CN220653579U - Lamp controller, system and positioning system - Google Patents

Abstract

The utility model relates to the technical field of lighting devices, in particular to a lamp controller, a system and a positioning system, wherein the lamp controller is used for controlling the switch and the brightness of a lighting lamp and comprises a control module and a signal transmission module, the control module is electrically connected with the lighting lamp to control the switch and the brightness of the lighting lamp, the signal transmission module comprises an L O RA unit, and the L O RA unit is in signal connection with the control module; the control module is in signal connection with external equipment through the L O RA unit, the L O RA unit is used for receiving external information and transmitting the external information to the control module, and the technical problem that the arrangement is complicated due to the fact that the lighting lamp is controlled through a signal wire in the prior art is solved.

Description

Lamp controller, system and positioning system

[ field of technology ]

The utility model relates to the technical field of lighting devices, in particular to a lamp controller, a lamp controller system and a lamp positioning system.

[ background Art ]

In the night or in the environment that illuminance is lower, need use the illumination lamps and lanterns to provide illumination in order to operate, among the prior art, in order to be convenient for control to all lamps and lanterns, need draw longer signal line to gather to gateway or centralized controller to every lamps and lanterns, this kind of mode based on bus transmission causes the trouble for the site operation, has increased the deployment cost, simultaneously, in the change of later stage construction and other buildings, natural loss etc. all probably causes the destruction to the bus, is inconvenient for later maintenance.

[ utility model ]

The utility model provides a lamp controller, a lamp controller system and a positioning system, which are used for solving the technical problem that the deployment is complicated due to the fact that a signal wire is used for controlling an illuminating lamp in the prior art.

The utility model provides a lamp controller for controlling the switch and the brightness of a lighting lamp, which comprises a control module and a signal transmission module, wherein the control module is electrically connected with the lighting lamp to control the switch and the brightness of the lighting lamp, and the signal transmission module comprises a LORA unit which is in signal connection with the control module; the control module is in signal connection with external equipment through the LORA unit, and the LORA unit is used for receiving external information and transmitting the external information to the control module.

Preferably, the lamp controller further comprises an input module and an induction sensor connected with the input module in a signal mode, the input module is connected with the control module in a signal mode, when the induction sensor senses an external preset object, induction signals are transmitted to the control module through the input module, and the control module controls the switch and the brightness of the lighting lamp.

Preferably, the input module comprises a switching value signal detection unit and an analog value signal detection unit, and at least one of the switching value signal detection unit and the analog value signal detection unit is in signal connection with the induction sensor.

Preferably, the sensing sensor comprises an illuminance sensor, and the illuminance sensor is in signal connection with the control module through an input module.

Preferably, the induction sensor further comprises a microwave sensor, an infrared sensor, an AI image pickup identification sensor and/or a Bluetooth identification sensor which are in signal connection with the input module.

Preferably, the lamp controller further comprises a detection module, the control module is in signal connection with the detection module, and the detection module is used for detecting the on-off state of the current or voltage flowing through the lighting lamp and transmitting the signal to the control module for judging the on-off state of the lighting lamp.

Preferably, the lamp controller further comprises a protection module, the protection module comprises a voltage reduction unit, the input end of the voltage reduction unit is connected with an external power supply, and the input end of the voltage reduction unit is connected with the control module.

In order to further solve the problems, the utility model also provides a lamp control system, which comprises the lamp controller and also comprises a central control device, wherein the central control device is in signal connection with the control module through a LORA unit.

Preferably, the lamp control system further comprises a cloud end, the signal transmission module further comprises an LTE4G unit in signal connection with the control module, and the cloud end is in signal connection with the LTE4G unit.

In order to further solve the above problems, the present utility model further provides a positioning system, including the above-mentioned luminaire control system, where the luminaire control system includes at least two controllers, and a positioning system further includes a moving object and a transmitting module disposed on the moving object, where at least two LORA units are configured to receive signals on the transmitting module and transmit the signals to the control module and/or the central control device.

Compared with the prior art, the lamp controller system and the positioning system provided by the utility model have the following advantages:

1. the lamp controller provided by the embodiment of the utility model comprises a control module and a signal transmission module, wherein the control module is electrically connected with a lighting lamp to control the switch and the brightness of the lighting lamp, and the signal transmission module comprises an L O RA unit which is in signal connection with the control module; the control module is in signal connection with external equipment through an L O RA unit, and the L O RA unit is used for receiving external information and transmitting the external information to the control module; through such design, have the utilization and connect the lighting fixture controller through long-range signal, and then control the switch and the luminance of lighting fixture, thereby solved among the prior art through signal line control lamps and lanterns cause the loaded down with trivial details technical problem of deployment process, still be convenient for at the later stage remove or redeploy lamps and lanterns as required simultaneously.

