiment, the number of one element may be one, and in other embodiments, the number of The number can be multiple, and the term “a” cannot be understood as a limitation on the number.
- "previous” and “rear” refer to the order of time in some places and the logical order in some places. The invention is not limited in this respect.
- a monitoring device 100 according to a preferred embodiment of the present invention is disclosed and explained in the following description, wherein the monitoring device 100 can form at least one monitoring area 200 so as to be opposite to At least one monitored object 300 in the monitoring area 200 performs monitoring.
- the monitoring device 100 includes a device main body 10 and at least two microwave monitoring components 20, wherein each of the microwave monitoring components 20 is mounted on the device main body 10.
- Each of the microwave monitoring components 20 forms a sub-monitoring area 201, and the sub-monitoring area 201 of the monitoring device 100 constitutes the monitoring area 200.
- an overlapping portion between two adjacent sub-monitoring areas 201 is an overlapping sub-monitoring area 2011, and a non-overlapping portion between two adjacent sub-monitoring areas 201 is an unoverlapping sub-monitoring Zone 2012.
- the overlapping sub-monitoring area 2011 and the non-overlapping sub-monitoring area 2012 constitute the monitoring area 200.
- the monitoring device 100 in the present invention can not only monitor the monitored object 300 located in the monitoring area 200, but also monitor that the monitored object 300 is located in the monitoring area 100.
- the monitoring device 100 can monitor whether the monitored object 300 is located in the overlapping sub-monitoring area 2011 or in the non-overlapping sub-monitoring area 2012.
- Each of the microwave monitoring components 20 includes a component main body 21, at least one radiation source 22, and at least one and a ground reference element 23, wherein the radiation source 22 is disposed at intervals on the ground reference element 23 and communicates with the ground reference element 23.
- a radiation gap is formed between the ground reference elements 23, wherein the ground reference element 23 is disposed on the component body 21.
- the component body 21 is mounted on the device body 10.
- the component body 21 and the radiation source 22 may be implemented to include a circuit board and an oscillating circuit or an oscillating circuit.
- the present invention is not limited in this aspect. limit. It is worth mentioning that, in the present invention, the number of the microwave monitoring components 20 mounted on the device main body 10 is not limited.
- the monitoring device 100 includes two microwave monitoring components 20, which are 20a and 20b, respectively.
- the microwave monitoring component 20a forms a sub-monitoring area 201a
- the microwave monitoring component 20b forms a sub-monitoring area 201b.
- An overlapping sub-monitoring area 2011 is formed between the sub-monitoring area 201a and the sub-monitoring area 201b.
- a portion of the sub-monitoring area 201a that does not overlap with the sub-monitoring area 201b forms an non-overlapping sub-monitoring area 2012a of the sub-monitoring area 201a.
- the monitoring device 100 when the monitored object 300 appears in the overlapping sub-monitoring area 2011, the monitoring device 100 can monitor the monitored object 300 at the same time Appears in the sub-monitoring area 201a formed by the microwave monitoring component 20a and the sub-monitoring area 201b formed by the microwave monitoring component 20b. Therefore, the monitoring device 100 can determine that the monitored object 300 is the overlapping sub-monitoring area 2011 in the monitoring area 200.
- the monitoring device 100 can monitor that the monitored object 300 does not appear simultaneously in the microwave monitoring component 20a
- the formed sub-monitoring area 201a and the sub-monitoring area 201b formed by the microwave monitoring component 20b only appear in the sub-monitoring area 201a formed by the microwave monitoring component 20a.
- the monitoring device 100 can determine that the monitored object 300 is located in the non-overlapping sub-monitoring area 2012a of the monitoring area 200. In this way, the monitoring device 100 can not only monitor whether the monitored object 300 appears in the monitoring area 200, but also determine whether the monitored object 300 is located in the monitoring area 200. position.
- the monitoring device 100 includes a processing unit 30, wherein the processing unit 30 is communicably connected to each of the microwave monitoring units 20 to receive each of the microwave monitoring units. 20 is a monitoring signal collected related to the position of the monitored object 300.
- the processing component 30 may be implemented as a chip having a processing analysis function or a device component including the chip, and the present invention is not limited in this respect.
- the monitoring device 100 includes at least one driving component 40.
- Each of the microwave monitoring components 20 is drivably connected to the driving component 40 so that the radiation direction formed by the microwave monitoring component 20 is adjusted in a horizontal direction, and then at least one of the microwave monitoring components 20 is adjusted to form The sub-monitoring area 201 is oriented horizontally.
- the microwave monitoring component 20 formed between two adjacent microwave monitoring components 20 is adjusted.
- the size of the non-overlapping sub-monitoring area 2011 is adjusted accordingly.
- the driving component 40 is controllably connected to the processing component 30, wherein the processing component 30 controls the driving component 40 by analyzing the monitoring signal related to the position of the monitored object 300. A control signal.
- the driving component 40 adjusts the horizontal direction of the sub-monitoring area 201 formed by at least one of the microwave monitoring components 20 correspondingly based on the control signal. Therefore, the monitored object 300 is kept or moved out of the sub-monitoring area 201 formed by two adjacent microwave monitoring components 20.
- the microwave monitoring component 20 is implemented to be drivably connected to the driving component 40 as a whole, so that the horizontal direction of the sub-monitoring area 201 formed by the microwave monitoring component 20 faces Be adjusted.
- each of the driving components 40 can be implemented as a motor, wherein the driving component 40 is communicably connected to the processing component 30, and the driving component 40 is disposed at The microwave monitoring component 20, and the driving component 40 is further driven to adjust the level of the sub-monitoring area 201 formed by at least one of the microwave monitoring components 20 based on the control signal formed by the processing component 30 The direction is facing.
- the type of the motor of the driving member 40 is not the focus of the present invention, and the invention is not limited in this respect.
- the monitoring device 100 includes two of the microwave monitoring components 20, as in the first embodiment described above.
- at least one of the two microwave monitoring components 20 is connected to one of the driving components 40, so that the sub-monitoring area 201a formed by the microwave monitoring component 20a is formed.
- the horizontal direction and position of can be changed as the microwave monitoring part 20a is driven.
- the sub-monitoring area 201 formed by the microwave monitoring component 20 that can be driven by the driving component 40 of the two microwave monitoring components 20 is defined. Is a reference monitoring area, and the sub-monitoring area 201 formed by another microwave monitoring component 20 is defined as a positioning monitoring area.
- the monitoring device 100 can first determine that the monitored object 300 is located in the overlapping sub-monitoring area 2011, the microwave monitoring The non-overlapping sub-monitoring area 2012a of the component 20a or the non-overlapping sub-monitoring area 2012b of the microwave monitoring component 20b.
- the processing component 30 forms the control signal correspondingly based on the formed monitoring signal, so as to drive at least one of the microwave monitoring components 20 to rotate, so that the formed sub-monitoring area 201 is used for the positioning.
- Sub-monitoring area is a reference monitoring area
- the sub-monitoring area 201 formed by another microwave monitoring component 20 is defined as a positioning monitoring area.
- the processing unit 30 when the monitored object 300 is located in the overlapping sub-monitoring area 2011, the processing unit 30 forms the control related to the monitored object 300 being located in the overlapping sub-monitoring area 2011 Signal, and correspondingly define the sub-monitoring area 201 formed by one of the microwave monitoring components 20 as the positioning monitoring area, and control the driving component 40 to drive one of the microwave monitoring components 20 to rotate to adjust A horizontal direction of the positioning monitoring area is oriented.
- the processing component 30 defines the sub-monitoring area 201a formed by the microwave monitoring component 20a as the positioning monitoring area, and defines the sub-monitoring area 201b formed by the microwave monitoring component 20b. Is the reference monitoring area.
- the processing component 30 adjusts the horizontal direction of the sub-monitoring area 201a formed by the microwave monitoring component 20a accordingly, so that the sub-monitoring area 201a and the microwave monitoring component 20b formed by the microwave monitoring component 20a The size of the overlapping sub-monitoring area 2011 of the overlapped portion formed between the sub-monitoring areas 201b is changed.
- the processing unit 30 can determine the specific location of the monitored object 300 in the monitoring area 200 formed by the monitoring device 100 by analyzing the data information related to the microwave monitoring unit 20a after the rotation. For example, in this embodiment, the processing unit 30 can determine the specific position of the monitored object 300 in the monitoring area 200 by analyzing the rotation angle, speed, and time of the microwave monitoring unit 20a.
- the processing component 30 can form information about the monitored object.
- the processing component 30 forms a control signal based on the monitoring signal. Accordingly, the processing component 30 defines the sub-monitoring area 201 formed by one of the microwave monitoring components 20 as the positioning monitoring area, and controls
- the driving component 40 drives one of the microwave monitoring components 20 to rotate to adjust the horizontal direction of the positioning monitoring area.
- the processing component 30 defines the sub-monitoring area 201b formed by the microwave monitoring component 20b as the positioning monitoring area, and defines the sub-monitoring area 201a formed by the microwave monitoring component 20a. Is the reference monitoring area.
- a control signal is then generated for controlling the driving component 40 to drive the microwave monitoring component 20a to adjust the range of the overlapping sub-monitoring area 2011, so that the monitored object 300 moves into the overlapping sub-monitoring area. 2011.
- the processing component 30 can further determine that the monitored object 300 is located in the sub-monitoring area 201a formed before the microwave monitoring component 20b is not driven. Specific location.
- the processing component 30 can form a signal that the monitored object 300 is located in the microwave monitoring component 20b.
- the processing unit 30 Based on the monitoring signal, the processing unit 30 then generates a control signal related to controlling the driving unit 40 to drive the microwave monitoring unit 20b to rotate.
- the microwave monitoring component 20a When the monitored object 300 appears alone in the sub-monitoring area 201 formed by the microwave monitoring component 20b, the microwave monitoring component 20a will be driven so that the monitored object 300 gradually moves into the microwave In the sub-monitoring area 201a formed by the monitoring component 20a, the processing component 30 can further determine that the monitored object 300 is located in the microwave monitoring component 20b based on the recorded data related to the movement of the microwave monitoring component 20a. The specific location of the sub-monitoring area 201b.
- the monitoring area 201a formed by the monitoring device 100 is a dynamic monitoring area, so that the monitoring device 100 can not only be located in the area opposite to the area.
- the monitored object 300 in the monitoring area 200 performs monitoring, and a specific position of the monitored object 300 in the monitoring area 200 can also be monitored.
- each of the microwave monitoring components 20 in the monitoring device 100 is drivably connected to the driving component 40 so that each of the All of the sub-monitoring areas 201 formed by the microwave monitoring component 20 can be defined as the positioning monitoring area.
- the processing component 30 can determine the specific position of the monitored object 300 in the monitoring area 200 by calculating data related to each of the microwave monitoring components 20 after being rotated.
- the monitoring device 100 includes at least one image acquisition component 50, wherein the image acquisition component 50 is communicably connected to the processing component 30 to perform the processing during the processing.
- the component 30 After calculating the specific position of the monitored object 300 in the monitoring area 201, the component 30 starts the image acquisition component 50 to obtain an image of the monitored object 300 located in the monitoring area 201. That is, in the present invention, the image acquisition component 50 is in a closed state before the monitoring device 100 acquires a specific position of the monitored object 300 in the monitoring area 200. In other words, before the monitored object 300 appears, the image acquisition component 50 will not acquire any information. Therefore, while monitoring the monitored object 300, the monitoring device 100 can acquire an image of the monitored object 300 only when the monitored object 300 appears.
- one image acquisition component 50 may be provided in each of the overlapping sub-monitoring area 2011 and the non-overlapping sub-monitoring area 2012, and may be provided in the overlapping sub-monitoring area 2011 and the non-overlapping
- Each of the image acquisition components 50 in the sub-monitoring area 2012 is initially in a closed state.
- the processing component 30 acquires the monitoring signal related to the position of the monitored object 300 in the monitoring area 200
- the image acquisition component 50 in the non-overlapping sub-monitoring area 2012 is activated to capture the monitored object 300.
- the monitoring device 100 includes a rotatable image acquisition component 50, wherein the image acquisition component 50 is rotatably connected to the drive. Part 40.
