CN208314198U - beam emitter - Google Patents

beam emitter Download PDF

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Publication number
CN208314198U
CN208314198U CN201820627085.XU CN201820627085U CN208314198U CN 208314198 U CN208314198 U CN 208314198U CN 201820627085 U CN201820627085 U CN 201820627085U CN 208314198 U CN208314198 U CN 208314198U
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China
Prior art keywords
beam emitter
main body
detection
plate main
environment
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CN201820627085.XU
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Chinese (zh)
Inventor
邹高迪
邹新
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Shenzhen Merrytek Technology Co Ltd
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Shenzhen Merrytek Technology Co Ltd
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    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B15/00Systems controlled by a computer
    • G05B15/02Systems controlled by a computer electric
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO 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
    • G01S13/00Systems 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
    • G01S13/88Radar or analogous systems specially adapted for specific applications
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO 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
    • G01S7/00Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
    • G01S7/02Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S13/00
    • G01S7/41Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S13/00 using analysis of echo signal for target characterisation; Target signature; Target cross-section
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO 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
    • G01S7/00Details of systems according to groups G01S13/00, G01S15/00, G01S17/00
    • G01S7/02Details of systems according to groups G01S13/00, G01S15/00, G01S17/00 of systems according to group G01S13/00
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
    • G01V3/00Electric or magnetic prospecting or detecting; Measuring magnetic field characteristics of the earth, e.g. declination, deviation
    • G01V3/12Electric or magnetic prospecting or detecting; Measuring magnetic field characteristics of the earth, e.g. declination, deviation operating with electromagnetic waves
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/418Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/105Controlling the light source in response to determined parameters
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/105Controlling the light source in response to determined parameters
    • H05B47/115Controlling the light source in response to determined parameters by determining the presence or movement of objects or living beings
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B2219/00Program-control systems
    • G05B2219/20Pc systems
    • G05B2219/26Pc applications
    • G05B2219/2642Domotique, domestic, home control, automation, smart house
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
    • Y02B20/40Control techniques providing energy savings, e.g. smart controller or presence detection

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Remote Sensing (AREA)
  • General Physics & Mathematics (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Electromagnetism (AREA)
  • Automation & Control Theory (AREA)
  • General Engineering & Computer Science (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Environmental & Geological Engineering (AREA)
  • Geology (AREA)
  • General Life Sciences & Earth Sciences (AREA)
  • Geophysics (AREA)
  • Manufacturing & Machinery (AREA)
  • Quality & Reliability (AREA)
  • Radar Systems Or Details Thereof (AREA)
  • Circuit Arrangement For Electric Light Sources In General (AREA)

Abstract

The utility model discloses a beam emitters, it includes an at least radiation source, at least a wave beam confinement element and a reference plate, wherein the reference plate includes a plate main body, wherein the plate main body has a plane of reference, the radiation source is arranged at the plate main body in a manner of the plane of reference for extending perpendicularly to the plate main body of the radiation source, and a radiating slot is formed between the radiation source and the plate main body, wherein the wave beam confinement element is neighboringly set to the radiation source, the radiation direction of the microwave generated with constraining the radiation source and plate main body mutual cooperation by the wave beam confinement element.

Description

Beam emitter
Technical field
The utility model relates to detection fields, in particular to a beam emitter, tested to detect in a detection system Object is surveyed in the action mode of environment.
Background technique
Based on user movement realize to the intelligence control system of the control of lamps and lanterns be reduce the energy consume one it is important Means.For example, the intelligence control system can be according to whether having user to enter an environment be arranged at the environment to control Lamps and lanterns mode, be expected to facilitate user and the consume of electric energy can be reduced, to achieve energy-saving and emission reduction purposes.It is existing The control flow of the intelligence control system of technology is: when a detector detects that user enters the dynamic of the environment from external After work, a control signal can be generated, in the subsequent state for controlling the lamps and lanterns according to the control signal.Although the prior art The intelligence control system a degree of convenience can be brought to user, but its defect is also fairly obvious.Specifically It says, the detector of the intelligence control system of the prior art is merely able to detection user in the shift action of the environment, such as walks Movement, that is, user can be detected in the significantly shift action of the environment by the detector, and small movement nothing Method is detected that this easilys lead to the intelligence control system and misplaces to the lamps and lanterns by the detector of the intelligence control system The bad phenomenon of control.Such as, when the detector detect user from it is external enter the environment walk about act when, the intelligent control System, which can control, to be arranged at the lamps and lanterns of the environment and is opened, and is rested or is seen on the seat when user sits in the environment When book, since the movement range of the user is smaller, then the detector can not detect user in this context, at this point, the intelligence Control system can close the lamps and lanterns for energy-efficient purpose, it is clear that this is not desired by a user, and once this phenomenon goes out It is existing, then trouble can be not only caused to user, but also bad user experience can be brought.
Utility model content
One of the utility model is designed to provide a beam emitter, to detect detected pair in a detection system As the action mode in environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system can obtain it is described Detected object the environment action mode, to obtain the detected object in the behavior of the environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system can not only obtain The detected object and can obtain the detected object in the fine motion of the environment in the shift action of the environment Movement.
One of the utility model is designed to provide a beam emitter, wherein the detection system can be in the ring Border forms an at least detection zone, and detects to the detected object in the detection zone, described in obtaining Action mode of the detected object in the environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system is in the environment shape At the detection zone be dynamic detection region, to improve the flexibility of the detection system.
One of the utility model is designed to provide a beam emitter, wherein the detection system can be right in real time The detected object in the environment is detected, to obtain the detected object in the real-time action of the environment Mode.
One of the utility model is designed to provide a beam emitter, wherein the detection system can initiatively to The environment emits an at least detection beam, to form at least one described detection zone in the environment by the detection beam Domain, when the detected object is located at the detection zone, the detected object can be to reflect the detection beam Mode responds the detection beam, and the detection system can by way of the detection beam that reception and analysis are responded Obtain the real-time action mode of the detected object.
One of the utility model is designed to provide a beam emitter, wherein the detection system is detected in execution one The environment is detected when tactful, in the subsequent real-time action mould for obtaining the detected object in the environment Formula.
One of the utility model is designed to provide a beam emitter, wherein the detection system is executing the inspection Survey strategy when can selectively to the environment carry out layered weighting and/or subregion detection and/or subangle detect, with The subsequent real-time action mode for obtaining the detected object in the environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system can be to the ring Border carries out layered weighting, to obtain the state of the different layers of the environment.For example, the detection system can press the environment It is divided into two layers or more according to the difference of height, every layer for comparing the environment is detected respectively, in this way, the inspection Examining system can obtain the detected object in the real-time action mode of the environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system is to the environment When carrying out layered weighting, every layer of state can be inconsistent, for example, the height of adjacent two layers can be different.
One of the utility model is designed to provide a beam emitter, wherein the detection system can be to the ring Border carries out subregion detection, to obtain the state of the different zones of the environment, in this way, the detection system energy The detected object is enough obtained in the real-time action mode of the environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system can be to the ring Border carries out subangle detection, to obtain the state of the different angle of the environment, in this way, the detection system energy The detected object is enough obtained in the real-time action mode of the environment.
One of the utility model is designed to provide a beam emitter, wherein according to the real-time of the detected object State can obtain the detected object in the behavior of the environment, can be according to the detected object with subsequent Behavior manages the environment locating for the detected object in a manner of adjusting the wave frequency of the environment.For example, the environment Sound wave and/or light wave can be conditioned.
One of the utility model is designed to provide a beam emitter, wherein by carrying out layering inspection to the environment Survey, the mode of subregion detection and subangle detection can accurately obtain the detected object in the behavior of the environment, To subsequent, can be according to locating for detected object detected object described in the behavior regulation of the environment described in The state of environment.
One of the utility model is designed to provide a beam emitter, wherein the detection system can be at least one Beam emitter forms the detection zone in the environment to the mode that the environment emits the detection beam, thus to place It is detected in the detected object of the detection zone and obtains the detected object in the real-time dynamic of the environment Operation mode.
One of the utility model is designed to provide a beam emitter, wherein the beam emitter can be with to institute The mode for stating environment transmitting microwave emits the detection beam, to form the detection zone in the environment.
One of the utility model is designed to provide a beam emitter, wherein the microwave that the beam emitter generates Radiation direction can be restrained so that the detection system can to the environment carry out layered weighting, subregion examine It surveys and subangle detects.
One of the utility model is designed to provide a beam emitter, wherein beam emitter transmitting is described The beam direction of detection beam can be conditioned, so that the detection zone forms dynamic detection region.
One of the utility model is designed to provide a beam emitter, wherein beam emitter generation is described Detection beam can be enhanced, so that the detection system can obtain the micromotion of the detected object.
One of the utility model is designed to provide a beam emitter, wherein the beam emitter provides a reference Plate and at least a radiation source, wherein the reference plate includes a plate main body and at least flank for being arranged at the plate main body, The radiation source is neighboringly set to the plate main body, wherein the radiation source and the plate main body can cooperate and produce The raw detection beam, wherein the flank can constrain the direction of the launch of the detection beam.
One of the utility model is designed to provide a beam emitter, wherein the flank is adjustably set to The plate main body adjusts the hair of the detection beam in a manner of the relative position by changing the flank and the plate main body Direction is penetrated, thus the detection zone for forming the beam emitter because emitting the detection beam to the environment Dynamic detection region.
One of the utility model is designed to provide a beam emitter, wherein the two sides of the plate main body are set respectively It is equipped with the flank, the direction of the launch of the detection beam is constrained to provide a variety of different the way of restraint, to make The layered weighting of the detection system, subregion detection and subangle detection can be met by obtaining the same beam emitter.
One of the utility model is designed to provide a beam emitter, wherein the beam emitter provides at least one Wave beam confinement element, the wave beam confinement element are neighboringly set to the radiation source, by the wave beam confinement element It constrains the radiation source and the plate main body cooperates and the direction of the launch of the detection beam of generation.
One of the utility model is designed to provide a beam emitter, wherein the radiation source and wave beam constraint The quantity of element all can be more than two, and in this way, the same beam emitter can meet the inspection Layered weighting, subregion detection and the subangle detection of examining system.
One of the utility model is designed to provide a beam emitter, wherein the beam emitter provides a reinforcement Plate, wherein the stiffening plate is arranged at the plate main body, to expand the size of the plane of reference of the plate main body, to increase The intensity for the detection beam that the strong beam emitter generates, so that the detection system can obtain described detected pair The micromotion of elephant.
According to the one aspect of the utility model, the utility model provides a beam emitter comprising:
An at least radiation source;
An at least wave beam confinement element;And
One reference plate, wherein the reference plate includes a plate main body, wherein the plate main body has a plane of reference, institute State radiation source be arranged in a manner of the plane of reference for extending perpendicularly to the plate main body of the radiation source it is described Plate main body, and a radiating slot is formed between the radiation source and the plate main body, wherein the wave beam confinement element quilt It is set to the radiation source, neighboringly to constrain the radiation source and the plate main body phase interworking by the wave beam confinement element The radiation direction of the microwave of conjunction and generation.