2. The lamp controller provided by the embodiment of the utility model further comprises an input module and an induction sensor connected with the input module in a signal way, wherein the input module is connected with the control module in a signal way, when the induction sensor senses an external preset object, an induction signal is transmitted to the control module through the input module, and the control module controls the switch and the brightness of the lighting lamp.

3. The input module of the lamp controller provided by the embodiment of the utility model comprises the switching value signal detection unit and the analog value signal detection unit, wherein at least one of the switching value signal detection unit and the analog value signal detection unit is connected with the induction sensor through signals, and through the design, the lamp controller provided by the embodiment can be adapted to various types of sensors, so that the practicability is enhanced.

4. The lamp controller provided by the embodiment of the utility model further comprises a detection module, wherein the control module is in signal connection with the detection module, the detection module is used for detecting the on-off state of the current or voltage flowing through the lighting lamp and transmitting the signal to the control module for judging the on-off state of the lighting lamp, and through the time, a user can conveniently acquire the use state of the lighting lamp, so that the management of the lighting lamp is facilitated.

5. The lamp controller provided by the embodiment of the utility model further comprises a protection module, wherein the protection module comprises a voltage reduction unit, the input end of the voltage reduction unit is connected with an external power supply, and the input end of the voltage reduction unit is connected with the control module; through the design, external alternating-current high-voltage power can be reduced to direct-current low-voltage power required by the lamp controller, and the lamp controller provided by the embodiment can be suitable for different environments.

6. The lamp control system provided by the embodiment of the utility model comprises at least one lamp controller and also comprises a central control device, wherein the central control device is in signal connection with the control module through the LORA unit, and through the design, the central control device is utilized to manage the lighting lamp controllers and acquire the service conditions of all lighting lamps in the system.

7. The lamp system provided by the embodiment of the utility model further comprises a cloud end, wherein the signal transmission module further comprises an LT E4G unit in signal connection with the control module, and the cloud end is in signal connection with the LT E4G unit; through such design, the user of being convenient for carries out unified management to all lamps and lanterns controllers to and in time knows the state of current or history lamps and lanterns, and adjusts the illumination lamps and lanterns according to the state of current or history lamps and lanterns, compares in prior art, has retrieved the work load of control and adjustment by a wide margin.

8. The lamp control system at least comprises two lamp controllers, a moving object and a transmitting module arranged on the moving object, wherein at least two ORA units are used for receiving signals on the transmitting module and transmitting the signals to the control module and/or the central control equipment.

[ description of the drawings ]

Fig. 1 is a schematic frame diagram of a lamp controller according to a first embodiment of the present utility model.

Fig. 2 is a schematic diagram of a lamp controller, an external power source and a lighting lamp according to a first embodiment of the present utility model.

Fig. 3 is a schematic diagram of a lamp control system according to a second embodiment of the present utility model.

Fig. 4 is a schematic frame diagram of a positioning system according to a third embodiment of the present utility model.

The attached drawings are used for identifying and describing:

1. a luminaire controller; 2. a lighting fixture; 3. a central control device; 4. and (3) cloud end. 5. A moving object;

11. a control module; 12. a signal transmission module; 13. an input module; 14. a detection module; 15. a protection module; 16. an inductive sensor; 51. a transmitting module;

121. an L O RA unit; 122. LT E4G units; 131. a switching value signal detection unit; 132. an analog quantity signal detection unit; 151. and a step-down unit.

[ detailed description ] of the utility model

For the purpose of making the technical solution and advantages of the present utility model more apparent, the present utility model will be further described in detail below with reference to the accompanying drawings and examples of implementation. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It should be noted that the terms "first" and "second" and the like in the description and the claims of the present utility model are used for distinguishing between different objects and not for describing a particular sequential order.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Also, some of the terms described above may be used to indicate other meanings in addition to orientation or positional relationships, for example, the term "upper" may also be used to indicate some sort of attachment or connection in some cases. The specific meaning of these terms in the present utility model will be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, the terms "mounted," "configured," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; may be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements, or components. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Referring to fig. 1 and 2, the present utility model provides a lamp controller 1, which includes a control module 11 and a signal transmission module 12, wherein the control module 11 is electrically connected with a lighting lamp 2 to control the on-off and brightness of the lighting lamp 2, the signal transmission module 12 includes a LORA unit 121, and the LORA unit 121 is in signal connection with the control module 11;

note that, the luminaire controller 1 is used to control the on/off and brightness of the lighting luminaire 2, and in this embodiment, the local wireless communication is implemented by providing the LORA unit 121 on the luminaire controller 1.