- the processing component 30 monitors the overlapping sub-monitoring area 2011 and / or the non-overlapping sub-monitoring area 2012 where the monitored object 300 is located in the monitoring area 201 in the monitoring area 201
- the The image acquisition component 50 is driven to maintain a horizontal direction toward a specific position of the monitored object 300 in the monitoring area 200 to acquire an image of the monitored object 300.
- the image acquisition component 50 is rotatably provided in the monitoring area 200, but those skilled in the art can understand that this is not a limitation on the present invention.
- the microwave monitoring component 20 detects moving objects by using the microwave Doppler effect principle, and those skilled in the art are well aware that detecting moving objects by using the microwave Doppler effect principle can detect
- the speed and distance parameters of the detected moving object are obtained from the output Doppler signal. Therefore, in combination with the angle and / or the monitored object 300 obtained by the monitoring device 100 of the present invention in the monitoring area 200
- the parameter of the movement direction can further generate relative coordinate data of the monitored object 300 in the monitoring area 200, so that the monitoring area 200 locates the monitoring object 300 and obtains the specific position of the monitored object 300 .
- the monitoring device 100 can first determine the specific position of the monitored object 300 in the monitoring area 200, and then, after the image acquisition component 50 is activated, it can quickly Perform fixed focus shooting on the monitored object 300. That is, the monitored object 300 whose position is determined is more convenient for the image acquisition component 50 to perform focusing.
- the monitoring device 100 includes three microwave monitoring components 20.
- the three microwave monitoring components 20 are a microwave monitoring component 20a, a microwave monitoring component 20b, and a microwave monitoring component 20c.
- the size of the range of the monitoring area 200 formed by the monitoring device 100 may be the same as or different from the size of the range of the monitoring area 200 formed by the monitoring device 100 in the above embodiment.
- the present invention Not subject to this limitation.
- the sub-monitoring areas 201a and 201b formed by the microwave monitoring component 20a and the microwave monitoring component 20b are respectively different from the microwave monitoring component 20a and the microwave monitoring component 20b in the above embodiment.
- the sizes of the formed sub-monitoring areas 201a and 201b may be the same or different.
- the size of the monitoring area 200 formed by the monitoring device 100 in this embodiment is different from the size of the range of the monitoring area 200 formed by the monitoring device 100 in the foregoing embodiment.
- the description is given by way of example, but those skilled in the art can understand that the present invention is not limited in this respect.
- only the ranges of the sub-monitoring areas 201a and 201b formed by the microwave monitoring component 20a and the microwave monitoring component 20b are the same as those in the foregoing embodiment, but the present invention is described as an example. Nor is it restricted in this regard.
- a portion where the sub-monitoring area 201a formed by the microwave monitoring component 20a and the sub-monitoring area 201b formed by the microwave monitoring component 20b overlap is defined as a first overlapping sub-monitoring Zone 2011a.
- An overlap between the sub-monitoring area 201a formed by the microwave monitoring component 20b and a sub-monitoring area 201b formed by the microwave monitoring component 20c is defined as a second overlapping sub-monitoring area 2011b.
- An overlapping portion between the sub-monitoring area 201c formed by the microwave monitoring component 20c and the sub-monitoring area 201a formed by the microwave monitoring component 20a is defined as a third overlapping sub-monitoring area 2011c.
- the non-overlapping portion of the sub-monitoring area 201a formed by the microwave monitoring component 20a and the sub-monitoring area 201b formed by the microwave monitoring component 20b is defined as a first non-overlapping sub-monitoring area 2012a.
- the non-overlapping portion of the sub-monitoring area 201b formed by the microwave monitoring component 20b and the sub-monitoring area 201c formed by the microwave monitoring component 20c is defined as a second non-overlapping sub-monitoring area 2012b.
- a non-overlapping portion of the sub-monitoring area 201c formed by the microwave monitoring component 20c and the sub-monitoring area 201a formed by the microwave monitoring component 20a is defined as a third non-overlapping sub-monitoring area 2012c.
- the monitoring area 200 formed by the monitoring device 100 is divided into six areas, that is, the first overlapping sub-monitoring area 2011a and the second overlapping The sub-monitoring area 2011b, the third overlapping sub-monitoring area 2011c, the first non-overlapping sub-monitoring area 2012a, the second non-overlapping sub-monitoring area 2012b, and the third non-overlapping sub-monitoring area 2012c.
- the monitoring device 100 can form six parts for monitoring, so that the monitoring device 100 can not only monitor whether the monitored object 300 is in the monitoring area.
- the monitoring area 200 can also determine which specific area of the monitored object 300 is in the monitoring area 200.
- the sub-monitoring areas formed by the microwave monitoring component 20a, the microwave monitoring component 20b, and the microwave monitoring component 20c are continuous with each other, but in the art, The skilled person can understand that the monitoring area 200 formed by the microwave monitoring component 20a, the microwave monitoring component 20b, and the microwave monitoring component 20c can also be implemented as a discontinuous sector. At this time, There may be no third overlapping sub-monitoring area 2011c between the microwave monitoring component 20a and the microwave monitoring component 20c.
- the monitoring device 100 includes at least one driving component 40. At least one of the microwave monitoring members 20 is rotatably connected to the driving member 40.
- the driving component 40 is connected to the microwave monitoring component 20b so that the microwave monitoring component 20b can be driven by the driving component 40.
- the monitoring device 100 includes the processing section 30, wherein the processing section 30 is communicably connected to the driving section 40 and the microwave monitoring section 20a, the microwave monitoring section 20b, and the microwave monitoring Component 20c. After the processing component 30 obtains the monitoring signal related to the position of the monitored object 300 in the monitoring area 200, it forms the control signal accordingly.
- the processing unit 30 controls the driving unit 40 to drive the microwave monitoring unit 20b to rotate according to the control signal.
- the microwave monitoring component 20b When the microwave monitoring component 20b is driven and rotated, the first overlapping sub-monitoring area 2011a, the second overlapping sub-monitoring area 2011b, the first non-overlapping sub-monitoring area 2012a, and the second non-overlapping The sizes of the sub-monitoring area 2012b and the third non-overlapping sub-monitoring area 2012c change accordingly.
- the driving component 40 and the processing component 30 can further obtain that the microwave monitoring component 20b occurs when the monitored object 300 removes the first overlapping sub-monitoring area 2011a or the second overlapping sub-monitoring area 2011b.
- Relevant data on rotation further determines the specific position of the monitored object 300 in the monitoring area 201.
- the processing component 30 is located according to the location of the monitored object 300.
- the monitoring signal related to the first sub-monitoring area 201a further forms the control signal.
- the driving part 40 connected to the microwave monitoring part 20b is correspondingly turned on and drives the microwave monitoring part 20b to rotate according to the control signal, so as to adjust the second sub-element formed by the microwave monitoring part 20b.
- the monitoring area 201b faces in the horizontal direction.
- the processing unit 30 can determine the specific position of the monitored object 300 by calculating data about the rotation of the microwave monitoring unit 20b. That is, at this time, the first sub-monitoring area 201a formed by the microwave monitoring component 20a and the third sub-monitoring area 201c formed by the microwave monitoring component 20c will serve as the reference monitoring area, and the The second sub-monitoring area 201b formed by the microwave monitoring component 20b will serve as the positioning monitoring area.
- the microwave monitoring component 20a, the microwave monitoring component 20b, and the sub-monitoring area 201 formed by the microwave monitoring component 20c are continuous with each other, and three of the microwave monitoring components 20
- a hidden area 202 is formed, wherein each sub-monitoring area 201 surrounds the hidden area 202.
- the monitoring device 100 does not monitor objects located in the hidden area 202. Therefore, using the monitoring device 100 of the present invention can not only form the monitoring area 201 for monitoring the monitored object 300, but also form a hidden area 202, and the formed hidden area 202 is located in the closed area.
- the monitored area 201 is formed around the hidden area 202. Therefore, when the monitoring device 100 of the present invention is used for monitoring, the user can set his own private space as the hidden area 202. In addition, it can monitor the area outside the private space while not exposing its own private space.
- the monitoring device 100 includes at least one image acquisition part 50, wherein the image acquisition part 50 is communicably connected to the processing part 30 so that the processing part 30 According to the monitoring signal related to the position of the monitored object 300 in the monitoring area 201, the image acquisition component 50 is activated, so that the image acquisition component 50 acquires all images located in the monitoring area 201.
- the image of the monitored object 300 is described. That is, in the present invention, the image acquisition component 50 is in a closed state before the monitoring device 100 acquires a specific position of the monitored object in the monitoring area 201. In other words, before the monitored object 300 appears, the image acquisition component 50 will not obtain any information. Therefore, the monitoring device 100 can monitor the monitored object 300, and only Obtaining an image of the monitored object 300 when the monitored object 300 appears.
- a user's private space is set as the hidden area 202 formed by the monitoring device 100, and the monitoring area 201 formed by the monitoring device 100 is set as Areas other than the user's private space that need to be monitored can monitor other parts of the user's private space.
- one image acquisition component 50 may be provided in each of the overlapping sub-monitoring area 2011 and the non-overlapping sub-monitoring area 2012, and set in the overlapping sub-monitoring area 2011 and Each of the image acquisition components 50 of the non-overlapping sub-monitoring area 2012 is initially in a closed state.
- the processing unit 30 calculates the position of the monitored object 300 in the monitoring area 300, the overlapping sub-monitoring area 2011 or / and the non-overlapping sub-monitoring corresponding to the monitored object 300
- the image acquisition component 50 in the area 2012 is activated to capture the monitored object 300.
- the monitoring device 100 includes a rotatable image acquisition component 50, wherein the image acquisition component 50 is rotatable. It is rotatably connected to the driving member 40.
- the processing component 30 monitors the overlapping sub-monitoring area 2011 and / or the non-overlapping sub-monitoring area 2012 where the monitored object 300 is located in the monitoring area 201 in the monitoring area 201, the The image acquisition component 50 is driven to maintain a horizontal direction toward a specific position of the monitored object 300 in the monitoring area 200 to acquire an image of the monitored object 300.
- the monitoring device 100 is implemented to include four of the microwave monitoring components 20, specifically, a microwave monitoring component 20a, a microwave monitoring component 20b, and a microwave.
- the microwave monitoring component 20a, the microwave monitoring component 20b, the microwave monitoring component 20c, and the microwave monitoring component 20d respectively form a sub-monitoring area 201a, a sub-monitoring area 201b, a sub-monitoring area 201c, and One child monitoring area 201d.
- two adjacent microwave monitoring components 20 form an overlapping sub-monitoring area 2011, respectively.
- a first overlapping sub-monitoring area 2011a is formed between the sub-monitoring area 10a and the sub-monitoring area 10b
- a second overlapping sub-monitoring is formed between the sub-monitoring area 10b and the sub-monitoring area 10bc.
- Area 2011b a third overlapping sub-monitoring area 2011c is formed between the sub-monitoring area 10b and the sub-monitoring area 10c
- a fourth overlapping sub-monitoring is formed between the sub-monitoring area 10c and the sub-monitoring area 10a Zone 2011d.
- a non-overlapping portion between the sub-monitoring area 201a, the sub-monitoring area 201b, and the sub-monitoring area 201d is a first non-overlapping sub-monitoring area 2012a.
- the non-overlapping portion between the sub-monitoring area 201b, the sub-monitoring area 201a, and the sub-monitoring area 201c is a second non-overlapping sub-monitoring area 2012b, and the sub-monitoring area 201c and the sub-monitoring area 201b
- the non-overlapping portion between the sub-monitoring area 201d and the sub-monitoring area 201d is a third non-overlapping sub-monitoring area 2012c.
- the monitoring device 100 monitors the monitored object 300 by dividing the monitoring area 200 into a ring-shaped eight areas, so that it can not only monitor the monitored object 300 Whether it is located in the monitoring area 200, and can also monitor the specific position of the monitored object 300 in the monitoring area 200.
- each of the microwave monitoring components 20 is rotatably mounted by a motor, respectively.
- the microwave monitoring unit 20a, the microwave monitoring unit 20b, the microwave monitoring unit 20c, and the microwave monitoring unit 20d are communicably connected to the processing unit 30, respectively.