One embodiment according to the present utility model, the wave beam confinement element are arranged at the plate main body.
One embodiment according to the present utility model, the wave beam confinement element have a constraint space, the radiation source It is maintained at the constraint space of the wave beam confinement element.
One embodiment according to the present utility model, the wave beam confinement element is in horn-like.
One embodiment according to the present utility model, the wave beam confinement element is plate-like, and wave beam constraint member Part is proximally retained the side of the radiation source.
One embodiment according to the present utility model, the wave beam confinement element extend perpendicularly to the plate main body The plane of reference extending direction.
One embodiment according to the present utility model, the wave beam confinement element have a groove, and the radiation source is protected Hold the groove in the wave beam confinement element.
One embodiment according to the present utility model, the quantity of the radiation source are one, the wave beam confinement element Quantity is two, and two wave beam confinement elements are maintained at the opposite side of the radiation source.
One embodiment according to the present utility model, the quantity of the radiation source are two, the wave beam confinement element Quantity is two, and two wave beam confinement elements are maintained between two radiation sources.
One embodiment according to the present utility model, two wave beam confinement elements are symmetrical.
The extending direction of one embodiment according to the present utility model, two wave beam confinement elements has angle.
One embodiment according to the present utility model, the beam emitter further comprise a shielding case, wherein described Shielding case is arranged at the side of the plate main body, and the shielding case and the radiation source are maintained at the plate main body Opposite side.
One embodiment according to the present utility model, if the wavelength parameter for the wave that the beam emitter generates is λ, wherein The distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
Detailed description of the invention
Fig. 1 is a block diagram representation according to an environmental management system of a preferred embodiment of the utility model.
Fig. 2A to Fig. 2 D is being applied to according to the environmental management system of the above-mentioned preferred embodiment of the utility model The schematic diagram of one study environment.
Fig. 3 A to Fig. 3 I is being applied to according to the environmental management system of the above-mentioned preferred embodiment of the utility model The schematic diagram of one room environment.
Fig. 4 is to be applied to the room according to the environmental management system of the above-mentioned preferred embodiment of the utility model Flow diagram when environment.
Fig. 5 A to Fig. 5 C is to be applied to one according to the environmental management system of the above-mentioned preferred embodiment of the utility model The schematic diagram of parlor environment.
Fig. 6 is to be applied to the parlor according to the environmental management system of the above-mentioned preferred embodiment of the utility model Flow diagram when environment.
Fig. 7 A to Fig. 7 C is being applied to according to the environmental management system of the above-mentioned preferred embodiment of the utility model The schematic diagram of one meeting room environmental.
Fig. 8 is to be applied to the meeting according to the environmental management system of the above-mentioned preferred embodiment of the utility model Flow diagram when room environmental.
Fig. 9 is the flow diagram according to the environmental management system of the above-mentioned preferred embodiment of the utility model.
Figure 10 A to Figure 10 C is the wave beam according to the environmental management system of the above-mentioned preferred embodiment of the utility model The schematic diagram of one embodiment of transmitter.
Figure 11 A is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model A state schematic diagram.
Figure 11 B is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Another state schematic diagram.
Figure 11 C is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Another state schematic diagram.
Figure 11 D is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Another state schematic diagram.
Figure 12 A to Figure 12 D is the wave beam according to the environmental management system of the above-mentioned preferred embodiment of utility model The schematic diagram of the another embodiment of transmitter.
Figure 13 A to Figure 13 C is the wave according to the environmental management system of the above-mentioned preferred embodiment of the utility model The schematic diagram of the different conditions of beam transmitter.
Figure 14 is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Another embodiment schematic diagram.
Figure 15 is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model A state schematic diagram.
Figure 16 is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Another embodiment schematic diagram.
Figure 17 is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model A state schematic diagram.
Figure 18 is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Another embodiment stereoscopic schematic diagram.
Figure 19 is the beam emitter according to the environmental management system of the above-mentioned preferred embodiment of the utility model Above embodiment schematic cross-sectional view.
Figure 20 is the block diagram representation according to the detection system of the above-mentioned preferred embodiment of the utility model.
Figure 21 A to Figure 21 C is to execute according to the detection system of the above-mentioned preferred embodiment of the utility model comprising dividing The schematic diagram of the detection zone formed when the inspection policies of layer inspection policies.
Figure 22 is to execute according to the detection system of the above-mentioned preferred embodiment of the utility model comprising subregion detection The schematic diagram of the detection zone formed when the inspection policies of strategy.
Figure 23 A and Figure 23 B are to execute according to the detection system of the above-mentioned preferred embodiment of the utility model comprising dividing The schematic diagram of the detection zone formed when the inspection policies of angle inspection policies.
Specific embodiment
It is described below for disclosing the utility model so that those skilled in the art can be realized the utility model.It retouches below Preferred embodiment in stating is only used as illustrating, it may occur to persons skilled in the art that other obvious modifications.It is retouched following The basic principle of the utility model defined in stating can be applied to other embodiments, deformation scheme, improvement project, etc. Tongfangs The other technologies scheme of case and the spirit and scope without departing from the utility model.
It will be understood by those skilled in the art that in the exposure of the utility model, term " longitudinal direction ", " transverse direction ", "upper", The orientation of the instructions such as "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom" "inner", "outside" or position are closed System is to be based on the orientation or positional relationship shown in the drawings, and is merely for convenience of describing the present invention and simplifying the description, without It is that the device of indication or suggestion meaning or element must have a particular orientation, be constructed and operated in a specific orientation, therefore on Stating term should not be understood as limiting the present invention.
It is understood that term " one " is interpreted as " at least one " or " one or more ", i.e., in one embodiment, The quantity of one element can be one, and in a further embodiment, the quantity of the element can be it is multiple, term " one " is no It can be interpreted as the limitation to quantity.
With reference to the attached drawing 1 of the Figure of description of the utility model, according to an environment of a preferred embodiment of the utility model Management system 100 is disclosed for and is set forth in following description, wherein the environmental management system 100 can be according to one Management strategy manages an environment 200, make in a manner of by adjusting the state of the environment 200 state of the environment 200 with The action mode of user in the environment 200 is adapted.Preferably, the environmental management system 100 can not only make The state of the environment 200 and user are adapted in the shift action mode of the environment 200, and the environmental management System 100 can also be such that the state of the environment 200 and user is adapted in the micromotion mode of the environment 200.
Preferably, user can be obtained in the environment 200 in the action mode of the environment 200 according to user Behavior, so that the environmental management system 100 can provide the pipe based on the behavior of the user in the environment 200 Reason is tactful, and the state of the environment 200 is adjusted when executing the management strategy, so that the state of the environment 200 and place It is adapted in the behavior of the user of the environment 200.For example, the environmental management system 100 is executing the management strategy When the state of the environment 200 can be adjusted in a manner of adjusting the wave frequency of the environment 200 so that the wave of the environment 200 Frequency and the behavior of the user in the environment 200 are adapted.For example, in the environmental management system of the utility model In 100 specific example, the environmental management system 100 can be to adjust the environment when executing the management strategy The mode of 200 audio (sound wave frequency range) adjusts the state of the environment 200 so that the audio of the environment 200 be in institute The behavior for stating the user of environment 200 is adapted.And in another tool of the environmental management system 100 of the utility model In body example, the environmental management system 100 can be to adjust the optical frequency of the environment 200 when executing the management strategy The mode of (lightwave band) adjusts the state of the environment 200 so that the optical frequency of the environment 200 be in the environment 200 User behavior be adapted.
Specifically, the environmental management system 100 can control at least one lamps and lanterns for being arranged at the environment 200 Working condition is adjusted described in a manner of the brightness of the light generated by adjusting the lamps and lanterns, color, colour temperature, light and shade variation The optical frequency of environment 200, so that the optical frequency of the environment 200 and the behavior of the user in the environment 200 be made to be adapted. More specifically, when the environmental management system 100 obtains user after the behavior of the environment 200 expectation sleep, the ring Border management system 100 can control the modes such as brightness, color, colour temperature and the light and shade variation of the light that the lamps and lanterns generate and adjust institute The state of environment 200 is stated, to be conducive to that user is helped to fall asleep.Alternatively, when the environmental management system 100 obtain user into After the mobile behavior for entering the environment 200, the environmental management system 100 can control the lamps and lanterns and be opened to be described Environment 200 provides illumination, and obtains user after the reading behavior of the environment 200 in the environmental management system 100, The environmental management system 100 can control the lamps and lanterns and be maintained at opening state to be constantly that the environment 200 provides Illumination.
It is highly preferred that the environmental management system 100 can be based on the real-time behavior of the user in the environment 200 The management strategy is provided, and adjusts the state of the environment 200 in real time when executing the management strategy, so that the ring The real-time status in border 200 and the real-time behavior of the user in the environment 200 are adapted.For example, the environmental management system System 100 can adjust the environment in a manner of adjusting the real-time wave frequency of the environment 200 when executing the management strategy 200 state, so that the real-time wave frequency of the environment 200 and the real-time behavior of the user in the environment 200 are adapted.
It is noted that the environmental management system 100 adjusts the environment 200 when executing the management strategy The mode of wave frequency adjust the state of the environment 200 so that the wave frequency of the environment 200 makes in the environment 200 The behavior of user be adapted it is merely illustrative, in the environmental management system 100 for disclosing and illustrating the utility model Appearance and feature, and it is not construed as the limitation of the content and range to the environmental management system 100 of the utility model.Example Such as, in other possible examples of the environmental management system 100 of the utility model, according to user in the environment 200 behavior, whether the environmental management system 100 can also control the switch of the lamps and lanterns in the environment 200, example Such as, the environmental management system 100 can according to user the environment 200 behavior prediction user in the environment 200 motion track, and user is being obtained after the motion track of the environment 200, the environmental management system 100 can To make the lamps and lanterns of the motion track in user be opened in advance, with the motion track for illuminating user.Or After the behavior for obtaining user, the environmental management system 100 can control the air-conditioning in the environment 200 and/or add Whether wet device switchs, for example, the environmental management system 100 can mention when the environment 200 will be gone to by obtaining user It is preceding to open the air-conditioning and/or humidifier for being in the environment 200, to adjust the temperature and/or humidity of the environment 200.Also To say, the environmental management system 100 can using in the environment 200 user as a detected object 300, and Real-time behavior obtaining the detected object 300 by way of obtaining the real-time action mode of the detected object 300, So that the environmental management system 100 can provide the management based on the real-time behavior of the detected object 300 subsequent Strategy, and the real-time status of the environment 200 is adjusted when executing the management strategy, so that the real-time shape of the environment 200 The real-time behavior of state and the detected object 300 is adapted.For example, the environmental management system 100 can be by detecting institute The variation for stating the movement of detected object 300 obtains the real-time behavior of the detected object 300.In addition, the environmental management System 100 can detected object 300 described in the variation prediction by the movement for detecting the detected object 300 behavior, For example, the environmental management system 100 can quilt described in the variation prediction by the movement for detecting the detected object 300 The motion track of test object 300.In other words, after the real-time behavior change of the detected object 300, the environment 200 Real-time status, such as the real-time wave frequency of the environment 200 can also change correspondingly, and the real-time wave frequency of the environment 200 Real-time behavior with the detected object 300 is adapted.