Specifically, the LORA unit 121 is connected to an external device signal, such as a computer, and may be used to transmit the current state of the switch and brightness of the lighting fixture 2, or may be used to receive a control signal of the external device, and after receiving the control signal of the external device, the LORA unit 121 transmits the signal to the control module 11, so as to facilitate adjusting the state of the lighting fixture.

It can be appreciated that by providing the LORA unit 121 on the luminaire controller 1, the technical problem that the deployment process is complicated due to the control of the lighting luminaire 2 through the signal line in the prior art is solved, and the lighting luminaire 2 is also convenient to be moved or redeployed at a later stage as required.

Further, the lamp controller 1 further includes an input module 13 and an induction sensor 16 connected with the input module 13 in a signal manner, the input module 13 is connected with the control module 11 in a signal manner, when the induction sensor 16 senses an external preset object such as a human body, a vehicle, etc., an induction signal is transmitted to the control module 11 through the input module 13, and the control module 11 controls the on-off and the brightness of the lighting lamp 2.

It should be noted that an interface for installing the induction sensor 16 may be provided on the lamp controller 1, so that the induction sensor 16 is directly connected with the input module 13 through the interface, where the input module 13 further converts the induction signal of the induction sensor 16 into digital information that can be read by the control module 11, and further controls the switch and brightness of the lighting lamp 2 through the control module 11.

Specifically, the sensing sensor 16 has a sensing range, and when an object or a human body is located in the sensing range, the sensing signal is transmitted to the control module 11 through the input module 13, and the control module 11 controls the lighting lamp 2 to perform lighting. When an object or a human body is located outside the range, the induction sensor 16 does not output an induction signal, and the control module 11 turns off the lighting fixture 2.

In some embodiments, the sensing sensor 16 may also sense the brightness of the outside world, so as to send the sensing information of the brightness to the control module 11 through the input module 13, thereby implementing brightness adjustment of the lighting fixture 2 according to the brightness of the outside world. Specifically, when the external environment is darker, the lighting lamp 2 is turned on or the brightness of the lighting lamp 2 is increased; when the external environment is brighter, the lighting fixture 2 is turned off or the brightness of the lighting fixture 2 is turned down.

It can be appreciated that by arranging the induction sensor 16 and the input module 13, the lighting lamp 2 can also control the switch and adjust the brightness according to the actual environment, and the device is applicable to various environments such as construction sites, street lamps and the like, and saves energy sources.

Further, the input module 13 includes a switching value signal detecting unit 131 and an analog value signal detecting unit 132, and at least one of the switching value signal detecting unit 131 and the analog value signal detecting unit 132 is in signal connection with the inductive sensor 16.

Further, the inductive sensor 16 includes one or more of an illuminance sensor, a microwave sensor, an infrared sensor, an AI-camera recognition sensor, and a bluetooth recognition sensor.

The switching value signal detecting unit 131 (Digital detecting unit) is used to convert the signal of the trigger switch of the microwave into a Digital signal that can be identified by the control module 11, specifically, the switching value signal is a signal having only two states, usually indicated as on and off, and the switching value signal can be simply used to indicate the state of a certain switch, button or sensor, such as the on-off state of the switch, the pressed state of the button, and so on. The switching value signal detection port generally judges the state of the switching value signal by reading the level. Digital input ports or GPIOs are typically used to detect switching value signals, which are on when the signal is high and off when the signal is low.

The Analog signal detecting unit 132 (Analog detecting unit) is configured to convert an external Analog signal that changes linearly into an Analog voltage signal that can be recognized or received by the control module 11. Specifically, the analog quantity signal may represent various physical quantities such as temperature, pressure, light intensity, and the like. The analog signal detection port is commonly used for receiving the output signal of the analog sensor and converting the output signal into digital quantity for processing. Analog input ports or AD cs (analog to digital converters) are typically used to detect analog signals. The AD C converts the analog quantity signal into a digital quantity, and the magnitude of the analog quantity signal is represented by reading the numerical value of the digital quantity. The signal detection port is an interface for connecting and receiving switching value and analog value signals, and can perform corresponding detection and processing according to the characteristics of input signals. The switching value signal detection port can judge the switching state by reading the level state, and the analog value signal detection port needs to convert the analog value signal into the digital value for processing and analysis.