- the processing component 30 generates the control signal according to the monitoring signal related to the position of the sub-monitoring area 201 where the monitored object 300 is located, so as to control the driving component 40 by activating the driving component 40.
- the microwave monitoring unit 20 rotates.
- the processing component 30 analyzes the data related to the deflection of the microwave monitoring component 20 before and after the rotation and the position change of the monitored object 300, and then determines that the monitored object 300 is in the monitoring area 200. Specific location.
- the monitoring device 100 can monitor that the monitored object 300 appears simultaneously in all The sub-monitoring area 201a and the sub-monitoring area 201b formed by the microwave monitoring component 20a and the microwave monitoring component 20b, respectively.
- the processing component 30 controls the microwave monitoring component 20b forming the second sub-monitoring area 201b accordingly to reduce the horizontal direction of the first overlapping sub-monitoring area 2011a so that the monitored The object gradually moves out of the first overlapping sub-monitoring area 2011a.
- the processing component 30 calculates displacements generated by the microwave monitoring component 20a and the microwave monitoring component 20b, thereby determining a specific position of the monitored object 300 in the monitoring area 200.
- the monitoring device 100 further includes at least one image acquisition component 50.
- the monitoring device 100 includes an image acquisition component 50, wherein the image acquisition component 50 is rotatably mounted to the device body 10.
- the image acquisition section 50 is communicably connected to the processing section 30.
- the processing unit 30 obtains multiple signals related to the area where the monitored object 300 is monitored by the microwave monitoring unit 20, the processing unit 30 drives the image acquisition unit 40 to rotate, so that the The image acquisition component 50 acquires an image of the monitored object 300 toward the sub-monitoring area 201 where the monitored object 300 is located.
- the monitoring device 100 includes a plurality of the image acquisition components 50.
- the first overlapping sub-monitoring area 2011a, the second overlapping sub-monitoring area 2011b, the third overlapping sub-monitoring area 2011c, the first overlapping sub-monitoring area 2011d, and the first unsupervised area The overlapping sub-monitoring area 2012a, the second non-overlapping sub-monitoring area 2012b, the third non-overlapping sub-monitoring area 2012c, and the first non-overlapping sub-monitoring area 2012d are all provided with the image acquisition component 50.
- the processing unit 30 Before the processing unit 30 obtains the monitoring signal related to the position of the monitored object 300, it is set in the first overlapping sub-monitoring area 2011a, the second overlapping sub-monitoring area 2011b, and the third overlapping Sub-monitoring area 2011c, the first overlapping sub-monitoring area 2011d, the first non-overlapping sub-monitoring area 2012a, the second non-overlapping sub-monitoring area 2012b, the third non-overlapping sub-monitoring area 2012c, and the The image acquisition component 50 of the first non-overlapping sub-monitoring area 2012d does not perform image acquisition work.
- the processing unit 30 Only after the processing unit 30 obtains a plurality of signals related to the area where the monitored object 300 is monitored by the microwave monitoring unit 20, the processing unit 30 drives a signal corresponding to the location of the monitored object 300.
- the image acquisition component 50 of the sub-monitoring area 201 performs image acquisition work.
- the image acquisition component 50 is not turned on. That is, until the monitoring device 100 acquires the specific sub-monitoring area 201 to which the monitored object 300 belongs, the image acquisition component 50 will not acquire an image. Therefore, the monitoring device 100 provided by the present invention can not only determine whether the monitored object 300 exists in the monitoring area 200, but also enable the monitoring device only when the monitored object appears in the monitoring area.
- the image acquisition part 50 of the monitoring device 100 acquires an image.
- each of the microwave monitoring components 20 in the monitoring device 100 includes at least one wave-adjusting plate 24, wherein the wave-adjusting plate 24 is held on the component body 21 and is in contact with the ground reference element 23. A predetermined angle is formed between them.
- the wave adjusting plate 24 is disposed on a path of microwave radiation so as to be able to limit the microwave to a predetermined area.
- the number of the wave tuning plates 24 may be set to one or more, and the present invention is not limited in this respect.
- each of the microwave monitoring components 20 may be provided with two of the wave adjusting plates 24, and one of the wave adjusting plates 24 is provided at the reference ground element 23.
- another wave tuning plate 24 is disposed on the right side of the ground reference element 23, that is, two wave tuning plates 24 are horizontally disposed on the ground reference element 23.
- Each of the wave-adjusting plates 24 is drivably connected to the driving component 40, so that by driving at least one of the wave-adjusting plates 24 of the microwave monitoring component 20, the wave-adjusting plate 24 and The preset angle formed between the ground reference elements 23 is adjusted, and the orientation of the sub-monitoring area 201 formed by each of the microwave monitoring components 20 in the horizontal direction can be adjusted, so that the adjacent The size of the overlapping sub-monitoring area 2011 formed between the two microwave monitoring components 20 is adjusted.
- the height direction in which the device main body 10 extends is a vertical direction
- the height direction in which the ground reference element 23 is located and extends with the device main body 10 is A horizontal direction.
- each of the wave adjusting plates 24 of each of the microwave monitoring components 20 can be adjusted.
- the description will be made by taking the predetermined angle between one of the wave-adjusting plate 24 and the ground reference element 23 of one of the microwave monitoring components 20 as an example.
- the way in which the wave-adjusting plate 24 is adjusted can be manually adjusted, or it can be installed in the device body 10 and connected to the wave-adjusting plate 24.
- the drive member 40 is adjusted.
- the wave-adjusting plate 24 can be implemented to be controlled by the processing unit 30 to drive the driving unit 40 to be automatically adjusted in a manner of automatic rotation. Accordingly, in this embodiment, when the monitored object 300 appears in
- the distance between two adjacent microwave monitoring components 20 in the monitoring device 100 can also be made.
- the overlapping sub-regions 2011 have different sizes, which in turn makes the sizes of the monitoring regions 200 formed by the monitoring device 100 different.
- FIGS. 10A and 10B when the radiation sources 22 of each of the microwave monitoring components 20 are set to two, the size of the sub-monitoring area 201 formed by the corresponding microwave monitoring component 20 decreases. Small, thereby making the entire monitoring area 200 smaller. That is, in FIG. 9A, FIG. 10A, and FIG.
- each of the microwave monitoring components 20 includes one of the radiation sources 22, wherein the radiation source 22 is mounted on the reference ground element 23.
- each of the microwave monitoring components 20 includes two of the wave-adjusting plates 24, one of which is disposed on the ground reference element 23 on the upper side of the radiation source 22, and the other of the wave-adjusting plates 24 A wave plate 24 is disposed on the ground reference element 23 on the lower side of the radiation source 22.
- the two wave-adjusting plates 24 are disposed in a vertical direction. Therefore, when each of the microwave monitoring components 20 works, the wave-adjusting plate 24 of each of the microwave monitoring components 20 limits the microwaves radiated by the radiation source 22 to a predetermined area, thereby forming the Sub monitoring area 201.
- the microwave monitoring component 20 forms at least two of the sub-monitoring areas 201 while simultaneously forming the hidden area 202.
- the wave control plate 24 of each of the microwave monitoring components 20 is disposed in a vertical direction, the width of the sub-monitoring area 201 formed by each of the microwave monitoring components 20 in the horizontal direction is changing.
- the sub-monitoring area formed by the microwave monitoring component 20 The size of 201 is different.
- the preset angle between the wave tuning plate 24 and the reference ground element 23 is different from any one of the ground reference elements 23 provided on the upper or lower side of the radiation source 22
- the sizes of the sub-monitoring areas 201 formed by the microwave monitoring component 20 are different, but also the sizes of the hidden areas 202 formed are correspondingly different.
- the hidden area 202 and the hidden area 202 of different sizes can be formed.
- Monitoring area 200 by adjusting the preset angle between the wave-adjusting plate 24 and the ground reference element 23, the hidden area 202 and the hidden area 202 of different sizes can be formed.
- Monitoring area 200 by adjusting the preset angle between the wave-adjusting plate 24 and the ground reference element 23, the hidden area 202 and the hidden area 202 of different sizes can be formed.
- Monitoring area 200 by adjusting the preset angle between the wave-adjusting plate 24 and the ground reference element 23, the hidden area 202 and the hidden area 202 of different sizes can be formed.
- the monitoring device 100 also includes at least one of the driving components 40, wherein the driving component 40 is disposed on the device main body 10, wherein each of the microwave monitoring components 20 The wave control plate 24 is drivably connected to the driving member 40.
- the user can automatically adjust the position between the wave adjustment plate 24 and the reference ground element 23 in each of the microwave monitoring components 20 by driving the driving component 40.
- the preset included angle enables the sizes of the monitoring area 200 and the hidden area 202 formed by the monitoring device 100 to be adjusted.
- an adjustable range of the preset angle formed between at least one of the wave adjustment plate 24 and the ground reference element 23 of each of the microwave monitoring components is greater than 0 ° and less than 90 °.
- the monitoring device 100 can form the monitoring area 200 and the shielding area 202.
- the monitoring area 200 includes the non-overlapping sub-monitoring area 2012 formed by each of the microwave monitoring components 20 and the sub-monitoring area 201 formed by two adjacent microwave monitoring components 20 respectively.
- the overlapping sub-monitoring area 2011 is composed.
- the monitoring device 100 can not only monitor whether the monitored object 300 is in the monitoring area 200 formed by the monitoring device 100, but also monitor whether the monitored object 300 is
- the non-overlapping sub-monitoring area 2012 constituting the monitored area 200 is also the overlapping sub-monitoring area 2011 between the sub-monitoring areas 201 formed by two adjacent microwave monitoring components 20 respectively. Therefore, the monitoring device 100 can also implement zone monitoring of the monitored object 300.
- the monitoring device 100 can also form the hidden area 202 in the middle of the monitoring device 100.
- a user when using the microwave monitoring device 100, a user can correspond to an area that is not to be monitored in real time with the hidden area 202, and correspond to an area that needs to be monitored with the monitoring area 201 formed by the monitoring device 100 .
- the plurality of microwave monitoring components 20 of the monitoring device 100 can first monitor the location of the monitored object 300 by means of area monitoring. .
- the processing component 30 of the monitoring device 100 can acquire an area where the monitored object 300 is located, and then control the image acquisition component 50 to obtain an image of the monitored object 300.
- the predetermined angle formed between the wave adjustment plate 24 and the ground reference element 23 of the microwave monitoring component 20 can be removed before the monitoring device 100 is manufactured. Preset, and the preset angle formed between the wave control plate 24 and the ground reference element 23 of the microwave monitoring component 20 is different, and the position of the monitoring area 200 formed by the monitoring device 100 will be different .
- the sub-monitoring area 201 formed by the corresponding microwave monitoring component 20 will increase, thereby increasing the size of the monitoring area 200 composed of a plurality of the sub-monitoring areas 201. Accordingly, the size of the hidden area 202 formed by the monitoring device 100 is reduced.
- the sub-monitoring area 201 formed by the corresponding microwave monitoring component 20 will increase, thereby increasing the size of the monitoring area 200 composed of a plurality of the sub-monitoring areas 201. Accordingly, the size of the hidden area 202 formed by the monitoring device 100 is reduced.
- the corresponding microwave monitoring component 20 forms the The sub-monitoring area 201 will be closer to the component body 21.
- an adjustable range of the preset angle formed between at least one of the wave adjustment plate 24 and the ground reference element 23 of each of the microwave monitoring components is greater than 0 ° and less than 90 °.
- the number of the radiation sources 22 included in each of the microwave monitoring components 20 in the monitoring device 100 may also be different. Specifically, when the number of the radiation sources 22 is different, the width and size of the sub-monitoring area 201 formed by the corresponding microwave monitoring component 20 are not only different, but also the hidden area formed by the monitoring device 100 The size of 202 is also different.
- the number of the radiation sources 22 included in one of the microwave monitoring components 20 is implemented to include two.
- the number of the radiation sources 22 included in one of the microwave monitoring components 20 is implemented to include four.
- each of the radiation sources 22 is horizontally arranged on the reference ground element 23.