With reference to attached drawing 1, the environmental management system 100 include an at least processor 101, an at least beam emitter 102, An at least signal receiver 103 and at least a wave frequency generator 104, wherein the beam emitter 102, the signal receive Device 103 and the wave frequency generator 104 are communicatively connected in a network respectively in the processor 101.
It is noted that the beam emitter 102, the signal receiver 103 and 104 quilt of wave frequency generator The communication mode for being communicatively coupled to the processor 101 is unrestricted in the environmental management system 100 of the utility model System.For example, in some specific examples of the environmental management system 100 of the utility model, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 be communicatively connected in a network in a manner of wired connection respectively in The processor 101.And in other specific examples of the environmental management system 100 of the utility model, the wave Beam transmitter 102, the signal receiver 103 and the wave frequency generator 104 can be communicated in a manner of wireless connection respectively Ground is connected to the processor 101.Nevertheless, it will be apparent to a skilled person that described in the utility model In the possible example of the other of environmental management system 100, the beam emitter 102,103 and of the signal receiver One in the wave frequency generator 104 can be communicatively connected in a network in the processor 101 in a manner of wired connection, and The other side with wireless connection in the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 Formula is communicatively connected in a network in the processor 101.
It's also worth mentioning that the beam emitter 102 and the signal receiver 103 can be split type structure, It is also possible to integral structure.Although in following description, with the beam emitter 102 and the signal receiver 103 are implemented as the interior of the environmental management system 100 for continuing to disclose and illustrate the utility model for split type structure Appearance and feature, but those skilled in the art should not be by the split type beam emitter 102 and the signal receiver 103 limitation as the range of the environmental management system 100 to the utility model.
Preferably, the environmental management system 100 further comprises an at least communication interface 105, wherein the processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 are communicatively connected in a network respectively In the communication interface 105, so that the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 It is communicatively connected in a network respectively in the processor 101.It is noted that the communication interface 105 can be but not limited to Wireless communication interface.The communication interface 105 can permit the more beam emitters 102, the signal receiver 103 and the wave frequency generator 104 access.That is, working as the beam emitter 102,103 and of the signal receiver When the wave frequency generator 104 can access the communication interface 105 respectively, the beam emitter 102, the signal are received Device 103 and the wave frequency generator 104 can be communicatively connected in a network to be made in this way in the processor 101 User can choose the beam emitter 102, the signal receiver 103 and the wave of the environmental management system 100 The number amount and type of frequency generator 104.
It is noted that the type of the processor 101 is in the environmental management system 100 of the utility model It is unrestricted, for example, the processor 101 can be but not limited to central processing unit (CPU).In addition, the wave frequency generator 104 type is also unrestricted in the environmental management system 100 of the utility model, as long as the wave frequency generator 104 Wave frequency can be generated, such as the lamps and lanterns of light wave can be generated and may be implemented as the environment pipe of the utility model The wave frequency generator 104 of reason system 100, the loudspeaker that can generate sound wave may be implemented as the described of the utility model The wave frequency generator 104 of environmental management system 100.It is noted that the environmental management system of the utility model 100 illustrate the content and feature of the wave frequency generator 104, but art technology by taking the lamps and lanterns and the loudspeaker as an example Personnel it should be understood that itself and be not construed as content and range to the environmental management system 100 of the utility model Limitation.
In addition, the environmental management system 100 further includes a power supply 106, wherein the processor with continued reference to attached drawing 1 101, in the beam emitter 102, the signal receiver 103, the wave frequency generator 104 and the communication interface 105 At least one be electrically connected to the power supply 106, with by the power supply 106 be the processor 101, the wave beam send out Emitter 102, the signal receiver 103, the wave frequency generator 104 and the communication interface 105 are powered.Nevertheless, this The technical staff in field it should be understood that the environmental management system 100 in the utility model some specific examples In, the communication interface 105 is it is also not necessary to be electrically connected to the power supply 106, such as the communication interface 105 can be with It is implemented as a WiFi wireless interface, by other power supply power supplies, such as by mains-supplied, rather than by the institute of the utility model The power supply 106 for stating environmental management system 100 is powered.It is noted that the electricity of the environmental management system 100 The type in source 106 is unrestricted in the present invention, as long as being capable of providing power supply so that the processor 101, the wave Beam transmitter 102, the signal receiver 103 and the wave frequency generator 104 are in running order.
Whereby it should be noted that in some possible examples of the environmental management system 100 of the utility model, The processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 can be divided It is not linked into the same WiFi network, so that the beam emitter 102, the signal receiver 103 and wave frequency hair Raw device 104 is communicatively connected in a network respectively in the processor 101.Certainly, by the processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 are respectively connected to the same WiFi network and are only for example, in this reality It, can also be by the processor 101, the beam transmission in other example with the novel environmental management system 100 Device 102, the signal receiver 103 and the wave frequency generator 104 are respectively connected to but are not limited to the same local area network, Metropolitan Area Network (MAN) Deng.
In addition, an it's also worth mentioning that specific example of the environmental management system 100 in the utility model In, the beam emitter 102 and the signal receiver 103 also may be implemented as integral structure.
Attached drawing 2A to Fig. 2 D shows a concrete application example of the environmental management system 100, wherein in this tool In the example of body, the institute of the utility model is further described so that the environmental management system 100 is disposed in a study 401 as an example State the content and feature of environmental management system 100.
Referring to figs. 2A to Fig. 2 D, show in this specific application of the environmental management system 100 of the utility model In example, at least one beam emitter 102 and at least one described signal receiver 103 are with the beam emitter 102 Adjacent mode is disposed in the ceiling 4011 in the study 401 with the signal receiver 103, at least one described wave frequency Generator 104 can be disposed in the ceiling 4011 in the study 401, wherein the position of the processor 101 not by Limitation, such as the processor 101 can be disposed in the desk 4012 or wall 4013 in the study 401.
It is noted that another in the environmental management system 100 of the utility model specifically applies example In, the beam emitter 102 and the signal receiver 103 are also possible to integral structure.Described in the utility model In this concrete application example of environmental management system 100, the wave frequency generator 104 may be implemented as the lamps and lanterns.
Certainly, it will be apparent to a skilled person that the institute of the environmental management system 100 of the utility model Stating processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 can also be by cloth Set the other positions in the study 401.In other words, in the institute of the environmental management system 100 shown in attached drawing 2A to Fig. 2 D State the position that processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 are arranged It sets and is only for example, and be not construed as the limitation of the content and range to the environmental management system 100 of the utility model.
Preferably, the beam emitter 102 is the beam emitter of miniaturization, can generate microwave, to be used for shape At the detection beam.That is, the beam emitter 102 can generate the detection wave in a manner of emitting microwave Beam.Another in the environmental management system 100 of the utility model is specifically applied in example, the beam emitter 102 can also generate ultrasonic wave, to be used to form the detection beam.Preferably, the beam emitter 102 can be carried out For but be not limited to gain microwave antenna, in the subsequent real-time behavior that can accurately obtain the detected object 300, especially It is the micromotion that can accurately obtain the detected object 300.That is, subsequent, when the detected object 300 in the study 401 generation act when, the environmental management system 100 can also obtain the detected object 300 Movement.Preferably, when the detected object 300, generation is acted in the study 401, the environmental management system 100 can obtain the movement of the detected object 300 in real time.It is highly preferred that the environmental management system 100 can not only The shift action of the detected object 300 is obtained in real time, but also the fine motion that can obtain the detected object 300 is dynamic Make.
Specifically, with reference to attached drawing 2A and Fig. 2 B, when the detected object 300 enters from the external of the study 401 When the study 401, the beam emitter 102 can form the environment 200 to the study 401 and emit the detection Wave beam, to form an at least detection zone 1021 in the study 401 by the detection beam.For example, the wave beam hair Emitter 102 can emit the detection beam to the position on the doorway in the study 401, on the doorway in the study 401 Position forms the detection zone 1021, exists at this point, the environmental management system 100 can obtain the detected object 300 The shift action on the doorway in the study 401.In other words, the environmental management system 100 can capture the detected object 300 from external into the shift action in the study 401.The environmental management system 100 can be according to the detected object 300 the shift action on the doorway in the study 401 variation, predict that the detected object 300 enters the study 401 Behavior, at this point, the environmental management system 100 can control the institute for being arranged at the ceiling 4011 in the study 401 Wave frequency generator 104 is stated to be opened.That is, movement of the environmental management system 100 according to the detected object 300 Movement, which can control, to be implemented as the wave frequency generators 104 of the lamps and lanterns and is opened and generates light, to illuminate the book Room 401.
More specifically, the environmental management system 100 can be according to the inspection responded by the detected object 300 It surveys wave beam and obtains the detected object 300 in the action signal of the environment 200, in subsequent, the environmental management system 100 Compare the detected object 300 in the action signal and deliberate action threshold value of the environment 200, if the detected object 300 are more than or equal to the deliberate action threshold value, the then environmental management system 100 in the action signal of the environment 200 The wave frequency generator 104 that the ceiling 4011 for being arranged at the study 401 can be controlled is opened.On the contrary, if The environmental management system 100 can not obtain the detected object 300 in the action signal in the study 401, then show do not have Have the detected object 300 in the study 401, at this point, the environmental management system 100 can control be arranged at it is described The wave frequency generator 104 of the ceiling 4011 in study 401 is maintained at closed state.In addition, working as the environment pipe Reason system 100 obtains the detected object 300 after the action signal in the study 401, and the environmental management system 100 can To continue to test the detected object 300 in the shift action in the study 401, the detected object also can detecte 300 the study 401 micromotion.
With reference to attached drawing 2C and Fig. 2 D, when the detected object 300 is walked about from the doorway in the study 401 to the desk Seat near 4012 and when being sitting on the seat near the desk 4012, the beam emitter 102 can Emit the detection beam to the position of the desk 4012 in the study 401, in the desk in the study 401 4012 position forms the detection zone 1021, at this point, the environmental management system 100 can obtain the detected object 300 the position of the desk 4012 micromotion.The environmental management system 100 can be according to the detected object The 300 micromotion control near the desk 4012 in the study 401 is implemented as the wave frequency hair of the lamps and lanterns Raw device 104 is maintained at opening state to provide lasting illumination.