The illuminance sensor is used for detecting the illumination intensity information near the lamp controller 1 and converting the illumination amount into an electric signal to be output; the microwave sensor is used for detecting the existence and the movement of a moving object in an induction range by sending a microwave signal and detecting the reflection of the microwave signal; the infrared sensor can detect the motion condition of a human body or an object; the AI camera recognition sensor mainly analyzes the image or video data captured by the camera by utilizing an artificial intelligence algorithm to realize object recognition, face recognition, action analysis and the like; the bluetooth identification sensor needs to set bluetooth equipment on an object or a human body, and receives and analyzes signals sent by the bluetooth equipment through the bluetooth identification sensor for detecting the existence and the signal intensity of the equipment. In summary, the induction sensors 16 provided in the embodiment may have different functions, and different kinds of induction sensors 16 may be selected according to actual requirements, for example, when the lighting fixture 2 is required to obtain surrounding illuminance information, an illuminance sensor may be installed; when it is necessary to acquire surrounding person movement information, an infrared sensor or an AI-capturing recognition sensor may be used. Meanwhile, a plurality of induction sensors 16 may be combined to obtain different data, for example, an infrared sensor and an illuminance sensor are matched to be connected with the input module 13 respectively, so as to obtain nearby personnel movement information and illuminance information, so that the switch and the brightness of the lighting lamp 2 can be conveniently adjusted through the control module 11 according to the information, specifically, when a person is located in the induction range of the infrared sensor or the illuminance is lower, the control module 11 controls the lighting lamp 2 to be turned on according to the induction signal of the induction sensor 16, and if the person is located outside the induction range of the infrared sensor or the illuminance is higher, the control module 11 controls the lighting lamp 2 to be turned off.

In addition, since the lamp controller 1 in the prior art does not have the switching value detection port and the analog value signal detection port, the deployment process is complicated and the workload and the cost are increased because the signal line is required to be connected to the gateway or the centralized controller during the setting. In the present embodiment, by providing the switching value signal detecting unit 131 and the analog value signal detecting unit 132, it is advantageous to adapt to different types of induction sensors 16.

Specifically, since the illuminance sensor outputs luminance information of the vicinity, which represents a continuous physical quantity, the illuminance sensor is connected to the analog signal detection unit 132 to output the luminance information to the control module 11, and the control module 11 controls the on/off or luminance of the lighting fixture 2 according to the specific luminance information.

In some embodiments, a comparison module is provided in the control module 11, in which a threshold is set, when the brightness value or the light intensity is greater than the threshold, the control module 11 turns off the lighting fixture 2, and when the brightness value or the light intensity is not greater than the threshold, the control module 11 turns on the lighting fixture 2.

Specifically, the microwave sensor and the infrared sensor may be used to sense whether the human body is in the sensing range, and output the switching value information, so the microwave sensor and/or the infrared sensor may be connected to the switching value signal detection unit 131, and when the microwave sensor and/or the infrared sensor sense the human body, the switching value signal detection unit 131 outputs the sensing information to the control module 11, so as to control the switching and brightness of the lighting fixture 2.

It can be understood that by providing the switching value signal detecting unit 131 and the analog value signal detecting unit 132, the lamp controller 1 provided in this embodiment can be adapted to various types of sensors, and the practicability is enhanced.

Further, the lamp controller 1 further comprises a detection module 14, and the control module 11 is in signal connection with the detection module 14.

It should be noted that, the detecting module 14 is configured to detect the on/off state of the current or the voltage flowing through the lighting fixture 2, and transmit the detection signal to the control module 11 to determine the state of the lighting fixture 2, and specifically, the state of the lighting fixture 2 may include a switching state, brightness, and the like.

In some embodiments, by acquiring the status of the lighting fixture 2, the control module 11 may further send status information of the lighting fixture 2 to an external device, such as a computer, through the signal transmission module 12, such as the LORA unit 121, so that a user can know the current status of the lighting fixture, and if the status of the lighting fixture 2 is off, it can further determine whether the lighting fixture 2 has a fault, so that maintenance is facilitated in daily use.

Further, the lamp controller 1 further includes a protection module 15, the protection module 15 specifically includes a step-down unit 151, an input end of the step-down unit 151 is connected with an external power supply, and an input end of the step-down unit is connected with the control module 11.