- the preset angles between the wave adjustment plate 24 and the plane on which the ground reference element 23 is located in the microwave monitoring component 20 in FIGS. 11A and 12 are the same, the description in FIG. 12
- the sub-monitoring area 201 formed by the radiation of the microwave monitoring component 20 in FIG. 12 is smaller than that formed by the radiation of the microwave monitoring component 20 in FIG. 11A.
- the sub-monitoring area 201 is relatively far from the position of the component body 21 and has a narrow width in the horizontal direction.
- the sub-monitoring area 201 formed by the microwave monitoring component 20 in FIG. 13 is radiated compared to The sub-monitoring area 201 formed by the microwave monitoring component 20 radiated by the microwave monitoring component 20 in FIG. 11A and FIG. 12 is further away from the location of the component main body 21, and wider in the horizontal direction and narrower.
- the position and width of the sub-monitoring area 201 formed by at least one of the microwave monitoring components 20 change, correspondingly, the size of the monitoring area 200 and the hidden area 202 formed by the monitoring device 100 Changes at the same time.
- the size of the monitoring area 200 and the size of the monitoring area 200 formed by the monitoring device 100 can be adjusted by adjusting the number of the radiation sources 22 in each of the microwave monitoring components 20.
- the size of the hidden area 202 changes at the same time.
- the radiation source 22 of each of the microwave monitoring components 20 is horizontally arranged on the component body 21.
- the microwave monitoring component 20 may also be vertically arranged on the component body 21, and the present invention is not limited in this respect.
- the component body 21 of each of the microwave monitoring components 20 is implemented to be made of a flexible board, more preferably, an FPC flexible board. Therefore, by bending the component main body 21, the microwave formed by the radiation source 22 can further be restricted to radiate by the component main body 21 that is bent. Therefore, by adjusting the degree of bending of the component body 21, the sizes of the monitoring area 200 and the hidden area 202 formed by the monitoring device 100 can be further adjusted.
- the device body 10 of the microwave monitoring device 100 includes a device body 11 and an adjustable base 12, wherein the device body 11 is mounted on the adjustable The upper end of the base 12.
- the height of the adjustable base 12 is set to be adjustable, so that the device body 11 can be supported to different heights by adjusting the height of the adjustable base 12.
- each of the microwave monitoring components 20 is mounted on the equipment body 11 of the equipment body 10. Therefore, when the height of the adjustable base 12 is adjusted, the height of each of the microwave monitoring components 20 mounted on the device body 10 is adjusted accordingly. In this way, the position of the sub-monitoring area 201 formed by each of the microwave monitoring components 20 from the component main body 21 is adjusted. Correspondingly, the position of the monitoring area 200 formed by each of the sub-monitoring areas 201 from the component body 21 is also adjusted, so that the size of the hidden area 202 formed by the monitoring device 100 can be adjusted. .
- the hidden area 202 can be adjusted by adjusting the height of the device body 11 mounted on the upper end of the adjustable base 12 in the device main body 10. the size of.
- the adjustable base is implemented as a telescopic rod.
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Abstract
一监控设备,其包括一设备主体和至少两个微波监控部件,其中每个所述微波监控部件被安装于所述设备主体,其中所述微波监控部件能够共同形成一监控区域和一隐蔽区域。
Description
本发明涉及一微波监控领域,更涉及一监控设备,其中所述监控系统能够通过分区监控的方式对被监控的物体进行监控。
监控系统已经被广泛地应有在诸多行业和领域,现有的监控系统对被监控物体进行监控的方式主要分为两种,一种是采用微波监控的方式对被监控的物体进行监控,另一种是采用图片获取的方式对被监控物体进行监控。
采用微波监控的方式对被监控的物体进行监控时,通常在监控系统被调试安装之后,形成的监控区域大小是固定的,对于被监控物体具体在监控系统形成的监控区域的那个位置,现有技术中采用微波监控的方式对被监控物体进行监控的监控系统往往是无法监控到的。换句话说,现有技术中采用微波的方式对被监控的物体进行监控时,只能监控到被监控物体是否在监控区域,而无法进一步地监控到被监控物体在被监控区域的大致位置。在某些情况下,如果不能得到被监控物体在监控区域的大致位置以及被监控物体相对的移动方向,有可能会给用户带来不必要的损失。
比如说现在的诸多家用汽车基本上都安装有倒车雷达。安装在汽车上的倒车雷达往往只能监控车辆后方预定的监控区域内是否有障碍物,至于障碍物在车辆后方监控区域的哪个位置,通过倒车雷达是无法得知的。此时用户只能通过观察后视镜才能够进行判断,而当车辆行驶在光线不够充足的地区时,通过后视镜观察得到的结果往往会出现偏差,因而容易发生车辆碰撞事故。
在对被监控物体进行监控的同时,为得知被监控物体的相对位置和图片等信息,用户往往会采用图片获取的方式对被监控物体进行监控。而采用图片获取的方式对被监控物体进行监控时,监控系统需要一直保持工作状态。换句话说,无论在被监控的区域是否出现了被监控物体,监控系统都会将监控区域中出现的物体通过图片的形式呈现。而对于一些用户来说,他们并不希望自己的私密场所如 住宅、办公室等长时间被监控系统以图片的方式拍摄,因为这样会容易暴露他们的隐私,但是这些用户也希望能够在有一些突发状况发生时,监控系统能监控到这些突发状况。明显地,现有技术中的监控系统无法解决上述问题。
发明内容
本发明的一个目的在于提供一监控设备,其中所述监控设备能够形成一监控区域和一隐蔽区域,以能够对位于所述监控区域中的被监控物体进行监控。
本发明的另一个目的在于提供一监控设备,其中所述监控设备能够环形的所述监控区域和被所述监控区域环绕的所述隐蔽区域。
本发明的另一个目的在于提供一监控设备,其中所述监控区域和所述隐蔽区域中的至少一个的大小能够被调整。
本发明的一个目的在于提供一监控设备,其中所述监控设备不仅能够通过形成至少一监控区域监控至少一被监控物体,而且还能够在所述监控区域进行分区监控,进而不仅能够判断所述被监控物体是否在所述监控区域,而且还能够判断所述被监控物体在所述监控区域的位置。
本发明的另一个目的在于提供一监控设备,其中所述监控设备形成的所述监控区域被分区后被划分为至少三个区域,因此通过判断所述被监控物体位于哪一个所述子监控区域,进而能够判断所述被监控物体位于所述监控区域的具体位置。
本发明的另一个目的在于提供一监控设备,其中所述监控设备包括至少两个所述微波监控部件,其中每个所述微波监控部件形成一个子监控区域,并且相邻两个所述微波监控部件形成的所述子监控区域之间重叠的部分形成一重叠子监控区域,相邻两个所述微波监控部件形成的所述子监控区域不重叠的部分各自形成一未重叠子监控区域,通过这样的方式,进而使得所述监控设备能够对所述被监控物体进行分区监控。
本发明的另一个目的在于提供一监控设备,其中所述监控设备能够调整至少一个所述微波监控部件形成的所述子监控区域的水平方向朝向,进而能够调整所述监控设备形成的所述隐蔽区域的范围大小。
本发明的另一个目的在于提供一监控设备,其中所述监控设备能够通过调整至少一个所述微波监控部件的一调波板与所述微波监控部件的一参考地元件之间的角度,进而能够调整所述监控区域的大小。
本发明的另一个目的在于提供一监控设备,其中所述监控设备能够通过调整至少一个所述微波监控部件的一辐射源的数量,进而能够调整所述微波监控设备形成的所述监控区域的大小。
本发明的另一个目的在于提供一监控设备,其中所述监控设备能够通过调整至少一个所述微波监控部件的所述辐射源排列的方式,进而能够调整所述微波监控设备形成的所述监控区域的大小。
为实现本发明以上至少一个目的,本发明提供一监控设备,其包括:
一设备主体;和
至少两个微波监控部件,其中每个所述微波监控部件被安装于所述设备主体,其中所述微波监控部件能够共同形成一监控区域和一隐蔽区域。
根据本发明一实施例,至少两个所述微波监控部件各自朝一个方向辐射形成一子监控区域。