Specifically, the environmental management system 100 can be according to the detection responded by the detected object 300 Wave beam obtains the detected object 300 in the action signal of the environment 200, in subsequent, the ratio of environmental management system 100 The detected object 300 the environment 200 action signal and default fine motion threshold value, if the detected object 300 It is more than or equal to the default fine motion threshold value in the action signal of the environment 200, then the environmental management system 100 can Control be arranged at the study 401 the ceiling 4011 the wave frequency generator 104 be maintained at opening state with Lasting illumination is provided.On the contrary, if the environmental management system 100 can not detect the detected object 200 in the book The shift action in room 401, can not also detect the detected object 200 in the micromotion in the study 401, then the ring Border management system 100 can control the wave frequency generator 104 and be closed.
In a specific example of the environmental management system 100 of the utility model, with reference to attached drawing 2B and figure 2C, the beam emitter 102 is by way of the detection beam emitted to the study 401 in 401 shape of study At the detection zone 1021 be dynamic detection region 1021, for example, the beam emitter 102 can be first to the study The position on 401 doorway emits the detection beam and the position on the doorway in the study 401 forms the detection zone 1021, with movement of the detected object 300 in the study 401, the beam emitter 102 can be then to institute The position for stating the desk 4012 in study 401 emits the detection beam and in the desk 4012 in the study 401 Position forms the detection zone 1021.
If there is the detected object 300 to be in the detection zone 1021, the detected object 300 can be rung The detection beam is answered, for example, the detected object 300 can respond the detection in a manner of reflecting the detection beam Wave beam.For example, entering the position on the doorway in the study 401 in user in this specific example shown in attached drawing 2B When, the beam emitter 102 can be to the position on the doorway in the study 401 transmitting detection beam and in the study The position on 401 doorway forms the detection zone 1021, at this point, the user of the position into the doorway in the study 401 Form the detected object 300.When the detection beam that the beam emitter 102 generates is radiated to described be detected When object 300, the detected object 300 can respond the detection beam in a manner of reflecting the detection beam.It can be with Understand, it is described when the detection beam of the beam emitter 102 transmitting is radiated to the detected object 300 Detected object 300 can respond the detection beam, a portion in a manner of to all the winds reflecting the detection beam The detection beam will form echo.The signal receiver 103, which can receive, is in the described of the detection zone 1021 The detection beam that detected object 300 responds, that is, the side of the detection beam is reflected when the detected object 300 Formula will form echo when responding the detection beam, and the signal receiver 103 can be received in a manner of receiving echo to be located In the detection beam that the detected object 300 of the detection zone 1021 responds.The processor 101 being capable of basis The inspection that the received detected object 300 for being in the detection zone 1021 of the signal receiver 103 responds It surveys wave beam acquisition user and enters the shift action in the study 401, and further made according to the shift action of user The behavior of user, so that the environmental management system 100 being capable of the generation of the wave frequency according to the behavior management of user subsequent The state of device 104.For example, after the processor 101 obtains user and enters the shift action in the study 401, the ring Border management system 100 can control the wave frequency generator 104 and be opened to generate light and illuminate the study 401.
With reference to attached drawing 2D, stop when user is sitting on the seat near the desk 4012 in the study 401 When breath or study, the beam emitter 102 can be to the position of the desk 4012 transmitting detection beam and in institute The position for stating desk 4012 forms the detection zone 1021, at this point, the user sat on the seat forms described detected pair As 300.It is described tested when the detection beam that the beam emitter 102 generates is radiated to the detected object 300 The detection beam can be responded in a manner of reflecting the detection beam by surveying object 300, and the signal receiver 103 can connect Receive the detection beam responded by the detected object 300.The processor 101 can be according to the signal receiver The detection beam that the 103 received detected objects 300 for being in the detection zone 1021 respond is used Micromotion of the person near the desk 4012 in the study 401, and further obtained according to the micromotion of user The rest behavior of user or reading behavior, so that the environmental management system 100 being capable of stopping according to user subsequent Breath behavior or reading behavior manage the state of the wave frequency generator 104.For example, when the processor 101 obtains user After the 401 rest behavior of study or reading behavior, the environmental management system 100 can control the wave frequency generator 104 are maintained at opening state and constantly provide illumination for the study 401.
Attached drawing 3A to Fig. 4 shows another concrete application example of the environmental management system 100, wherein showing at this In example, the ring of the utility model is further described so that the environmental management system 100 is disposed in a room 402 as an example The content and feature of border management system 100.
With reference to attached drawing 3A, in this specific example of the environmental management system 100 of the utility model, at least one A beam emitter 102 and at least one described signal receiver 103 are with the beam emitter 102 and the signal The adjacent mode of receiver 103 is disposed in a ceiling 4021 and a wall 4022 in the room 402, at least one institute The ceiling 4021 that wave frequency generator 104 can be disposed in the room 402 is stated, wherein the position of the processor 101 Set unrestricted, such as the processor 101 can be disposed in the wall 4022 in the room 402.It is practical new at this In this concrete application example of the environmental management system 100 of type, the wave frequency generator 104 may be implemented as raising Sound device.Certainly, it will be apparent to a skilled person that the place of the environmental management system 100 of the utility model Reason device 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 can also be disposed in The other positions in the room 402.In other words, the processor of the environmental management system 100 shown in attached drawing 3A 101, the position that the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 are arranged is only to lift Example, and it is not construed as the limitation of the content and range to the environmental management system 100 of the utility model.
The beam emitter 102 can emit the detection beam to the environment 200 that the room 402 is formed, To form the detection zone 1021 in the room 402 by the detection beam.For example, being disposed in the room The beam emitter 102 of 402 ceiling 4021 can be to the position where the dressing table 4024 in the room 402 Emit the detection beam, to form the detection zone in the position where the dressing table 4024 in the room 402 1021, with reference to attached drawing 3B;Or it is disposed in 102 energy of the beam emitter of the ceiling 4021 in the room 402 Position where enough from bed bodies 4025 to the room 402 emits the detection beam, in the bed body in the room 402 Position where 4025 forms the detection zone 1021, with reference to attached drawing 3C;Or it is disposed in the day in the room 402 The beam emitter 102 of card 4021 can the dressing table 4024 and the bed body 4025 to the room 402 it is same When emit the detection beam, in the position point where the dressing table 4024 in the room 402 and the bed body 4025 The detection zone 1021 is not formed, with reference to attached drawing 3D;Or it is disposed in the institute of the ceiling 4021 in the room 402 The detection beam can be emitted to the dressing table 4024 in the room 402 by stating beam emitter 102, in the room Position where 402 dressing table 4024 forms the detection zone 1021, and the beam emitter 102 emits The angle of the detection beam can be conditioned, with the detection beam shape emitted in the subsequent beam emitter 102 At the detection zone 1021 can be gradually moved to institute from the position where the dressing table 4024 in the room 402 The position where bed body 4025 is stated, so that the detection zone 1021 forms dynamic detection region 1021, with reference to attached drawing 3E. In other words, the environmental management system 100 can carry out subregion detection to the environment 200 that the room 402 is formed. That is, the beam emitter 102 of the environmental management system 100 can be in each position in the room 402 point Not simultaneously or form the detection zone 1021 according to sequencing, with each position individually to the room 402 into Row detection, to obtain the detected object 300 in the action mode of each position in the room 402.For example, the environment The beam emitter 102 of management system 100 can the room 402 each position respectively simultaneously or according to successive The detection zone 1021 is sequentially formed, is detected with each position in the individually room 402, it is described tested to obtain Survey shift action or micromotion of the object 300 in each position in the room 402.
With reference to attached drawing 3F, the ceiling 4021 in the room 402 is disposed in when the environmental management system 100 The beam emitter 102 detected to the mode that the bed body 4025 in the room 402 emits the detection beam The detected object 300 is disposed in the room when in the bed body 4025 or near the bed body 4025 The beam emitter 102 of 402 wall 4022 can further emit to the bed body 4025 in the room 402 The detection beam carries out layered weighting with the environment 200 formed to the room 402, and in subsequent, the processing Device 101 can be according in the bed body 4025 for being in the room 402 or near the bed body 4025 The detection beam that detected object 300 responds obtains the behavior of the detected object 300.For example, being shown in attached drawing 3F This specific example in, the beam emitter 102 can to the room 402 formed the environment 200 in emit Three layers of detection beam and formed and divided along multiple detection zones 1021 of the short transverse arrangement in the room 402 The case where other different layers to the room 402, is detected respectively, in this way, can judge the quilt subsequent Test object 300 in the bed body 4025 or the bed body 4025 behavior, such as can judge it is described be detected pair It stands or is seated in the bed body 4025 or recumbency near the bed body 4025 as 300.Certainly, this field It should be understood that in other examples, the beam emitter 102 can also be formed technical staff to the room 402 The environment 200 in the detection beam of transmitting two layers or four layers or more the case where different layers, is examined respectively It surveys.It will be apparent to a skilled person that the environmental management system 100 of the utility model is detecting described be detected Object 300 is not needed in the behavior of the environment 200 by shooting the environment 200 and the detected object 300 Image, but carried out by way of emitting the detection beam to the environment 200 and the detected object 300, from And it avoids and is related to the leakage of content of the privacy of the detected object 300.
With continued reference to attached drawing 3F, every layer of the room 402 detection zone 1021 is successively defined as from bottom to top One first layer detection zone 1022, a second layer detection zone 1023 and a third layer detection zone 1024, wherein forming institute State the detected object that the detection beam of first layer detection zone 1022 can be lain in the bed body 4025 300 responses, and form the detection beam of the second layer detection zone 1023 and the third layer detection zone 1024 then It can not be responded by the detected object 300, if the signal receiver 103 only has received to be detected by described subsequent The detection beam for the formation first layer detection zone 1022 that object 300 responds, then subsequent, the processor 101 can Obtaining the detected object 300 is the state in recumbency, to obtain the detected object 300 in the room 402 Interior behavior.
It is noted that in other examples of the environmental management system 100 of the utility model, if the letter Number receiver 103 has received the formation responded by the detected object 300 the first layer detection zone 1022 and described The detection beam of second layer detection zone 1023, then subsequent, the processor 101 can obtain described be detected pair As 300 be in the state that is seated, thus the behavior energy in the subsequent detected object 300 in the detection zone 1021 It is enough obtained;If the signal receiver 103 has received the formation responded by the detected object 300 described The detection wave of one layer of detection zone 1022, the second layer detection zone 1023 and the third layer detection zone 1024 Beam, then subsequent, it is in the state that stand that the processor 101, which can obtain the detected object 300,.
The processor 101 can be in the detection zone 1021 according to the signal receiver 103 is received The detection beam that the detected object 300 responds obtains the behavior of the detected object 300 in the room 402, For example, the processor 101 can be in described in the detection zone 1021 according to the signal receiver 103 is received The detection beam that detected object 300 responds obtains the behavior lain in the bed body 4025.In subsequent, the processor 101 can generate the management strategy according to the behavior of the detected object 300, and execute in the processor 101 described The state of the wave frequency generator 104 is adjusted when management strategy, with by the wave frequency generator 104 to change the room The mode of the frequency range of the wave frequency of the environment 200 of 402 formation adjusts the state in the room 402, so that the room Between 402 state and user state be adapted.For example, when the environmental management system 100 obtains the detected object After 300 lie in the behavior in the bed body 4025, it can judge that the detected object 300 prepares sleep, at this point, the environment Management system 100 can generate the management strategy according to the behavior of the detected object 300, wherein the management strategy Content, which can be, controls the wave frequency frequency range that the wave frequency generator 104 generates, to execute institute in the environmental management system 100 The wave frequency frequency range and the brain wave phase of the detected object 300 for generating the wave frequency generator 104 when stating management strategy Match, and the detected object 300 is helped to fall asleep.