It should be noted that, the step-down unit 151 is mainly responsible for step-down converting the external ac high voltage power into the dc high voltage power required by the lamp controller 1, which may be the same as the lamp controller 1 in this embodiment and suitable for different environments.

In some embodiments, the protection module 15 further comprises an EMC module that allows the luminaire controller 1 to function properly in an electromagnetic environment and without interfering with other surrounding devices and systems. Specifically, before use, the EMC conduction interference test can be performed to avoid interference generated by interference signals generated by the electronic equipment through a conductive medium or a public power line; the interference signal generated by the external equipment can be processed by adding a safety capacitor mode in the circuit, and the interference signal is transmitted to the electronic equipment through spatial coupling. Thereby preventing electromagnetic interference generated by some external electronic products from affecting or damaging the normal operation of the electronic equipment.

In some embodiments, the protection module 15 further includes an energy storage unit, which can implement conversion between electric energy and chemical energy, so as to solve the problem that the lighting fixture 2 and the fixture controller 1 can still be used normally in the case of sudden power failure or in an environment where the power supply network is not complete.

Referring to fig. 1 and 3, a lamp control system according to a second embodiment of the present utility model includes a lamp controller 1 according to at least one embodiment, and further includes a central control device 3, where a LORA unit 121 of the central control device 3 is connected to a control module 11 through signals.

It should be noted that, the lamp control system provided in this embodiment may be used to control a plurality of lamp controllers 1, so as to facilitate unified management of the plurality of lamp controllers 1, where the central control device 3 includes a remote controller, a computer or a mobile terminal such as a mobile phone, etc., and the control module 11 in the lamp controller 1 sends the state of the lighting lamp 2 to the central control device 3 through the LORA unit 121, so that a user can know the current switching and brightness states of the lighting lamp 2 conveniently, and meanwhile, the user may send a control signal through the central control device 3, where the control signal is transmitted to the control module 11 through the LORA unit 121, so as to implement remote adjustment of the switching and brightness of the lighting lamp 2.

Further, the lamp control system includes a cloud 4, the signal transmission module 12 further includes an LTE4G unit 122 in signal connection with the control module 11, and the cloud 4 is in signal connection with the LTE4G unit 122.

It should be noted that, compared with the LORA unit 121, the lte4G module supports high-speed data transmission, has a high transmission rate, and can transmit the service condition of the lamp to the cloud 4 for storage, so that a user can find the history state of the lamp.

In some embodiments, the lamp controller 1 may also be signal connected to the central control device 3 through the LTE4G unit 122, which is not specifically limited in this embodiment.

It can be appreciated that by the lamp control system provided by the embodiment, a user can manage all lamp controllers 1 uniformly, know the state of the current or history lamp in time, and adjust the lighting lamp 2 according to the state of the current or history lamp.

Referring to fig. 3 and 4, a positioning system according to a third embodiment of the present utility model includes a lamp control system according to the second embodiment, wherein the lamp control system includes at least two lamp controllers 1, a moving object 5, and a transmitting module 51 disposed on the moving object 5, and at least two LORA units 121 are configured to receive signals from the transmitting module 51 and transmit the signals to the control module 11 and/or the central control device 3.

It should be noted that, the transmitting module 51 is in signal connection with the forehead LORA unit 121 in the luminaire controller 1, and specifically, a LORA transmitting circuit is disposed in the transmitting module 51, so that an electrical signal sent by the transmitting module 51 may be received by the LORA module.

It should be noted that, in this embodiment, a triangulation method is used as the prior art, and the triangulation method is a positioning method based on triangle geometry principle, which is used to determine the position of the target object in space, and this embodiment is not repeated.

Specifically, by disposing and acquiring the position information of at least two lamp controllers 1, and installing the signal transmitting module 51 on the moving object 5/human body to be detected, when the moving object 5/human body moves, the transmitting module 51 is used for sending digital information to the surrounding, after the LORA unit 121 in the nearby lamp controllers 1 receives the information, the information is sent to the control module 11/central control device 3, the angle and distance of the transmitting module 51 relative to the lamp controllers 1 are calculated by the control module 11/central control device 3, and after the acquired and calculated information of the lamp controllers 1 are summarized, the specific position of the moving object 5 can be calculated, thereby realizing the positioning of the moving object 5.