根据本发明一实施例,相邻两个所述微波监控部件各自形成的所述子监控区域能够形成一重叠的子监控区域和每个所述微波监控部件的一未重叠子监控区域。
根据本发明一实施例,所述监控设备包括至少三个所述微波监控部件,其中至少三个所述微波监控部件能够共同形成连续的所述监控区域。
根据本发明一实施例,至少三个所述微波监控部件能够共同形成环形的所述监控区域和被所述监控区域环绕的所述隐蔽区域。
根据本发明一实施例,每个所述微波监控部件包括一部件主体、至少一辐射源、以及一参考地元件,其中所述辐射源被设置于所述参考地元件,并形成至少一辐射缝隙,其中所述参考地元件被设置于所述部件主体,其中所述部件主体被设置于所述设备主体。
根据本发明一实施例,每个所述微波监控部件包括至少一调波板,其中所述调波板被保持于所述部件主体,并与所述参考地元件之间形成一预设角度。
根据本发明一实施例,每个所述微波监控部件包括至少一对所述调波板。
根据本发明一实施例,每个所述微波监控部件的一对所述调波板被在竖直方向上间隔地布置在所述部件主体。
根据本发明一实施例,每个所述微波监控部件的至少一个所述调波板以与所述参考地元件之间形成的所述预设角度可调的方式被安装于所述部件主体。
根据本发明一实施例,每个所述微波部件中位于所述辐射源上侧的所述调波板以与所述参考地元件之间形成的所述预设角度可调的方式被安装于所述部件主体。
根据本发明一实施例,每个所述微波部件中位于所述辐射源下侧的所述调波板以与所述参考地元件之间形成的所述预设角度可调的方式被安装于所述部件主体。
根据本发明一实施例,所述监控设备包括至少一驱动部件,其中每个所述微波监控部件的至少一个所述调波板被可转动地连接于所述驱动部件。
根据本发明一实施例,至少一个所述微波监控部件的所述辐射源的数量被设置为至少两个。
根据本发明一实施例,至少一个所述微波监控部件的至少两个所述辐射源被在水平方向间隔地布置在所述参考地元件。
根据本发明一实施例,至少一个所述微波监控部件的至少两个所述辐射源被在竖直方向间隔地布置在所述参考地元件。
根据本发明一实施例,每个所述微波监控部件的所述部件主体被通过一体成型的软板制成。
根据本发明一实施例,所述监控设备包括至少一图像获取部件,其中所述图像获取部件以朝向所述监控区域的方式被设置于所述设备主体。
根据本发明一实施例,所述图像获取部件被连接于每个所述微波监控部件,其中所述微波监控部件监测到位于所述监控区域内的一被监控物体时,所述图像获取部件被开启,以获取所述被监控物体的图像。
根据本发明一实施例,所述监控设备包括一处理部件,其中所述图像获取部件和每个所述微波监控部件被连接于所述处理部件,其中所述图像获取部件可转动地安装于所述设备主体,其中当所述处理部件接收至少一个所述微波监控部件监测到位于所述监控区域内的一被监控物体时,所述处理部件控制所述图像获取部件开启并驱动所述图像获取部件转动至朝向所述被监控物体。
根据本发明一实施例,所述设备主体包括一设备本体和一可调底座,其中每个所述微波监控部件被安装于所述设备本体,其中所述设备本体被连接于所述可调底座的上端,其中所述可调底座被调整时,被安装于所述设备本体的所述微波监控部件被支撑至不同高度。
根据本发明一实施例,所述可调底座被实施为一伸缩杆。
图1示出了本发明一个实施例的一监控设备的结构示意图。
图2A和图2B分别示出了本发明第一个实施例的所述监控设备在一种情况下两个不同工作状态的示意图。
图3A和图3B分别示出了本发明第一个实施例的所述监控设备在另外一种情况下两个不同工作状态下的示意图。
图4示出了本发明第一个实施例的所述监控设备在一状态下控制一图像获取部件进行监控的两个不同工作状态的示意图。
图5示出了本发明第二个实施例的一监控设备的状态示意图。
图6示出了本发明第二个实施例的所述监控设备中至少一个所述微波监控部件转动后的状态示意图。
图7A和图7B分别示出了本发明第二个实施例的所述监控设备在两个不同工作状态下的示意图。
图8示出了本发明第三个实施例的一监控设备的状态示意图。
图9A示出了本发明第四个实施例的一监控设备的示意图。
图9B示出了本发明第四个实施例的所述监控设备中一微波监控部件的一调波板被调整后的示意图。
图10A示出了本发明第五个实施例的一监控设备的示意图。
图10B示出了本发明第五个实施例的变形实施例的所述监控设备示意图。
图11A示出了本发明第六个实施例的一监控设备的示意图。
图11B示出了本发明第六个实施例的所述监控设备中一微波监控部件的一调波板被调整后的示意图。
图11C示出了本发明第六个实施例的所述监控设备中一微波监控部件的另一调波板被调整后的示意图。
图12示出了本发明第七个实施例的一监控设备的示意图。
图13示出了本发明第七个实施例的所述变形实施例的所述监控设备示意图。
图14示出了本发明高度可调的一监控设备的结构示意图。
以下描述用于揭露本发明以使本领域技术人员能够实现本发明。以下描述中的优选实施例只作为举例,本领域技术人员可以想到其他显而易见的变型。在以下描述中界定的本发明的基本原理可以应用于其他实施方案、变形方案、改进方案、等同方案以及没有背离本发明的精神和范围的其他技术方案。
本领域技术人员应理解的是,在本发明的揭露中,术语“纵向”、“横向”、“上”、“下”、“前”、“后”、“左”、“右”、“竖直”、“水平”、“顶”、“底”“内”、“外”等指示的方位或位置关系是基于附图所示的方位或位置关系,其仅是为了便于描述本发明和简化描述,而不是指示或暗示所指的装置或元件必须具有特定的方位、以特定的方位构造和操作,因此上述术语不能理解为对本发明的限制。
可以理解的是,术语“一”应理解为“至少一”或“一个或多个”,即在一个实施例中,一个元件的数量可以为一个,而在另外的实施例中,该元件的数量可以为多个,术语“一”不能理解为对数量的限制,另外,本发明中“前”、“后”在某些地方是指时间的先后,在某些地方是指逻辑的先后,本发明不受此方面的限制。
参考图1至图9,依本发明的一较佳实施例的一监控设备100在接下来的描述中被揭露和阐述,其中所述监控设备100能够形成至少一监控区域200,以对位于所述监控区域200中的至少一被监控物体300进行监控。
具体地,在本发明实施例中,所述监控设备100包括一设备主体10和至少两个微波监控部件20,其中每个所述微波监控部件20被安装于所述设备主体10。每个所述微波监控部件20形成一个子监控区域201,并且监控设备100所述子监控区域201组成所述监控区域200。
在本发明中,相邻两个所述子监控区域201之间重叠的部分为一重叠子监控区域2011,相邻两个所述子监控区域201之间未重叠的部分为一未重叠子监控区域2012。所述重叠子监控区域2011和所述未重叠子监控区域2012组成所述监控区域200。通过这样的方式,使得所述监控设备100在进行监控工作时,能够分区进行监控。也即是说,本发明中所述监控设备100不仅能够对位于所述监控区域200的所述被监控物体300进行监控,而且还能够监控到所述被监控物体300位于所述监控区域100的位置,比如所述监控设备100能够监控到所述被监控物体300是位于所述重叠子监控区域2011,还是位于所述未重叠子监控区域 2012。
每个所述微波监控部件20包括一部件主体21、至少一辐射源22和至少一以及一参考地元件23,其中所述辐射源22被间隔地设置于所述参考地元件23,并与所述参考地元件23之间形成一辐射缝隙,其中所述参考地元件23被设置于所述部件主体21。所述部件主体21被安装于所述设备主体10。
本领域技术人员能够理解的是,在本实施例中,所述部件主体21和所述辐射源22可以被实施为包括一线路板和一激荡电路或震荡电路等,本发明不受此方面的限制。值得一提的是,在本发明中,安装于所述设备主体10的所述微波监控部件20的数量不受限制。
比如说,参考图2A至图4B,在本发明的一个实施例中,所述监控设备100包括两个所述微波监控部件20,分别为20a和20b。所述微波监控部件20a形成一子监控区域201a,且所述微波监控部件20b形成一子监控区域201b。所述子监控区域201a和所述子监控区域201b之间形成一个所述重叠子监控区域2011。所述子监控区域201a中与所述子监控区域201b未重叠的部分形成所述子监控区域201a的一未重叠子监控区域2012a。所述子监控区域201b中与所述子监控区域201a未重叠的部分形成所述子监控区域201b的一未重叠子监控区域2012b。因此,在本实施例中,所述监控设备100通过将所述监控区域200分为一个所述未重叠子监控区域2012a和一个所述未重叠子监控区域2012b以及一个所述重叠子监控区域2011,进而通过分区监控的方式实现对位于所述监控区域200中的所述被监控物体进行监测。
比如说,如图2A所示,在本实施例的一个示例中,所述被监控物体300出现在所述重叠子监控区域2011时,所述监控设备100能够监控到所述被监控物体300同时出现在所述微波监控部件20a形成的所述子监控区域201a和所述微波监控部件20b形成的所述子监控区域201b。因此,所述监控设备100能够判断出所述被监控物体300是在所述监控区域200的所述重叠子监控区域2011。
如图3A所示,当所述被监控物体300出现在所述未重叠子监控区域2012a时,所述监控设备100能够监控到所述被监控物体300并未同时出现在所述微波监控部件20a形成的所述子监控区域201a和所述微波监控部件20b形成的所述子监控区域201b,而仅仅出现在所述微波监控部件20a形成的所述子监控区域201a。随后所述监控设备100能够判断出所述被监控物体300位于所述监控区域 200的所述未重叠子监控区域2012a。通过这样的方式,从而使得所述监控设备100不仅能够监控到所述被监控物体300是否出现在所述监控区域200,而且还能够判断出所述被监控物体300位于所述监控区域200内的位置。
更具体地,在本发明中,所述监控设备100包括一处理部件30,其中所述处理部件30被可通信地连接于每个所述微波监控部件20,以接收每个所述微波监控部件20采集的与所述被监控物体300位置有关的一监控信号。可以理解的是,所述处理部件30可以被实施为一具有处理分析功能的芯片或包括所述芯片的装置部件,本发明不受此方面的限制。
进一步地,所述监控设备100包括至少一驱动部件40。每个所述微波监控部件20被可驱动地连接于所述驱动部件40,以使所述微波监控部件20形成的辐射方向在水平方向被调整,进而调整其中至少一个所述微波监控部件20形成的所述子监控区域201水平方向朝向。本领域技术人员能够理解的是,当其中一个所述微波监控部件20形成的所述子监控区域201的水平方向朝向被调整后,相邻两个所述微波监控部件20之间形成的所述未重叠子监控区域2011的大小也被相应地调整。此外,所述驱动部件40被可控制地连接于所述处理部件30,其中所述处理部件30通过分析与所述被监控物体300位置有关的所述监控信号,进而形成控制所述驱动部件40一控制信号。所述驱动部件40基于所述控制信号相应地调整其中至少一个所述微波监控部件20形成的所述子监控区域201的水平方向朝向。以使所述被监控物体300保持或移出在相邻两个所述微波监控部件20形成的所述子监控区域201中。
本领域技术人员能够理解的是,所述微波监控部件20被实施为整体可驱动地连接于所述驱动部件40,从而使得所述微波监控部件20形成的所述子监控区域201的水平方向朝向得以被调整。
本领域技术人员可以理解的是,每个所述驱动部件40可以被实施为一马达,其中所述驱动部件40被可通信地连接于所述处理部件30,其中所述驱动部件40被设置于所述微波监控部件20,且所述驱动部件40基于所述处理部件30形成的所述控制信号,进而被驱动以调整其中至少一个所述微波监控部件20形成的所述子监控区域201的水平方向朝向。
本领域技术人员能够理解的是,在本发明中,所述驱动部件40的所述马达的种类不是本发明的重点,不发明不受此方面的限制。
参考图2A至图3B,在此示例中,所述监控设备100包括两个所述微波监控部件20,如同上述第一个实施例。在本实施例中,两个所述微波监控部件20中的至少一个所述微波监控部件20a被连接于一个所述驱动部件40,从而使得所述微波监控部件20a形成的所述子监控区域201a的水平方向朝向和位置能够随着所述微波监控部件20a被驱动而改变。
为使本领域技术人员能够理解本发明,在本实施例中,两个所述微波监控部件20中能够被所述驱动部件40驱动的所述微波监控部件20形成的所述子监控区域201定义为一参考监控区域,而另一个所述微波监控部件20形成的所述子监控区域201被定义为一定位监控区域。当所述被监控物体300位于所述监控设备100的所述监控区域200时,所述监控设备100首先能够判断出所述被监控物体300是位于所述重叠子监控区域2011、所述微波监控部件20a的所述未重叠子监控区域2012a或所述微波监控部件20b的所述未重叠子监控区域2012b。随后所述处理部件30基于有关形成的所述监控信号相应地形成所述控制信号,以驱动其中至少一个所述微波监控部件20转动,进而使其形成的所述子监控区域201为所述定位子监控区域。