Certainly, it will be apparent to a skilled person that in the environmental management system shown in attached drawing 3G to Fig. 3 I In 100 this specific application, the wave frequency generator 104 is implemented as the lamps and lanterns, wherein the environmental management system 100 adjust the state for the environment 200 that the room 402 is formed in a manner of controlling the working condition of the lamps and lanterns.For example, It is described when the environmental management system 100, which detects the detected object 300, lies in expectation sleep in the bed body 4025 The brightness for the light that environmental management system 100 can be such that the wave frequency generator 104 for being implemented as the lamps and lanterns generates reduces, The wave frequency generator 104 for being implemented as the lamps and lanterns can be made to produce with reference to attached drawing 3G or the environmental management system 100 The colour temperature of raw light changes, and can make to be implemented as the lamps and lanterns with reference to attached drawing 3H or the environmental management system 100 The light that the wave frequency generator 104 generates changes with light and shade, with reference to attached drawing 3I, so that the formation of the room 402 is described The state of environment 200 is changed, so that user be helped to fall asleep.In other words, the processor 101 is configured as:
Obtain the behavior of the detected object 300 in the room 402;
The management strategy is generated according to the behavior of the detected object 300;And
The management strategy is executed, to manage the environment 200 that the room 402 is formed, to make the environment 200 State adapt to the state of the detected object 300.
Attached drawing 5A to Fig. 6 shows another concrete application example of the environmental management system 100, wherein showing at this In example, the ring of the utility model is further described so that the environmental management system 100 is disposed in a parlor 403 as an example The content and feature of border management system 100.
With reference to attached drawing 5A, in this specific example of the environmental management system 100 of the utility model, at least one A beam emitter 102 and at least one described signal receiver 103 are with the beam emitter 102 and the signal The adjacent mode of receiver 103 is disposed in a ceiling 4031 and a wall 4032 in the parlor 403, at least one institute The ceiling 4031 that wave frequency generator 104 can be disposed in the parlor 403 is stated, wherein the position of the processor 101 Set unrestricted, such as the processor 101 can be disposed in the wall 4032 in the parlor 403.In this implementation In example, the wave frequency generator 104 may be implemented as the lamps and lanterns.Certainly, it will be apparent to a skilled person that The processor 101, the beam emitter 102, the signal of the environmental management system 100 of the utility model receive Device 103 and the wave frequency generator 104 can also be disposed in the other positions in the parlor 403.In other words, in attached drawing 5A The processor 101, the beam emitter 102, the signal receiver 103 of the environmental management system 100 shown The position being arranged with the wave frequency generator 104 is only for example, and is not construed as the environment to the utility model The limitation of the content and range of management system 100.
The beam emitter 102 can emit the detection beam to the environment 200 that the parlor 403 is formed, To form the detection zone 1021 in the parlor 403 by the detection beam.For example, being disposed in the parlor The beam emitter 102 of 403 ceiling 4031 can be sent out to the position where the sofa 4033 in the parlor 403 The detection beam is penetrated, to form the detection zone 1021 in the position where the sofa 4033 in the parlor 403, is joined Examine attached drawing 5B.If having the detected object 300 to be in the detection zone 1021 is disposed in the visitor with reference to attached drawing 5C The beam emitter 102 of the wall 4032 in the Room 403 can further emit to the position where the sofa 4033 The detection beam carries out layered weighting with the environment 200 formed to the parlor 403, and in subsequent, the processing The inspection that device 101 can be responded according to the detected object 300 on the sofa 4033 for being in the parlor 403 Survey the behavior that wave beam obtains the detected object 300.For example, in this specific example shown in attached drawing 5C, the wave Emit three layers of detection zone 1021 in the environment 200 that beam transmitter 102 can be formed to the parlor 403 to distinguish The case where different height in the parlor 403, is detected respectively, in this way, can judge the quilt subsequent Test object 300 such as can judge the detected object 300 described in the behavior of the position where the sofa 4033 Position where sofa 4033 stands or is seated.Certainly, it will be apparent to a skilled person that in other examples In, the beam emitter 102 also can to the parlor 403 formed the environment 200 in emit two layers or four layers with On the detection beam respectively the case where different layers, is detected.
With continued reference to attached drawing 5C, wherein being formed described in the detection beam and formation of the first layer detection zone 1022 The detection beam of second layer detection zone 1023 can be sitting in 300 sound of the detected object on the sofa 4033 It answers, and the detection beam for forming the third layer detection zone 1024 can not be responded by the detected object 300, if Subsequent, the signal receiver 103 only has received the formation responded by the detected object 300 the first layer detection zone The detection beam in domain 1022 and the detection beam for forming the second layer detection zone 1023, then it is described subsequent Processor 101 can obtain the detected object 300 and be sitting on the sofa 4033, to obtain described detected pair As 300 behavior in the detection zone 1021.
The processor 101 can be in the detection zone 1021 according to the signal receiver 103 is received The detected object 300 for the detection zone 1021 that the detection beam that the detected object 300 responds obtains Behavior, for example, the processor 101 can be in the detection zone according to the signal receiver 103 is received The detection beam that 1021 detected object 300 responds obtains the behavior being sitting on the sofa 4033.Subsequent, The processor 101 can generate the management strategy according to the behavior of the detected object 300, and in the processor The mode that the frequency range of the wave frequency of the wave frequency generator 104 is adjusted when the 101 execution management strategy adjusts the parlor 403 State, so that the state by the state in parlor 403 and user is adapted.For example, working as the environmental management system After the 100 acquisition detected objects 300 are sitting in the behavior on the sofa 4033, the detected object 300 can be judged It is in observation television program, at this point, the environmental management system 100 can be generated according to the behavior of the detected object 300 The management strategy, and in the working condition of the subsequent wave frequency generator 104 according to the content-control of the management strategy.
In other words, the processor 101 is configured as:
Obtain the behavior of the detected object 300 of the detection zone 1021 in the parlor 403;
The management strategy is generated according to the behavior of the detected object 300;And
The management strategy is executed, to manage the environment 200 that the parlor 403 is formed, to make the environment 200 State adapt to the state of the detected object 300.
Attached drawing 7A to Fig. 8 shows another concrete application example of the environmental management system 100, wherein in this tool In body application example, it is practical new that this is further described so that the environmental management system 100 is disposed in a meeting room 404 as an example The content and feature of the environmental management system 100 of type.
With reference to attached drawing 7A, in this specific example of the environmental management system 100 of the utility model, at least one A beam emitter 102 and at least one described signal receiver 103 are connect with the beam emitter 102 and the signal A ceiling 4041 and a wall 4042 that the adjacent mode of device 103 is disposed in the meeting room 404 are received, at least by one The wave frequency generator 104 can be disposed in the ceiling 4041 of the meeting room 404, wherein the processor 101 Position it is unrestricted, for example, the processor 101 can be disposed in the wall 4042 of the meeting room 404.? This of the environmental management system 100 of the utility model is specifically applied in example, and the wave frequency generator 104 can be by It is embodied as the lamps and lanterns.Certainly, those skilled in the art it should be understood that the utility model the environmental management system 100 processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 can also To be disposed in the other positions of the meeting room 404.In other words, the environmental management system 100 shown in attached drawing 7A The processor 101, the beam emitter 102, the signal receiver 103 and the wave frequency generator 104 be arranged Position be only distance, and be not construed as to the content of the environmental management system 100 of the utility model and range Limitation.
The beam emitter 102 can emit the detection wave to the environment 200 that the meeting room 404 is formed Beam, to form the detection zone 1021 in the meeting room 404 by the detection beam.For example, being disposed in described The beam emitter 102 of meeting room 404 can emit institute to the position where a conference table 4043 for the meeting room 404 Detection beam is stated, to form the detection zone 1021 in the position where the conference table 4043 of the meeting room 404, With reference to attached drawing 7B.All detected objects 300 are in the detection zone 1021 and are disposed in reference to attached drawing 7C The beam emitter 102 of the wall 4042 of the meeting room 404 can be further to 4043 place of conference table Position emit the detection beam, with the environment 200 that is formed to the meeting room 404 according to highly carrying out layering inspection It surveys, and subsequent, the processor 101 can be according to the institute near the conference table 4043 in the meeting room 404 The detection beam for stating the response of detected object 300 obtains the behavior of the detected object 300.For example, showing in attached drawing 7C In this specific example out, in the environment 200 that the beam emitter 102 can be formed to the meeting room 404 Three layers of detection beam of transmitting are to form the first layer detection zone 1022, the second layer detection zone 1023 and described Third layer detection zone 1024 detects respectively come the case where different height layer to the meeting room 404 respectively, passes through this The mode of sample can judge the detected object 300 at 4043 place of the conference table of the meeting room 404 subsequent The behavior of position, such as when detecting that it is described that all detected objects 300 in the meeting room 404 are centered around Conference table 4043 and when being seated, it can be determined that all detected objects 300 just in session or are discussing issues, and work as detection Some into all detected objects 300 in the meeting room 404 are seated, and other stand, Huo Zhesuo When a part in the detected object 300 having is far from the conference table 4043, it can be determined that the detected object 300 It is not on meeting state or is not on the state discussed issues.That is, the environmental management system 100 can be with All detected objects 300 are obtained in the spatial distribution of the environment 200.
It, can be according to the detected object 300 in the meeting after processor 101 obtains above-mentioned judging result The behavior of room 404 generates the management strategy, and the wave frequency hair is adjusted when the processor 101 executes the management strategy The wave band of the wave frequency of raw device 104 makes the state of the meeting room 404 and the shape of the detected object 300 in this way State is adapted.
In other words, the processor 101 is configured as:
Obtain the behavior of the detected object 300 of the detection zone 1021 in the meeting room 404;
The management strategy is generated according to the behavior of the detected object 300;And
The management strategy is executed, to manage the environment 200 that the meeting room 404 is formed, to make the environment 200 state adapts to the state of the detected object 300.
According to the other side of the utility model, the utility model further provides for an environmental management technique, wherein described Environmental management technique includes the following steps:
(A) behavior of at least detected object 300 in an environment 200 is obtained;
(B) management strategy is generated according to the behavior of the detected object 300;And
(C) management strategy is executed, to manage the environment 200.
For example, this in the environmental management system 100 shown in attached drawing 2A to Fig. 2 D is specifically applied in example, it can To obtain behavior of the user in the study 401 first, then the behavior according to user in the study 401 generates institute Management strategy is stated, and adjusts the state in the study 401 when executing the management strategy, so that the reality in the study 401 When state and user real-time behavior be adapted.In this of the environmental management system 100 shown in attached drawing 3A to Fig. 4 Specifically using in example, behavior of the user in the room 402 can be obtained first, then according to the behavior of user The management strategy is generated, and adjusts the state in the room 402 when executing the management strategy, so that the room 402 real-time status and the real-time behavior of user are adapted.In the environmental management system 100 shown in attached drawing 5A to Fig. 6 This specifically apply in example, behavior of the user in the parlor 403 can be obtained first, then according to user Behavior generate the management strategy, and the state in the parlor 403 is adjusted when executing the management strategy, so that institute The real-time behavior of the real-time status and user of stating parlor 403 is adapted.In the environmental management shown in attached drawing 7A to Fig. 8 In this specific example of system 100, behavior of the user in the meeting room 404 can be obtained first, then basis The behavior of user generates the management strategy, and the state of the meeting room 404 is adjusted when executing the management strategy, So that the real-time status of the meeting room 404 and the real-time behavior of user are adapted.
Preferably, in the step (C) of the environmental management technique 1000, when executing the management strategy to adjust The mode of the wave frequency of the whole environment 200 manages the environment 200.For example, the processor 101 is executing the management plan The direction of the wave frequency of different frequency range can be generated when slightly by the wave frequency generator 104 to the study 401, the room 402, emit wave frequency in the parlor 403 and the meeting room 404, so as to adjust the study 401, room 402, described The frequency range of the wave frequency for the environment 200 that parlor 403 and the meeting room 404 are formed adjusts the ring in this way The state in border 200, and it is adapted the real-time status of the environment 200 and the real-time behavior of user.
Further, further comprise step in the step (A):
(A.1) action mode of the detected object 300 of the detection in the environment 200;With
(A.2) action mode according to the detected object 300 in the environment 200 determines the detected object 1021 the environment 200 behavior.
It is noted that in the step (A.1), movement of the detected object 300 in the environment 200 Mode includes shift action and micromotion.In the present invention, the detected object 300 is detected first in the environment Whether there is shift action in 200, if detect the detected object 300 in the environment 200 there are shift action, this When, the wave frequency generator 104 is opened, and continues to test the detected object 300 and whether there is in the environment 200 Micromotion, if detecting the detected object 300, there are micromotions in the environment 200, at this point, the wave frequency is sent out Raw device 104 is maintained at opening state, if not detecting micromotion, the wave frequency generator 104 is closed.
It will be appreciated by persons skilled in the art that when the detection beam radiation of the beam emitter 102 transmitting When to the detected object 300, the time that the different parts of the detected object 300 respond the detection beam is different, And subsequent, described in the different parts response by the detected object 300 that the signal receiver 103 receives The time of detection beam is not also identical, and according to such principle, the processor 101 is able to detect in the detection zone The action mode of 1021 detected object 300, and once the detected object 300 in the detection zone 1021 Action mode be acquired, then the detected object 300 can be also determined in the behavior of the detection zone 1021.
Further, further comprise step in the step (A.1):
(A.1.1) inspection policies are based on an at least beam emitter 102 and issue a detection beam to the environment 200 Mode form the detection zone 1021 in the environment 200 by the detection beam;
(A.1.2) it receives and is in the detection wave that the detected object 300 of the detection zone 1021 responds Beam;And
(A.1.3) according to the detection beam detection responded by the detected object 300 in the detection zone The action mode of 121 detected object 300.
It is noted that the inspection policies in the step (A.1.1) are selected from: layered weighting strategy, subregion Domain inspection policies, action mode inspection policies, carry out judgement and predicting strategy composition to motion track at subangle inspection policies Tactful group.That is, the beam emitter 102 is in which way to the environment 200 in the step (A.1.1) Emit the detection beam.Such as in some embodiments, the beam emitter 102 is in a manner of layered weighting to the ring Border 200 emits the detection beam, in further embodiments, the beam emitter 102 by subregion detect in a manner of to The environment 200 emits the detection beam, and in further embodiments, the beam emitter 102 is detected with subangle Mode emits the detection beam to the environment 200.
According to the other side of the utility model, with reference to attached drawing 9, the environmental management system 100 of the utility model into One step includes a processing unit 10, a strategy generating unit 20 and an execution unit 30, wherein the processing unit 10, described Strategy generating unit 20 and the execution unit 30 are mutually communicatively coupled respectively, wherein the processing unit 10 is for obtaining The behavior of at least one detected object 300 in the environment 200, the strategy generating unit 20 is according to the place The behavior for managing the detected object 300 in the environment 200 that unit 10 obtains generates the management strategy, described Execution unit 30 manages the environment 200 in a manner of adjusting the state of the environment 200 when executing the management strategy.
Preferably, described to execute list in this specific example of the environmental management system 100 of the utility model Member 30 is when executing the management strategy by adjusting the wave frequency generator in a manner of the external wave frequency generator 104 The frequency range of 104 wave frequencies issued changes the real-time status of the environment 200, to manage the environment 200.That is, The execution unit 30 can control the working condition of the wave frequency generator 104.
With further reference to attached drawing 9, the environmental management system 100 further comprises a detection unit 40, wherein the inspection It surveys unit 40 to be communicatively connected in a network in the processing unit 10, wherein the detection of the detection unit 40 is in the environment 200 The detected object 300 action mode, with subsequent, the processing unit 10 can be obtained according to the detection unit 40 The detected object 300 obtain the detected object 300 described in the mode of the action mode of the environment 200 The behavior of environment 200.
Further, the environmental management system 100 further comprises a receiving unit 50, wherein the detection unit 40 are communicatively connected in a network in the receiving unit 50, and the receiving unit 50 is communicatively connected in a network in the signal receiver 103, wherein the receiving unit 50 obtains institute from the signal receiver 103 in a manner of the external signal receiver 103 The detection beam that the received detected object 300 for being in the environment 200 of signal receiver 130 responds is stated, And subsequent, the detection unit 40 can receive the inspection that the receiving unit 50 obtains from the receiving unit 50 Wave beam is surveyed, and the detected object 300 is obtained in the action mode of the environment 200 according to the detection beam.
Further, the environmental management system 100 further comprises an adjustment unit 60, described in wherein at least one Beam emitter 102 can be adjustably coupled to the adjustment unit 60, so that the adjustment unit 60 is for adjusting institute The angle of the detection beam of the sending of beam emitter 102 is stated, thus the detection for issuing the beam emitter 102 The detection zone 1021 of Wave beam forming is dynamic detection region 1021.
In an example of the environmental management system 100 of the utility model, the adjustment unit 60 can be controlled The whole position of the beam emitter 102 is adjusted, for example, the adjustment unit 60 can control the beam emitter 102 are adjusted relative to the angle of an installation site (such as the ceiling 4011 in the study 401).And it is practical at this In another example of the novel environmental management system 100, the adjustment unit 60 can control the beam emitter 102 a part of structure is adjusted, to change the angle for the detection beam that the beam emitter 102 issues.
Specifically, attached drawing 10A to Figure 11 D shows a specific example of the beam emitter 102, wherein described Beam emitter 102 forms the detection zone 1021 in the environment 200 in a manner of emitting microwave to the environment 200, For detecting the detected object 300 in the action mode of the environment 200.Specifically, the beam emitter 102 is wrapped Including a reference plate 11 and a radiation source 12, the reference plate 11 further comprises a plate main body 111 and an at least flank 112, In each flank 112 be arranged at the plate main body 111 respectively, and each flank 112 respectively with the plate master Body 111 has default angle, and the radiation source 12 is neighboringly set to the reference plate 11, in the radiation source 12 and institute It states and forms a radiating slot 120 between the plate main body 111 of reference plate 11.The beam emitter 102 is each by providing The mode of the flank 112 can constrain the radiation source 12 and the plate main body 111 cooperates and the detection of generation The sending angle of wave beam, and then control the beam direction of the detection beam.
It is noted that although this in the beam emitter 102 shown in attached drawing 10A to Figure 11 D is specific It discloses and is illustrated described in the utility model by taking the beam emitter 102 includes two flanks 112 as an example in example The content and feature of beam emitter 102, in other possible examples of the beam emitter 102 of the utility model, The quantity of the flank 112 of the beam emitter 102 can also be with one or three or more.It is noted that institute State surface and institute that the radiating slot 120 formed between radiation source 12 and the plate main body 111 refers to the radiation source 12 The surface for stating plate main body 111 has difference in height.That is, being formed in the beam emitter 102 of the utility model The radiating slot 120 between the radiation source 12 and the plate main body 111 can be but not limited to tangible media.
Preferably, each flank 112 is adjustably set to the side of the plate main body 111 respectively, for adjusting It saves the radiation source 12 and the plate main body 111 cooperates and the sending angle of the detection beam of generation.Specifically, The plate main body 111 and each flank 112 are respectively provided with a plane of reference 110, and the radiation source 12 is neighboringly set to The plate main body 111 of the reference plate 11, and the plate of the extending direction of the radiation source 12 and the reference plate 11 Plane where the plane of reference 110 of main body 111 is parallel, by adjusting each flank 112 and the plate main body 111 The mode of angle, can control the radiation source 12 and the plate main body 111 cooperate and the detection beam that generates Angle is issued, and then the beam direction of the control detection beam and control are formed in the detection zone of the environment 200 1021 position.Preferably, in this specific example of the beam emitter 102 shown in attached drawing 10A, the flank 112 quantity is two, and two flanks 112 are adjustable respectively in two symmetrical modes of the flank 112 It saves land and is set to the side of the plate main body 111, so that two flanks 112 are equal relative to the angle of the plate main body 111 It can be adjusted.Further, it is single to be controllably connected to the adjustment for the flank 112 of the beam emitter 102 Member 60, wherein the adjustment unit 60 can adjust angle of the flank 112 relative to the plate main body 111, to adjust The sending angle of the detection beam of the transmitting of beam emitter 102 is stated, the subangle of the environment 200 is examined to realize It surveys, subregion is detected and layered weighting.
It is noted that in a specific example of the beam emitter 102 of the utility model, the wave The flank 112 of two of beam transmitter 102 can be conditioned respectively relative to the angle of the plate main body 111, that is, adjusted When angle of one flank 112 relative to the plate main body 111, another described flank 112 is relative to the plate main body 111 angle can be constant.And in another specific example of the beam emitter 102 of the utility model, it is described The flank 112 of two of beam emitter 102 can be by synchronously and with amplitude relative to the angle of the plate main body 111 It adjusts.