参考图2A和图2B,当所述被监控物体300位于所述重叠子监控区域2011时,所述处理部件30形成与所述被监控物体300位于所述重叠子监控区域2011有关的所述控制信号,并相应地将其中一个所述微波监控部件20形成的所述子监控区域201定义为所述定位监控区域,并控制所述驱动部件40驱动其中一个所述微波监控部件20转动,以调整所述定位监控区域的水平方向朝向。比如在本示例中,所述处理部件30将所述微波监控部件20a形成的所述子监控区域201a定义为所述定位监控区域,将所述微波监控部件20b形成的所述子监控区域201b定义为所述参考监控区域。所述处理部件30相应地调整所述微波监控部件20a形成的所述子监控区域201a的水平方向朝向,以使所述微波监控部件20a形成的所述子监控区域201a和所述微波监控部件20b形成的所述子监控区域201b之间重叠部分的所述重叠子监控区域2011的范围大小改变。
随着所述重叠子监控区域2011的改变,所述被监控物体300将逐渐地移出或进入所述重叠子监控区域2011。所述处理部件30通过分析所述微波监控部件20a转动后有关的数据信息,从而能够判断出所述被监控物体300位于所述监控设备100形成的所述监控区域200的具体位置。比如在本实施例中,所述处理 部件30通过分析所述微波监控部件20a转动的角度、速度、时间等,进而能够判断出所述被监控物体300在所述监控区域200的具体位置。
比如如图3A和图3B所示的示例中,当所述被监控物体300位于所述微波监控部件20a的所述未重叠子监控区域2012a时,所述处理部件30能够形成有关所述被监控物体300位于所述微波监控部件20a的所述未重叠子监控区域2012a的一监控信号。所述处理部件30基于所述监控信号形成一控制信号,相应地,所述处理部件30将其中一个所述微波监控部件20形成的所述子监控区域201定义为所述定位监控区域,并控制所述驱动部件40驱动其中一个所述微波监控部件20转动,以调整所述定位监控区域的水平方向朝向。比如在本示例中,所述处理部件30将所述微波监控部件20b形成的所述子监控区域201b定义为所述定位监控区域,将所述微波监控部件20a形成的所述子监控区域201a定义为所述参考监控区域。随后生成有关控制所述驱动部件40驱动所述微波监控部件20a转动的一控制信号,以调整所述重叠子监控区域2011的范围大小,进而使所述被监控物体300移入所述重叠子监控区域2011。随后,所述处理部件30基于记录的所述微波监控部件20b移动的有关数据,进而能够判断出所述被监控物体300位于所述微波监控部件20b未被驱动之前形成的所述子监控区域201a的具体位置。
同样地,当所述被监控物体300位于所述微波监控部件20b的所述未重叠子监控区域2012b时,所述处理部件30能够形成有关所述被监控物体300位于所述微波监控部件20b的所述未重叠子监控区域2012b的一监控信号。所述处理部件30基于所述监控信号,随后生成有关控制所述驱动部件40驱动所述微波监控部件20b转动的一控制信号。当所述被监控物体300单独出现在所述微波监控部件20b形成的所述子监控区域201时,所述微波监控部件20a将被驱动,以使所述被监控物体300逐渐地移入所述微波监控部件20a形成的所述子监控区域201a,其中所述处理部件30基于记录的所述微波监控部件20a移动的有关数据,进而能够判断出所述被监控物体300是位于所述微波监控部件20b所述子监控区域201b的具体位置。
也就是说,在本发明中,通过驱动所述微波监控部件20a,使得监控设备100形成的所述监控区域201a为一动态的监控区域,进而使得所述监控设备100不仅能够分区对位于所述监控区域200中的所述被监控物体300进行监控,而且还 能够监控到所述被监控物体300在所述监控区域200中的具体位置。
更值得一提的是,在本发明的一个优选实施例中,所述监控设备100中的每个所述微波监控部件20都被可驱动地连接于所述驱动部件40,从而使得每个所述微波监控部件20形成的所述子监控区域201都能够被定义为所述定位监控区域。同样地,所述处理部件30通过分别计算每个所述微波监控部件20转动后有关的数据,进而能够判断出所述被监控物体300位于所述监控区域200中的具体位置。
如图4A和图4B所示,更进一步地,所述监控设备100包括至少一图像获取部件50,其中所述图像获取部件50被可通信地连接于所述处理部件30,以在所述处理部件30计算出所述被监控物体300在所述监控区域201中的具体位置之后,启动所述图像获取部件50获取位于所述监控区域201内的所述被监控物体300的图像。也就是说,在本发明中,所述图像获取部件50在所述监控设备100获取到所述被监控物体300在所述监控区域200内的具体位置之前,都是处于关闭状态的。换句说,在所述被监控物体300出现之前,所述图像获取部件50是不会获取任何信息的。因此,所述监控设备100在对所述被监控物体300进行监控的同时,只有在所述被监控物体300出现时才能够获取所述被监控物体300的图像。
值得一提的是,可以在每个所述重叠子监控区域2011和所述未重叠子监控区域2012设置一个所述图像获取部件50,并且设置于所述重叠子监控区域2011和所述未重叠子监控区域2012的每个所述图像获取部件50一开始处于关闭状态。当所述处理部件30获取有关所述被监控物体300在所述监控区域200中的位置有关的所述监控信号时,对应于所述被监控物体300的所述重叠子监控区域2011或/和所述未重叠子监控区域2012中的所述图像获取部件50被启动,以对所述被监控物体300进行拍摄。
更值得一提的是,在本发明的另一个实施例中,所述监控设备100包括一个可转动的所述图像获取部件50,其中所述图像获取部件50被可转动地连接于所述驱动部件40。当所述处理部件30监控到所述被监控物体300位于所述监控区域201在所述监控区域201中的所述重叠子监控区域2011和/或所述未重叠子监控区域2012时,所述图像获取部件50被驱动以保持水平方向朝向对应于所述被监控物体300在所述监控区域200的具体位置,以获取所述被监控物体300的图 像。本发明以下至少一个示例中,仅以在所述监控区域200设置一个可转动地所述图像获取部件50为例进行说明,但是本领域技术人员能够理解的是,此并非对本发明的限制。
本领域技术人员应当理解,所述微波监控部件20藉由微波多普勒效应原理对移动物体进行探测,而本领域技术人员周知,藉由微波多普勒效应原理对移动物体进行探测,能够在输出的多普勒信号中获取被探测的移动物体的速度和距离参数,因此,结合本发明的所述监控设备100于所述监控区域200所获取的所述被监控物体300的角度和/或移动方向的参数,进而能够生成所述被监控物体300于所述监控区域200的相对坐标数据,如此以于所述监控区域200定位所述监控物体300而获取所述被监控物体300的具体位置。
可以理解的是,由于本发明中,所述监控设备100首先能够确定所述被监控物体300在所述监控区域200的具体位置,随后,所述图像获取部件50被启动后,进而能够快速地对所述被监控物体300进行定焦拍摄。也就是说,被确定位置的所述被监控物体300更便于所述图像获取部件50进行定焦。
参考图5至图7B,在本发明的第二个实施中,所述监控设备100包括三个所述微波监控部件20。在本实施例中,三个所述微波监控部件20分别为一微波监控部件20a、一微波监控部件20b以及一微波监控部件20c。在本实施例中,所述监控设备100形成的所述监控区域200的范围大小可以与上述实施例中所述监控设备100形成的所述监控区域200的范围大小相同,也可以不同,本发明不受此方面的限制。
此外,在本实施中,所述微波监控部件20a和所述微波监控部件20b分别形成的所述子监控区域201a、201b与上述实施例中所述微波监控部件20a和所述微波监控部件20b分别形成的所述子监控区域201a、201b的范围大小可以相同,也可以不同。
为使本领域技术人员能够理解本发明,本实施例仅以所述监控设备100形成的所述监控区域200大小与上述实施例中所述监控设备100形成的所述监控区域200的范围大小不同为例进行说明,但是,本领域技术人员能够理解的是,本发明不受此方面的限制。另外,在本实施例中,仅以所述微波监控部件20a和所述微波监控部件20b分别形成的所述子监控区域201a、201b的范围大小与上述实施例相同为例进行说明,但本发明也不受此方面的限制。
具体地,在本实施例中,所述微波监控部件20a形成的所述子监控区域201a和所述微波监控部件20b形成的所述子监控区域201b重叠的部分被定义为一第一重叠子监控区域2011a。所述微波监控部件20b形成的所述子监控区域201a和所述微波监控部件20c形成的一子监控区域201b之间重叠的部分被定义为一第二重叠子监控区域2011b。所述微波监控部件20c形成的所述子监控区域201c和所述微波监控部件20a形成的所述子监控区域201a之间重叠的部分被定义为一第三重叠子监控区域2011c。所述微波监控部件20a形成的所述子监控区域201a和所述微波监控部件20b形成的所述子监控区域201b未重叠的部分被定义为一第一未重叠子监控区域2012a。所述微波监控部件20b形成的所述子监控区域201b和所述微波监控部件20c形成的所述子监控区域201c未重叠的部分被定义为一第二未重叠子监控区域2012b。所述微波监控部件20c形成的所述子监控区域201c和所述微波监控部件20a形成的所述子监控区域201a未重叠的部分被定义为一第三未重叠子监控区域2012c。
本领域技术人员能够理解的是,在本实施例中,所述监控设备100形成的所述监控区域200被分为六个区,即所述第一重叠子监控区域2011a、所述第二重叠子监控区域2011b、所述第三重叠子监控区域2011c、所述第一未重叠子监控区域2012a、所述第二未重叠子监控区域2012b以及所述第三未重叠子监控区域2012c。当所述被监控物体300位于所述监控区域200时,由于所述监控设备100能够形成六个部分进行监控,进而使得所述监控设备100不仅能够监控到所述被监控物体300是否在所述监控区域200,而且还能够判断出所述被监控物体300在所述监控区域200中的具体哪个区。
值得一提的是,在本实施例中,所述微波监控部件20a、所述微波监控部件20b以及所述微波监控部件20c各自形成的所述子监控区域之间是相互连续的,但是本领域技术人员可以理解的是,所述微波监控部件20a、所述微波监控部件20b以及所述微波监控部件20c共同形成的所述监控区域200也可以被实施为一不连续的扇形区域,此时,所述微波监控部件20a和所述微波监控部件20c之间可以没有所述第三重叠子监控区域2011c。
更进一步地,在本发明实施例中,所述监控设备100包括至少一个所述驱动部件40。至少一个所述微波监控部件20被可转动地连接于所述驱动部件40。优选地,所述驱动部件40被连接于所述微波监控部件20b,以使所述微波监控部 件20b能够被所述驱动部件40驱动。另外,所述监控设备100包括所述处理部件30,其中所述处理部件30被可通信地连接于所述驱动部件40和所述微波监控部件20a、所述微波监控部件20b以及所述微波监控部件20c。所述处理部件30在获取到与所述被监控物体300在所述监控区域200中的位置有关的所述监控信号后,相应地形成所述控制信号。所述处理部件30根据所述控制信号控制所述驱动部件40驱动所述微波监控部件20b转动。当所述微波监控部件20b被驱动并转动时,所述第一重叠子监控区域2011a、所述第二重叠子监控区域2011b、所述第一未重叠子监控区域2012a、所述第二未重叠子监控区域2012b以及所述第三未重叠子监控区域2012c的范围大小相应地发生改变。因此,当所述被监控物体300出现在所述第一重叠子监控区域2011a、所述第二重叠子监控区域2011b或所述第三重叠子监控区域2011c中的任意一个时,藉由所述驱动部件40和所述处理部件30,进而能够得到在所述被监控物体300移除所述第一重叠子监控区域2011a或所述第二重叠子监控区域2011b时,所述微波监控部件20b发生转动的有关数据,进而判断出所述被监控物体300位于所述监控区域201中的具体位置。
参考图5和图6,当所述被监控物体300出现在所述微波监控部件20a形成的所述第一未重叠子监控区域2012a时,所述处理部件30根据有关所述被监控物体300位于所述第一子监控区域201a有关的所述监控信号,进而形成所述控制信号。被连接于所述微波监控部件20b的所述驱动部件40藉由所述控制信号相应地被开启并驱动所述微波监控部件20b转动,以调整所述微波监控部件20b形成的所述第二子监控区域201b的水平方向朝向。逐渐地,当所述被监控物体300逐渐地进入所述微波监控部件20b形成的所述第二子监控区域201b和所述微波监控部件20a形成的所述第一子监控区域201a之前的所述第一重叠子监控区域2011a时,所述处理部件30通过计算有关所述微波监控部件20b转动的数据,进而能够判断出所述被监控物体300的具体位置。也就是说,此时所述微波监控部件20a形成的所述第一子监控区域201a和所述微波监控部件20c形成的所述第三子监控区域201c将作为所述参考监控区域,而所述微波监控部件20b形成的所述第二子监控区域201b将作为所述定位监控区域。
优选地,在本发明中,所述微波监控部件20a、所述微波监控部件20b以及所述微波监控部件20c形成的所述子监控区域201之间相互连续,并且三个所述 微波监控部件20在形成相互连续的所述监控区域201的同时,形成一隐蔽区域202,其中各个子监控区域201环绕于所述隐蔽区域202。换句话说,所述监控设备100并不对位于所述隐蔽区域202中的物体进行监控。因此,利用本发明所述监控设备100不仅能够形成对所述被监控物体300进行监控的所述监控区域201,而且还能够形成一个隐蔽区域202,并且形成的所述隐蔽区域202位于所述封闭监控区域201的中间。换句话说,形成的所述监控区域201是环绕在所述隐蔽区域202的周围,因此利用本发明所述监控设备100进行监控时,用户可以将自己的私密空间设置为所述隐蔽区域202,进而能够在实现对私密空间之外的区域进行监控的同时,还不会暴露自己的私密空间。
如图5至7B所示,更进一步地,所述监控设备100包括至少一图像获取部件50,其中所述图像获取部件50被可通信地连接于所述处理部件30,以在所述处理部件30根据有关所述被监控物体300在所述监控区域201中位置有关的所述监测信号,启动所述图像获取部件50,进而使所述图像获取部件50获取位于所述监控区域201内的所述被监控物体300的图像。也就是说,在本发明中,所述图像获取部件50在所述监控设备100获取到所述被监控物体在所述监控区域201内的具体位置之前,都是处于关闭状态的。换句说,在所述被监控物体300出现之前,所述图像获取部件50是不会获取任何信息的,因此,所述监控设备100能够对所述被监控物体300进行监控,同时只有在所述被监控物体300出现时获取所述被监控物体300的图像。
通过以上描述,本领域技术人员可以理解的是,如果将用户的私密空间设置成所述监控设备100形成的所述隐蔽区域202,而将所述监控设备100形成的所述监控区域201设置成用户私密空间之外的其它需要监控的区域,进而能够实现对用户私密空间之外的其它部分空间进监控。
参考图7B,值得一提的是,可以在每个所述重叠子监控区域2011和所述未重叠子监控区域2012设置一个所述图像获取部件50,并且设置于所述重叠子监控区域2011和所述未重叠子监控区域2012的每个所述图像获取部件50一开始处于关闭状态。当所述处理部件30计算出所述被监控物体300在所述监控区域300中的位置时,对应于所述被监控物体300的所述重叠子监控区域2011或/和所述未重叠子监控区域2012中的所述图像获取部件50被启动,以对所述被监控物体300进行拍摄。
参考图5至图7A,更值得一提的是,在本发明的另一个实施例中,所述监控设备100包括一个可转动地所述图像获取部件50,其中所述图像获取部件50被可转动地连接于所述驱动部件40。当所述处理部件30监控到所述被监控物体300位于所述监控区域201在所述监控区域201中的所述重叠子监控区域2011和/或所述未重叠子监控区域2012时,所述图像获取部件50被驱动以保持水平方向朝向对应于所述被监控物体300在所述监控区域200的具体位置,以获取所述被监控物体300的图像。
参考图8,在本发明另一个实施例中,所述监控设备100被实施为包括四个所述微波监控部件20,具体地,分别为一微波监控部件20a、一微波监控部件20b、一微波监控部件20c以及一微波监控部件20d。所述微波监控部件20a、所述微波监控部件20b、所述微波监控部件20c以及所述微波监控部件20d分别对应地分别形成一子监控区域201a、一子监控区域201b、一子监控区域201c以及一子监控区域201d。优选地,在本实施例中,相邻两个所述微波监控部件20分别形成一重叠子监控区域2011。具体地,所述子监控区域10a与所述子监控区域10b之间形成一第一重叠子监控区域2011a,所述子监控区域10b与所述子监控区域10bc之间形成一第二重叠子监控区域2011b,所述子监控区域10b与所述子监控区域10c之间形成一第三重叠子监控区域2011c,所述子监控区域10c与所述子监控区域10a之间形成一第四重叠子监控区域2011d。此外,在本实施例中,所述子监控区域201a与所述子监控区域201b以及所述子监控区域201d之间未重叠的部分为一第一未重叠子监控区域2012a。所述子监控区域201b与所述子监控区域201a和所述子监控区域201c之间未重叠的部分为一第二未重叠子监控区域2012b,所述子监控区域201c与所述子监控区域201b和所述子监控区域201d之间未重叠的部分为一第三未重叠子监控区域2012c,所述子监控区域201d与所述子监控区域201a和所述子监控区域201c之间未重叠的部分为一第四未重叠子监控区域2012d。
本领域技术人员可以理解的是,所述监控设备100通过将所述监控区域200分割为一个环形的八个区域对所述被监控物体300进行监控,从而不仅能够监控到所述被监控物体300是否位于所述监控区域200,而且还能够监控到所述被监控物体300在所述监控区域200的具体位置。
此外,每个所述微波监控部件20分别通过一马达被可转动地安装。所述微 波监控部件20a、所述微波监控部件20b、所述微波监控部件20c以及所述微波监控部件20d分别被可通信地连接于所述处理部件30。所述处理部件30根据有关所述被监控物体300所在的所述子监控区域201的位置有关的所述监控信号,相应地生成所述控制信号,以通过启动所述驱动部件40进而控制所述微波监控部件20转动。所述处理部件30随后通过分析转动前后对应的所述微波监控部件20发生偏转有关的数据和所述被监控物体300的位置变化,进而判断出所述被监控物体300在所述监控区域200中的具体位置。
比如说,在如8所示的示例中,当所述被监控物体300出现在所述第一重叠子监控区域2011a后,所述监控设备100能够监控到所述被监控物体300同时出现在所述微波监控部件20a和所述微波监控部件20b分别形成的所述子监控区域201a和所述子监控区域201b。随后,所述处理部件30相应地控制形成所述第二子监控区域201b的所述微波监控部件20b,以减小所述第一重叠子监控区域2011a的水平方向朝向,以使所述被监控物体逐渐地移出所述第一重叠子监控区域2011a。所述处理部件30通过计算所述微波监控部件20a和所述微波监控部件20b产生的位移,从而判断出所述被监控物体300在所述监控区域200中的具体位置。
值得一提的是,在本实施例中,所述监控设备100进一步包括至少一图像获取部件50。比如在本发明一个实施例中,所述监控设备100包括一个所述图像获取部件50,其中所述图像获取部件50被实施为可转动地安装与所述设备主体10。所述图像获取部件50被可通信地连接于所述处理部件30。在所述处理部件30得到多个所述微波监控部件20监控到的有关所述被监控物体300所在区域有关的信号时,所述处理装部件30驱动所述图像获取装40转动,从而使得所述图像获取部件50朝向所述被监控物体300所在的所述子监控区域201获取所述被监控物体300的图像。
在本发明的另一个实施例中,所述监控设备100包括多个所述图像获取部件50。比如,优选地,所述第一重叠子监控区域2011a、所述第二重叠子监控区域2011b、所述第三重叠子监控区域2011c、所述第一重叠子监控区域2011d、所述第一未重叠子监控区域2012a、所述第二未重叠子监控区域2012b、所述第三未重叠子监控区域2012c和所述第一未重叠子监控区域2012d都设有一个所述图像获取部件50。在所述处理部件30得到有关所述被监控物体300的位置有关的所 述监控信号之前,设置于述第一重叠子监控区域2011a、所述第二重叠子监控区域2011b、所述第三重叠子监控区域2011c、所述第一重叠子监控区域2011d、所述第一未重叠子监控区域2012a、所述第二未重叠子监控区域2012b、所述第三未重叠子监控区域2012c和所述第一未重叠子监控区域2012d的所述图像获取部件50并不进行图像获取工作。只有当所述处理部件30得到多个所述微波监控部件20监控到的有关所述被监控物体300所在区域有关的信号后,所述处理部件30才驱动对应于所述被监控物体300所在的所述子监控区域201的所述图像获取部件50进行图像获取工作。
更值得一提的是,在所述处理装部件30获取到有关所述被监控物体300所在的所述子监控区域201的位置之前,所述图像获取部件50并未被开启。也就是说,所述监控设备100获取到所述被监控物体300的所属的具体的所述子监控区域201之前,所述图像获取部件50是不会获取图像的。因此,本发明提供的所述监控设备100不仅能够判断所述监控区域200是否存在所述被监控物体300,而且还能够在只有所述被监控物体出现在所述监控区域时,才启动所述监控设备100的所述图像获取部件50获取图像。
进一步地,所述监控设备100中每个所述微波监控部件20包括至少一个调波板24,其中所述调波板24被保持于所述部件主体21,并且与所述参考地元件23之间形成一预设夹角。所述调波板24被设置于微波辐射的路径,以能够将所述微波限制在预定区域内。
值得一提的是,在本发明至少一个实施例中,所述调波板24的数量可以设置为一个或一个以上,本发明不受此方面的限制。
参考图1至图8以及9A和图9B,每个所述微波监控部件20可以设置两个所述调波板24,并且其中一个所述调波板24被设置在所述参考地元件23的左侧,另外一个所述调波板24被设置在所述参考地元件23的右侧,也就是说,两个所述调波板24是被水平设置于所述参考地元件23。每个所述调波板24被可驱动地连接于所述驱动部件40,从而通过驱动所述微波监控部件20的至少一个所述调波板24,进而能够使所述调波板24与所述参考地元件23之间形成的所述预设角度被调整,并且能够使得每个所述微波监控部件20形成的所述子监控区域201在水平方向上的朝向得以被调整,进而使相邻两个所述微波监控部件20之间形成的所述重叠子监控区域2011大小得以被调整。
值得一提的是,在本发明中,所述设备主体10延伸的高度方向为一竖直方向,其中在所述参考地元件23所在的平面上且与所述设备主体10延伸的高度方向为一水平方向。
本领域技术人员能够理解的是,每个所述微波监控部件20的每个所述调波板24都可以被调整,为使本领域技术人员能够理解本发明,本发明至少一个实施例中,仅以其中一个所述微波监控部件20的一个所述调波板24与所述参考地元件23之间的所述预定夹角被调整为例进行阐述。
值得一提的是,在本发明中,所述调波板24被调整的方式可以是通过手动调整,也可以是通过安装于所述设备主体10并被连接于所述调波板24的所述驱动部件40被调整。更值得一提的是,所述调波板24能够被实施为通过所述处理部件30控制所述驱动部件40被驱动以自动转动的方式被自动调整。相应地,在本实施例中,当所述被监控物体300出现在
在本实施例中,仅通过调整至少一个所述微波监控部件20的所述辐射源22的数量,进而也能够使得所述监控设备100中相邻两个所述微波监控部件20之间形成的所述重叠子区域2011大小不同,进而使得所述监控设备100形成的所述监控区域200的大小不同。如图10A和图10B所示,当将每个所述微波监控部件20的所述辐射源22设置为两个时,对应的所述微波监控部件20形成的所述子监控区域201的大小减小,从而使得整个所述监控区域200变小。也就是说,图9A、图10A以及图10B中可以不设置所述调波板24,而是仅仅通过改变其中至少一个所述微波监控部件20中所述辐射源22的数量,进而能够调整所述监控区域200和所述隐蔽区域202大小。参考图11A、图11B以及图11C,在本发明一个实施例中,每个所述微波监控部件20包括一个所述辐射源22,其中所述辐射源22被安装于所述参考地元件23。且每个所述微波监控部件20包括两个所述调波板24,其中一个所述调波板24被设置于所述辐射源22上侧的所述参考地元件23,另一个所述调波板24被设置于所述辐射源22下侧的所述参考地元件23。也就是说,在本实施例中,两个所述调波板24被设置在竖直方向上。因此,当每个所述微波监控部件20工作时,每个所述微波监控部件20的所述调波板24将所述辐射源22辐射形成的微波限制在预定的区域内,从而形成所述子监控区域201。
值得一提的是,在本发明任一实施例中,所述微波监控部件20在形成至少 两个所述子监控区域201的同时,也同时形成所述隐蔽区域202。
由于每个所述微波监控部件20的所述调波板24被设置在一竖直方向上,因此,每个所述微波监控部件20形成的所述子监控区域201在水平方向的宽度是不变的。
当每个所述微波监控部件20的所述调波板24相对于所述参考地元件23的所述预定夹角被实施为不同大小时,所述微波监控部件20形成的所述子监控区域201的大小不同。尤其是当设置于所述辐射源22上侧或下侧的所述参考地元件23中任何一个所述调波板24相对于所述参考地元件23之间的所述预设夹角不同时,不仅所述微波监控部件20形成的所述子监控区域201的大小不同,而且形成的所述隐蔽区域202的大小也会相应的不同。
也就是说,在本发明中,可以通过调整所述调波板24相对于所述参考地元件23之间的所述预设夹角,进而能够形成不同大小的所述隐蔽区域202和所述监控区域200。
此外,在本实施例中,所述监控设备100也包括至少一个所述驱动部件40,其中所述驱动部件40被设置于所述设备主体10,其中每个所述微波监控部件20的所述调波板24被可驱动地连接于所述驱动部件40。
具体地,在本实施例中,用户能够通过驱动所述驱动部件40进而能够自动地调整每个所述微波监控部件20中所述调波板24相对于所述参考地元件23之间的所述预设夹角,从而使得所述监控设备100形成的所述监控区域200和所述隐蔽区域202的大小得以被调整。
值得一提的是,每个所述微波监控部件的至少一个所述调波板24与所述参考地元件23之间形成的所述预设角度可调范围为大于0°小于90°。