It is noted that angle of the flank 112 of the beam emitter 102 relative to the plate main body 111 Adjustable mode is unrestricted, such as in the specific example of the beam emitter 102 shown in attached drawing 10A to Figure 10 C, The flank 112 is sent out by being adjustably set to the side of the plate main body 111 in a manner of rotatable in the wave beam In other some specific examples of emitter 102, the flank 112 is with a part of deformable side of the plate main body 111 Formula is adjustably set to the side of the plate main body 111.With further reference to attached drawing 10A to Figure 10 C, if the radiation source Linear distance parameter of 12 outermost to the flank 112 of the reference plate 11 and the link position of the plate main body 111 For L, if the wavelength parameter for the detection beam that the radiation source 12 issues is λ, the wherein value range of parameter L are as follows: L≤λ/ 16.If the outermost parameter of the flank 112 and link position to the flank 112 of the plate main body 111 is l, wherein The value range of parameter l are as follows: l >=λ/4.
With continued reference to attached drawing 10A to Figure 10 C, the beam emitter 102 further comprises a shielding case 13, wherein described Shielding case 13 is arranged at the back side of the plate main body 111 of the reference plate 11, so that the shielding case 13 and the radiation Source 12 is respectively held in the two sides of the plate main body 111 of the reference plate 11, wherein there is the shielding case 13 shielding to make With, to enhance the intensity for the detection beam that the beam emitter 102 issues, thus it is subsequent more accurately obtain described in The movement of detected object 300.In addition, the shielding case 13 also have the function of it is dust-proof and moisture-proof.Preferably, the shielding case The height dimension of 13 inner space is greater than 1/32 times of wavelength, and in this way, the beam emitter 102 can be kept away The complementary wave for exempting from itself generation generates interference to main wave, and then guarantees the stability and reliability of the beam emitter 102.
Attached drawing 11A shows a working condition of the beam emitter 102, at this point, the beam emitter 102 The flank 112 of two of the reference plate 11 and the plate main body 111 are in unfolded state.Attached drawing 11B shows the wave Another working condition of beam transmitter 102, at this point, the left side positioned at attached drawing 11B of the beam emitter 102 is described Flank 112 is adjusted so that the detection wave that the beam emitter 102 emits relative to the angle of the plate main body 111 The angle of beam can be adjusted so that the position for the detection zone 1021 for forming the detection beam is also adjusted therewith Section.Attached drawing 11C shows another working condition of the beam emitter 102, at this point, the position of the beam emitter 102 The flank 112 on the right side of attached drawing 11C is adjusted so that the beam emitter relative to the angle of the plate main body 111 The angle of the detection beam of 102 transmittings can be adjusted so that the detection zone for forming the detection beam 1021 position is also conditioned therewith.Attached drawing 11D shows another working condition of the beam emitter 102, at this point, institute Two flanks 112 for stating beam emitter 102 be adjusted so that relative to the angle of the plate main body 111 make it is described The angle for the detection beam that beam emitter 102 emits, which can be adjusted so that, makes the described of the detection beam formation The position of detection zone 1021 is also conditioned therewith.Certainly, it will be apparent to a skilled person that with the flank 112 are conditioned relative to the size of the angle of the plate main body 111, the mobile position of the detection zone 1021 and the inspection The size for surveying region 1021 can be controlled.
Attached drawing 12A to Figure 12 D shows a variant embodiment of the beam emitter 102, with attached drawing 10A to figure Unlike the beam emitter 102 shown in 10C, in the beam emitter 102 shown in attached drawing 12A to Figure 12 D In this embodiment, the reference plate 11 only includes a plate main body 111, that is, the reference plate 11 is unadjustable.It is described The extending direction of radiation source 12 and the extending direction of the plane of reference 110 of the plate main body 111 of the reference plate 11 are mutual Vertically, and between the radiation source 12 and the plate main body 111 radiating slot 120 is formed.The beam emitter 102 further comprise an at least wave beam confinement element 14, wherein the wave beam confinement element 14 is neighboringly set to the spoke Source 12 is penetrated, the transmitting of the detection beam generated for constraining the radiation source 12 and the plate main body 111 mutual cooperation Direction.
Specifically, in this specific example of the beam emitter 102 shown in attached drawing 12A to Figure 12 D, institute Wave beam confinement element 14 is stated with a constraint space 140, wherein the radiation source 12 is maintained at the wave beam confinement element 14 The constraint space 140, so that the radiation source 12 and the plate main body 111 cooperate and the detection wave that generates Beam can be constrained and via the opening of the wave beam confinement element 14 from the constraint space 140 by the wave beam confinement element 14 It outwardly radiates, wherein the wave beam confinement element 14 is used to constrain the launch angle of the detection beam radiated, in turn Limit the location and shape for the detection zone 1021 that the detection beam is formed.Preferably, the wave beam confinement element 14 It is arranged at the plate main body 111 of the reference plate 11, so that the radiation source 12 is maintained at the wave beam confinement element 14 constraint space 140.It is highly preferred that the wave beam confinement element 14 is in horn-like.Attached drawing 13A to Figure 13 C is shown The type for the detection beam that this embodiment of the beam emitter 102 of attached drawing 12A to Figure 12 D generates.
Attached drawing 14 and Figure 15 show another variant embodiment of the beam emitter 102, extremely with attached drawing 12A Unlike the beam emitter 102 shown in Figure 12 D, in the beam emitter 102 shown in attached drawing 14 and Figure 15 In this specific example, the wave beam confinement element 14 is plate-like, wherein the wave beam confinement element 14 be maintained at it is described The side of radiation source 12 produces for constraining the plate main body 111 mutual cooperation of the radiation source 12 and the reference plate 11 Raw microwave, to control the launch angle for the detection beam that the beam emitter 102 emits.Preferably, the wave The extending direction of beam confinement element 14 and the extending direction of the plate main body 111 are mutually perpendicular to or the wave beam confinement element There is angle, and the angle is acute angle between 14 extending direction and the extending direction of the plate main body 111.
Further, the wave beam confinement element 14 has a groove 141, for accommodating the radiation source 12, and institute Stating has gap between radiation source 12 and the wave beam confinement element 14.That is, the radiation source 12 and the wave beam are about Beam element 14 does not contact.The type for the detection beam that the beam emitter 102 with reference to shown in attached drawing 15 generates, It can be seen that attached drawing 14 and the beam emitter 102 shown in Figure 15 are particularly suitable for carrying out subregion to the environment 200 Detection, subangle detection and layered weighting.
It is noted that the quantity of the wave beam confinement element 14 is also possible to two, wave beam described in two of them is about Beam element 14 can be arranged on the opposite side of the radiation source 12, by two constraints jointly of wave beam confinement element 14 The radiation source 12 and the plate main body 11 cooperate and the direction of the launch of the detection beam of generation.In the utility model One embodiment in, two wave beam confinement elements 14 can be symmetrical.And the utility model another In embodiment, the extending direction of two wave beam confinement elements 14 also can have angle.
Attached drawing 16 and Figure 17 shows another variant embodiment of the beam emitter 102, with attached drawing 14 and figure Unlike the beam emitter 102 shown in 15, in this of the beam emitter 102 shown in attached drawing 16 and Figure 17 In specific example, the quantity of the radiation source 12 is two, wherein each radiation source 12 be vertically disposed at it is described The plate main body 111 of reference plate 11.Correspondingly, the quantity of the wave beam confinement element 14 is two, wherein each wave Beam confinement element 14 is adjacent with each radiation source 12 respectively, to constrain respectively often by each wave beam confinement element 14 A radiation source 12 and the plate main body 111 cooperate and the microwave of generation, to control the beam emitter 102 The launch angle of the detection beam of transmitting.Preferably, two wave beam confinement elements 14 are adjacent, that is, two waves Beam confinement element 14 is located between two radiation sources 12, so that each wave beam confinement element 14 can respectively about The each radiation source 12 of beam and the plate main body 111 cooperate and the microwave of generation, so that 102 energy of the beam emitter Enough emit two non-interfering detection beams.The beam emitter 102 shown in attached drawing 16 is particularly suitable for described Environment 200 carries out subregion detection, subangle detection and layered weighting.
With continued reference to attached drawing 14 to Figure 17, the beam emitter 102 further comprises the shielding case 13, Described in shielding case 13 be arranged at the reference plate 11 the plate main body 111 back side so that the shielding case 13 and institute The opposite side that radiation source 12 is respectively held in the plate main body 111 of the reference plate 11 is stated, wherein the shielding case 13 has Have shielding action, to enhance the intensity for the detection beam that the beam emitter 102 issues, thus it is subsequent more accurately Obtain the movement of the detected object 300.In addition, the shielding case 13 also have the function of it is dust-proof and moisture-proof.Preferably, institute The height dimension for stating the inner space of shielding case 13 is greater than 1/32 times of wavelength, in this way, the beam emitter 102 complementary waves that can be avoided itself generation generate interference to main wave, so guarantee the beam emitter 102 stability and can By property.
Attached drawing 18 and Figure 19 show a variant embodiment of the beam emitter 102, with attached drawing 10A to figure Unlike the beam emitter 102 shown in 11D, in this of the beam emitter 102 shown in attached drawing 18 and Figure 19 In a variant embodiment, the reference plate 11 of the beam emitter 102 includes a plate main body 111 and is set It is placed in a stiffening plate 113 of the plate main body 111, wherein the stiffening plate 113 is used to expand the ginseng of the plate main body 111 The area in face 110 is examined, in this way, generates microwave when the radiation source 12 and the plate main body 111 mutual cooperation When, the stiffening plate 113 is used to enhance the intensity for the detection beam that the beam emitter 102 generates, this is for described It is especially important that whether detection system, which can capture the detected object 300 in the micromotion of the environment 200,.
Preferably, the plate main body 111 and the stiffening plate 113 are riveted on together, to guarantee 111 He of plate main body The reliability of connection relationship between the stiffening plate 113.For example, in the present invention, the plate main body 111 provides default Perforation, the stiffening plate 113 provide default perforation, wherein after the stiffening plate 113 is arranged at plate main body 111, The default perforation of at least one of the stiffening plate 113 corresponds to a default perforation of the plate main body 111, then the plate again The exposed surface of the surface of main body 111 and the stiffening plate 113 is tin plating or copper facing, in the institute for forming the reference plate 11 While stating the plane of reference 110, metal material can be maintained at the default perforation and the plate main body of the stiffening plate 113 simultaneously 111 default perforation, so that the stiffening plate 113 and the plate main body 111 are riveted on together.In attached drawing 18 and Figure 19 In this specific example of the beam emitter 102 shown, the stiffening plate 113 can be arranged at the stiffening plate 113。
In addition, although in this specific example of the beam emitter 102 shown in attached drawing 18 and Figure 19, with institute State the radiation source 12 of beam emitter 102 extending direction it is with the extending direction of the plate main body 111 consistent for take off The content and feature of the beam emitter 102 of dew and elaboration the utility model, still, it should be understood by those skilled in the art that , in other possible examples of the beam emitter 102 of the utility model, the institute of the beam emitter 102 The extending direction for stating radiation source 12 can also be perpendicular to the extending direction of the plane of reference 110 of the plate main body 111.