比如说,在如图1至图8以及图9A所示的示例中,当每个所述微波监控部件20的所述调波板24与参考地元件23之间形成所述预定夹角时,所述监控设备100能够形成所述监控区域200和所述屏蔽区域202。此时,所述监控区域200由每个所述微波监控部件20形成的所述未重叠子监控区域2012和相邻两个所述微波监控部件20各自形成的子监控区域201之间的所述重叠子监控区域2011组成。
一方面,在本实施例中,所述监控设备100不仅能够监控到所述被监控物体300是否在所述监控设备100形成的所述监控区域200,而且还能够监控所述被 监控物体300是在组成所述被监控区域200的所述未重叠子监控区域2012还是相邻两个所述微波监控部件20各自形成的子监控区域201之间的所述重叠子监控区域2011。因此,所述监控设备100还能够实现对所述被监控物体300进行分区监控。另一方面,所述监控设备100还能够在所述监控设备100的中部形成所述隐蔽区域202。因此,用户在使用所述微波监控设备100时,能够将不想被实时监控的区域与所述隐蔽区域202对应,而将需要被监控的区域与所述监控设备100形成的所述监控区域201对应。当所述被监控物体300出现在所述监控区域201后,所述监控设备100的多个所述微波监控部件20首先能够通过分区域监控的方式,监控到所述被监控物体300所在的位置。随后,所述监控设备100的所述处理部件30能够获取所述被监控物体300所在的区域,随后控制所述图像获取部件50获取所述被监控物体300的图像。
值得一提的是,由于所述监控设备100中,所述微波监控部件20的所述调波板24与所述参考地元件23形成所述预定夹角可以在制作所述监控设备100之前被预设,而所述微波监控部件20的所述调波板24与所述参考地元件23之间形成所述预设夹角不同,所述监控设备100形成的所述监控区域200位置会不同。
例如,如图1至图8以及11B所示,当一个所述微波监控部件20中位于所述辐射源22上侧的所述调波板24与所述参考地元件23之间的所述预定夹角被调小后,对应的所述微波监控部件20形成的所述子监控区域201将增大,进而使得由多个所述子监控区域201组成的所述监控区域200的大小增大。相应地,所述监控设备100形成的所述隐蔽区域202的大小减小。
如图1至图8以及11C所示,当一个所述微波监控部件20中位于所述辐射源22下侧的所述调波板24与所述参考地元件23之间的所述预定夹角被调小后,对应的所述微波监控部件20形成的所述子监控区域201将增大,进而使得由多个所述子监控区域201组成的所述监控区域200的大小增大。相应地,所述监控设备100形成的所述隐蔽区域202的大小减小。并且,当一个所述微波监控部件20下侧所述调波板24与所述参考地元件23之间的所述预定夹角被调小后,对应的所述微波监控部件20形成的所述子监控区域201将更靠近所述部件主体21。
值得一提的是,每个所述微波监控部件的至少一个所述调波板24与所述参考地元件23之间形成的所述预设角度可调范围为大于0°小于90°。
另外,所述监控设备100中的每个所述微波监控部件20包括的所述辐射源 22的数量也可以不同。具体地说,当所述辐射源22的数量不同时,对应的所述微波监控部件20形成的所述子监控区域201的宽度和大小不仅不同,而且所述监控设备100形成的所述隐蔽区域202的大小也不同。
具体地,参考图12,其中一个所述微波监控部件20包括的所述辐射源22的数量被实施为包括两个。参考图13,其中一个所述微波监控部件20包括的所述辐射源22的数量被实施为包括四个。
参考图12,由于其中一个所述微波监控部件20包括的所述辐射源22的数量被实施为两个,其中每个所述辐射源22被水平方向布置于所述参考地元件23。当图11A和图12中所述微波监控部件20中所述调波板24与所述参考地元件23所在的平面之间的所述预设角度都相同的情况下,图12中的所述微波监控部件20中由于所述辐射源22是多元的,因此,图12中所述微波监控部件20辐射形成的所述子监控区域201较之图11A中所述微波监控部件20辐射形成的所述子监控区域201的距离所述部件主体21的位置较远,而在水平方向的宽度较窄。同样地,由于图13中所述微波监控部件20包括的所述辐射源22的数量被实施为四个,因此,图13中所述微波监控部件20辐射形成的所述子监控区域201较之图11A和图12中所述微波监控部件20辐射形成的所述子监控区域201距离所述部件主体21的位置更远,而在水平方向上的宽的更窄。而当其中至少一个所述微波监控部件20形成的所述子监控区域201的位置和宽度发生变化时,对应地,所述监控设备100形成的所述监控区域200和所述隐蔽区域202的大小同时发生变化。
因此,在制作所述监控设备100时,通过调整每个所述微波监控部件20中所述辐射源22的数量,进而能够使所述监控设备100形成的所述监控区域200的大小和所述隐蔽区域202的大小同时改变。
更具体地,在本实施例中,每个所述微波监控部件20的所述辐射源22被水平布置于所述部件主体21。此外,所述微波监控部件20也可以被竖直布置于所述部件主体21,本发明不受此方面的限制。
优选地,在本实施例中,每个所述微波监控部件20的所述部件主体21被实施由软板制成,更优选地,由FPC软板制成。因此,通过弯折所述部件主体21的方式,进而能够使所述辐射源22形成的微波被弯曲的所述部件主体21限制在预定角度内辐射。因此,通过调整所述部件主体21弯曲的程度,进一步能够调 整所述监控设备100形成的所述监控区域200和所述隐蔽区域202的大小。
参考图14,更优选地,在本发明中,所述微波监控设备100的所述设备主体10包括一设备本体11和一可调底座12,其中所述设备本体11被安装于所述可调底座12的上端。所述可调底座12的高度被设置为可调整,从而通过调整所述可调底座12的高度,进而能够将所述设备本体11支撑至不同的高度。
此外,每个所述微波监控部件20被安装于所述设备主体10的所述设备本体11。因此,当通过调整所述可调底座12的高度时,被安装于所述设备本体10的所述各个所述微波监控部件20的高度也被相应地调整。通过这样的方式,进而使得每个所述微波监控部件20形成的所述子监控区域201距离所述部件主体21的位置被调整。相对应地,由各个所述子监控区域201形成的所述监控区域200距离所述部件主体21的位置也被调整,进而使得所述监控设备100形成的所述隐蔽区域202的大小得以被调整。
本领域技术人员能够理解的是,在本发明中,通过调整所述设备主体10中被安装于所述可调底座12上端的所述设备本体11所处高度,进而能够调整所述隐蔽区域202的大小。优选地,所述可调底座被实施为一伸缩杆。
用于解释本发明功能和结构原理的该实施例已被充分说明和描述,且本发明不受基于这些实施例原理基础上的改变的限制。因此,本发明包括涵盖在附属权利要求书要求范围和精神之内的所有修改。
Claims (22)
- 一监控设备,其特征在于,其包括:一设备主体;和至少两个微波监控部件,其中每个所述微波监控部件被安装于所述设备主体,其中所述微波监控部件能够共同形成一监控区域和一隐蔽区域。
- 根据权利要求1所述的监控设备,其中至少两个所述微波监控部件各自朝一个方向辐射形成一子监控区域。
- 根据权利要求2所述的监控设备,其中相邻两个所述微波监控部件各自形成的所述子监控区域能够形成一重叠的子监控区域和每个所述微波监控部件的一未重叠子监控区域。
- 根据权利要求1所述的监控设备,其中所述监控设备包括至少三个所述微波监控部件,其中至少三个所述微波监控部件能够共同形成连续的所述监控区域。
- 根据权利要求4所述的监控设备,其中至少三个所述微波监控部件能够共同形成环形的所述监控区域和被所述监控区域环绕的所述隐蔽区域。
- 根据权利要求1至5中任一所述的监控设备,其中每个所述微波监控部件包括一部件主体、至少一辐射源、以及一参考地元件,其中所述辐射源被设置于所述参考地元件,并形成至少一辐射缝隙,其中所述参考地元件被设置于所述部件主体,其中所述部件主体被设置于所述设备主体。
- 根据权利要求6所述的监控设备,其中每个所述微波监控部件包括至少一调波板,其中所述调波板被保持于所述部件主体,并与所述参考地元件之间形成一预设角度。
- 根据权利要求7所述的监控设备,其中每个所述微波监控部件包括至少一对所述调波板。
- 根据权利要求8所述的监控设备,其中每个所述微波监控部件的一对所述调波板在竖直方向上间隔地布置在所述部件主体。
- 根据权利要求9所述的监控设备,其中每个所述微波监控部件的至少一个所述调波板以与所述参考地元件之间形成的所述预设角度可调的方式被安装于所述部件主体。
- 根据权利要求10所述的监控设备,其中每个所述微波部件中位于所述辐射源上侧的所述调波板以与所述参考地元件之间形成的所述预设角度可调的方式被安装于所述部件主体。
- 根据权利要求10所述的监控设备,其中每个所述微波部件中位于所述辐射源下侧的所述调波板以与所述参考地元件之间形成的所述预设角度可调的方式被安装于所述部件主体。
- 根据权利要求10所述的监控设备,其中所述监控设备包括至少一驱动部件,其中每个所述微波监控部件的至少一个所述调波板被可转动地连接于所述驱动部件。
- 根据权利要求6所述的监控设备,其中至少一个所述微波监控部件的所述辐射源的数量被设置为至少两个。
- 根据权利要求14所述的监控设备,其中至少一个所述微波监控部件的至少两个所述辐射源被在水平方向间隔地布置在所述参考地元件。
- 根据权利要求15所述的监控设备,其中至少一个所述微波监控部件的至少两个所述辐射源被在竖直方向间隔地布置在所述参考地元件。
- 根据权利要求6所述的监控设备,其中每个所述微波监控部件的所述部件主体被通过一体成型的软板制成。
- 根据权利要求1至5中任一所述的监控设备,其中所述监控设备包括至少一图像获取部件,其中所述图像获取部件以朝向所述监控区域的方式被设置于所述设备主体。
- 根据权利要求18所述的监控设备,其中所述图像获取部件被连接于每个所述微波监控部件,其中所述微波监控部件监测到位于所述监控区域内的一被监控物体时,所述图像获取部件被开启,以获取所述被监控物体的图像。
- 根据权利要求18所述的监控设备,其中所述监控设备包括一处理部件,其中所述图像获取部件和每个所述微波监控部件被连接于所述处理部件,其中所述图像获取部件可转动地安装于所述设备主体,其中当所述处理部件接收至少一个所述微波监控部件监测到位于所述监控区域内的一被监控物体时,所述处理部件控制所述图像获取部件开启并驱动所述图像获取部件转动至朝向所述被监控物体。
- 根据权利要求1所述的监控设备,其中所述设备主体包括一设备本体和 一可调底座,其中每个所述微波监控部件被安装于所述设备本体,其中所述设备本体被连接于所述可调底座的上端,其中所述可调底座被调整时,被安装于所述设备本体的所述微波监控部件被支撑至不同高度。
- 根据权利要求21所述的监控设备,其中所述可调底座被实施为一伸缩杆。
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Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20030222809A1 (en) * | 2002-04-24 | 2003-12-04 | Terumi Nakazawa | Millimeter wave radar monitoring system |
CN102576483A (zh) * | 2009-10-02 | 2012-07-11 | 发明人投资控股公司 | 用于为区域保障安全的保安系统和方法 |
CN105376538A (zh) * | 2015-12-08 | 2016-03-02 | 湖南纳雷科技有限公司 | 一种雷达与视频融合的大范围监控系统及方法 |
CN205142414U (zh) * | 2015-11-24 | 2016-04-06 | 陕西亿达泰电子科技有限公司 | 一种基于雷达的视频联动监控装置 |
CN107945445A (zh) * | 2017-12-28 | 2018-04-20 | 克拉玛依市格恩赛电子科技有限公司 | 一种带预处理功能的雷球联动警示监控系统及其监控方法 |
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Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20030222809A1 (en) * | 2002-04-24 | 2003-12-04 | Terumi Nakazawa | Millimeter wave radar monitoring system |
CN102576483A (zh) * | 2009-10-02 | 2012-07-11 | 发明人投资控股公司 | 用于为区域保障安全的保安系统和方法 |
CN205142414U (zh) * | 2015-11-24 | 2016-04-06 | 陕西亿达泰电子科技有限公司 | 一种基于雷达的视频联动监控装置 |
CN105376538A (zh) * | 2015-12-08 | 2016-03-02 | 湖南纳雷科技有限公司 | 一种雷达与视频融合的大范围监控系统及方法 |
CN107945445A (zh) * | 2017-12-28 | 2018-04-20 | 克拉玛依市格恩赛电子科技有限公司 | 一种带预处理功能的雷球联动警示监控系统及其监控方法 |
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