Other side according to the present utility model, the utility model further provide for a detection method, wherein the inspection Survey method includes the following steps:
(a) an at least detection zone 1021 is formed in an environment 200 by an at least detection beam;
(b) detection beam responded by an at least detected object 300 for being in the detection zone 1021 is received;
(c) detected object 300 is obtained in the movement of the environment 200 according to the detection beam being received Signal;And
(d) action signal based on the detected object 300 in the environment 200 detects the detected object 300 In the action mode of the environment.
Preferably, the detected object 300 includes shift action mode and fine motion in the action mode of the environment 200 Action mode.
Further, further comprise step in the step (d):
(d.1) action signal and preset threshold of the detected object 300 in the environment 200;With
(d.2) detected object 300 is detected in the action mode of the environment according to comparison result.
In the above-mentioned methods, action signal and deliberate action threshold of the detected object 300 in the environment 200 Value, it is described if the detected object 300 is more than or equal to deliberate action threshold value in the action signal of the environment 200 Detected object 300 is shift action mode in the action mode of the environment 200, and the detected object 300 is in institute The action mode and default fine motion threshold value for stating environment 200, if the detected object 300 is in the action signal of the environment 200 More than or equal to default fine motion threshold value, then the detected object 300 is micromotion in the action mode of the environment 200 Mode.In the detection method of the utility model, if the parameter of the deliberate action threshold value is V1, if the default fine motion The parameter of threshold value is V2, wherein the parameter V1 of the deliberate action threshold value and parameter V2 of the default fine motion threshold value meets public affairs Formula:Wherein k is constant, and the value of k is preferably 6, i.e., the parameter V1 of the described deliberate action threshold value and The parameter V2 of the default fine motion threshold value preferably meets formula:
According to the other side of the utility model, with reference to attached drawing 20, the utility model further provides for a detection system 400, wherein the detection system 400 includes an at least beam emitter 102, an at least signal receiver 103, one movement letter Number acquiring unit 70 and a detection unit 40, wherein the action signal acquiring unit 70 be communicatively connected in a network respectively in The signal receiver 103 and the detection unit 40, wherein the beam emitter 102, which is based on the inspection policies, issues institute Detection beam is stated to be used to form the detection zone 102, the reception of signal receiver 103 is in the detection zone The detection beam that 102 detected object 300 responds, the action signal acquiring unit 70 connect from the signal Device 103 is received to obtain the received detection beam of the signal receiver 103 and obtained according to the detection beam being received The detected object 300 the environment 200 action signal, wherein the detection unit 40 be based on the detected object 300 detect the detected object 300 in the action mode of the environment 200 in the action signal of the environment 200.It is preferred that The action mode on ground, the detected object 300 includes shift action and micromotion.
Specifically, the detection unit 40 further comprises a comparison module 41 and is communicatively connected in a network in the ratio Compared with a detection module 42 of module 41, wherein the comparison module 41 is communicatively connected in a network in the action signal acquiring unit 70.The comparison module 41 detected object 300 the environment 20 action signal and preset threshold, it is described Detection module 42 detects the detected object 300 in the dynamic of the environment 200 according to the comparative structure of the comparison module 41 Operation mode.More specifically, action signal of the comparison module 41 detected object 300 in the environment 200 With deliberate action threshold value, if the detected object 300 the environment 200 action signal be more than or equal to deliberate action Threshold value, then the detected object 300 is shift action mode in the action mode of the environment 200, wherein the relatively mould The detected object 300 of block 42 the environment 200 action mode and default fine motion threshold value, if it is described be detected pair As 300 are more than or equal to default fine motion threshold value in the action signal of the environment 200, then the detected object 300 is in institute The action mode for stating environment 200 is micromotion mode.
Further, the detection system 400 includes a processing unit 10, wherein the processing unit 10 is by communicably It is connected to the detection unit 40, wherein described detected pair that the processing unit 10 is detected according to the detection unit 40 As 300 action mode obtains the behavior of the detected object 300.
Further, the detection system 400 includes an adjustment unit 60, wherein the beam emitter 102 is adjustable It saves land and is connected to the adjustment unit 60, wherein the adjustment unit 60 is used to adjust the institute that the beam emitter 102 issues The angle of detection beam is stated, so that the detection zone 102 that the detection beam is formed is dynamic detection region 102.
Attached drawing 21A to Figure 21 C shows the detection system 400 and is executing the detection plan comprising layered weighting strategy When slightly, the state for the detection zone 1021 that the detection beam that the beam emitter 102 issues is formed.Specifically It says, in this specific example shown in attached drawing 21A, in the short transverse of the environment 200, every layer of detection zone 1021 height dimension is consistent.In this specific example shown in attached drawing 21B, the height of every layer of detection zone 1021 Size is successively successively decreased to the lower part from the top of the environment 200.In this specific example shown in attached drawing 21C, it is formed in The height dimension of the detection zone 1021 of every layer of the top of the environment 200 is greater than the lower part for being formed in the environment 200 Every layer of detection zone 1021 height dimension.It is noted that although described in shown in attached drawing 21A to Figure 21 C When executing the inspection policies comprising layered weighting strategy, the beam emitter 102 issues described detection system 400 In these examples for the detection zone 1021 that detection beam is formed, the adjacent detection zone 1021 is in parallel described Detection zone 1021, it will be appreciated by those skilled in the art that the adjacent detection zone 1021 is the parallel detection zone Domain 1021 is merely illustrative, and is not construed as the limitation of the content and range to the detection system 400 of the utility model.
The detection system 400 shown in attached drawing 22 execute include the inspection policies of subregion inspection policies when, The state for the detection zone 1021 that the detection beam that the beam emitter 102 issues is formed.Specifically, described Beam emitter 102 can emit the detection wave simultaneously or according to sequencing to the different location of the environment 200 Beam, to form the detection zone 1021 in the environment 200 by the detection beam.It is noted that in attached drawing The rectangular detection zone 1021 of the column that the detection beam shown in 22 is formed in the environment 200 is only to show Example, with the content and feature of the detection system for illustrating and disclosing the utility model, and is not construed as to this reality With the limitation of the content and range of the novel detection system 400.For example, in the detection system 400 of the utility model Other examples in, the detection zone 1021 that the detection beam is formed can be but not limited to the inspection of round ellipse Region is surveyed, and the size of the adjacent detection zone 1021 can also be inconsistent.
The detection system 400 shown in attached drawing 23A and Figure 23 B is executing the detection comprising subangle inspection policies When tactful, the state for the detection zone 10921 that the detection beam that the beam emitter 102 issues is formed.Specifically Say that the beam emitter 102 can be simultaneously or according to sequencing to described in the transmitting of the different angle of the environment 200 in ground Detection beam, to form the detection zone 1021 in the environment 200 by the detection beam.It is noted that The beam emitter 102 emits institute to the environment 200 when executing includes the inspection policies of subangle inspection policies The size of the detection zone 1021 stating detection beam and being formed can be different.
It will be appreciated by those skilled in the art that above embodiments are only for example, wherein the feature of different embodiments It can be combined with each other, do not explicitly pointed out in the accompanying drawings with obtaining being readily conceivable that according to the content that the utility model discloses Embodiment.
It should be understood by those skilled in the art that foregoing description and the embodiments of the present invention shown in the drawings are only used as It illustrates and is not intended to limit the utility model.The purpose of this utility model completely and effectively realizes.The function of the utility model Energy and structural principle show and illustrate in embodiment, under without departing from the principle, the embodiments of the present invention Can there are any deformation or modification.

Claims (27)

1. beam emitter characterized by comprising
An at least radiation source;
An at least wave beam confinement element;And
One reference plate, wherein the reference plate includes a plate main body, wherein the plate main body has a plane of reference, the radiation source The plate main body is arranged in a manner of the plane of reference for extending perpendicularly to the plate main body of the radiation source, and And a radiating slot is formed between the radiation source and the plate main body, wherein the wave beam confinement element is neighboringly arranged In the radiation source, generated with constraining the radiation source and plate main body mutual cooperation by the wave beam confinement element The radiation direction of microwave.
2. beam emitter according to claim 1, wherein the wave beam confinement element is arranged at the plate main body.
3. beam emitter according to claim 2, wherein the wave beam confinement element has a constraint space, the spoke The source of penetrating is maintained at the constraint space of the wave beam confinement element.
4. beam emitter according to claim 3, wherein the wave beam confinement element is in horn-like.
5. beam emitter according to claim 2, wherein the wave beam confinement element is plate-like, and the wave beam is about Beam element is proximally retained the side of the radiation source.
6. beam emitter according to claim 5, wherein extending perpendicularly to for the wave beam confinement element is described The extending direction of the plane of reference of plate main body.
7. beam emitter according to claim 6, wherein the wave beam confinement element has a groove, the radiation source It is maintained at the groove of the wave beam confinement element.
8. according to the beam emitter any in claim 5 to 7, wherein the quantity of the radiation source is one, it is described The quantity of wave beam confinement element is two, and two wave beam confinement elements are maintained at the opposite side of the radiation source.
9. according to the beam emitter any in claim 5 to 7, wherein the quantity of the radiation source is two, it is described The quantity of wave beam confinement element is two, and two wave beam confinement elements are maintained between two radiation sources.
10. beam emitter according to claim 8, wave beam confinement element described in two of them is symmetrical.
11. beam emitter according to claim 9, wave beam confinement element described in two of them is symmetrical.
12. beam emitter according to claim 8, the extending direction of wave beam confinement element described in two of them has folder Angle.
13. beam emitter according to claim 9, the extending direction of wave beam confinement element described in two of them has folder Angle.
14. further comprising a shielding case, wherein the shielding according to claim 1 to any beam emitter in 7 Cover is arranged at the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite of the plate main body Side.
15. beam emitter according to claim 8 further comprises a shielding case, wherein the shielding case is set In the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite side of the plate main body.
16. beam emitter according to claim 9 further comprises a shielding case, wherein the shielding case is set In the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite side of the plate main body.
17. beam emitter according to claim 10 further comprises a shielding case, wherein the shielding case is set In the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite side of the plate main body.
18. beam emitter according to claim 11 further comprises a shielding case, wherein the shielding case is set In the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite side of the plate main body.
19. beam emitter according to claim 12 further comprises a shielding case, wherein the shielding case is set In the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite side of the plate main body.
20. beam emitter according to claim 13 further comprises a shielding case, wherein the shielding case is set In the side of the plate main body, and the shielding case and the radiation source are maintained at the opposite side of the plate main body.
21. beam emitter according to claim 14, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
22. beam emitter according to claim 15, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
23. beam emitter according to claim 16, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
24. beam emitter according to claim 17, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
25. beam emitter according to claim 18, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
26. beam emitter according to claim 19, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
27. beam emitter according to claim 20, wherein setting the wavelength parameter for the wave that the beam emitter generates For λ, wherein the distance formed between the inner surface of the shielding case and the surface of the plate main body is more than or equal to 1/32 λ.
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CN208314196U (en) 2019-01-01
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CN108872976A (en) 2018-11-23
CN108398681B (en) 2023-12-29
WO2019154063A1 (en) 2019-08-15

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