Compared with the prior art, the lamp controller system and the positioning system provided by the utility model have the following advantages:

1. the lamp controller provided by the embodiment of the utility model comprises a control module and a signal transmission module, wherein the control module is electrically connected with a lighting lamp to control the switch and the brightness of the lighting lamp, and the signal transmission module comprises an L O RA unit which is in signal connection with the control module; the control module is in signal connection with external equipment through an LO RA unit, and the LORA unit is used for receiving external information and transmitting the external information to the control module; through such design, have the utilization and connect the lighting fixture controller through long-range signal, and then control the switch and the luminance of lighting fixture, thereby solved among the prior art through signal line control lamps and lanterns cause the loaded down with trivial details technical problem of deployment process, still be convenient for at the later stage remove or redeploy lamps and lanterns as required simultaneously.

2. The lamp controller provided by the embodiment of the utility model further comprises an input module and an induction sensor connected with the input module in a signal way, wherein the input module is connected with the control module in a signal way, when the induction sensor senses an external preset object, an induction signal is transmitted to the control module through the input module, and the control module controls the switch and the brightness of the lighting lamp.

3. The input module of the lamp controller provided by the embodiment of the utility model comprises the switching value signal detection unit and the analog value signal detection unit, wherein at least one of the switching value signal detection unit and the analog value signal detection unit is connected with the induction sensor through signals, and through the design, the lamp controller provided by the embodiment can be adapted to various types of sensors, so that the practicability is enhanced.

4. The lamp controller provided by the embodiment of the utility model further comprises a detection module, wherein the control module is in signal connection with the detection module, the detection module is used for detecting the on-off state of the current or voltage flowing through the lighting lamp and transmitting the signal to the control module for judging the on-off state of the lighting lamp, and through the time, a user can conveniently acquire the use state of the lighting lamp, so that the management of the lighting lamp is facilitated.

5. The lamp controller provided by the embodiment of the utility model further comprises a protection module, wherein the protection module comprises a voltage reduction unit, the input end of the voltage reduction unit is connected with an external power supply, and the input end of the voltage reduction unit is connected with the control module; through the design, external alternating-current high-voltage power can be reduced to direct-current low-voltage power required by the lamp controller, and the lamp controller provided by the embodiment can be suitable for different environments.

6. The lamp control system provided by the embodiment of the utility model comprises at least one lamp controller and also comprises a central control device, wherein the central control device is in signal connection with the control module through the LORA unit, and through the design, the central control device is utilized to manage the lighting lamp controllers and acquire the service conditions of all lighting lamps in the system.

7. The lamp system provided by the embodiment of the utility model further comprises a cloud end, wherein the signal transmission module further comprises an LT E4G unit in signal connection with the control module, and the cloud end is in signal connection with the LT E4G unit; through such design, the user of being convenient for carries out unified management to all lamps and lanterns controllers to and in time knows the state of current or history lamps and lanterns, and adjusts the illumination lamps and lanterns according to the state of current or history lamps and lanterns, compares in prior art, has retrieved the work load of control and adjustment by a wide margin.

8. The lamp control system at least comprises two lamp controllers, a moving object and a transmitting module arranged on the moving object, wherein at least two L O RA units are used for receiving signals on the transmitting module and transmitting the signals to the control module and/or the central control equipment.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the utility model, but any modifications, equivalents, improvements, etc. within the principles of the present utility model should be included in the scope of the present utility model.

Claims (10)

1. A lamp controller for controlling the switching and brightness of a lighting lamp, characterized by: the LED lighting device comprises a control module and a signal transmission module, wherein the control module is electrically connected with the lighting lamp to control the switch and the brightness of the lighting lamp, the signal transmission module comprises an L O RA unit, and the L O RA unit is in signal connection with the control module;

the control module is in signal connection with external equipment through the L O RA unit, and the L O RA unit is used for receiving external information and transmitting the external information to the control module.

2. The lamp controller of claim 1, further comprising an input module and an induction sensor in signal connection with the input module, wherein the input module is in signal connection with the control module, and when the induction sensor senses an external preset object, an induction signal is transmitted to the control module through the input module, and the control module controls the switch and the brightness of the lighting lamp.

3. The luminaire controller of claim 2, wherein the input module comprises a switching value signal detection unit and an analog value signal detection unit, at least one of the switching value signal detection unit and the analog value signal detection unit being in signal connection with an inductive sensor.

4. A luminaire controller as claimed in claim 3, characterized in that the inductive sensor comprises an illuminance sensor which is in signal connection with the control module via an input module.

5. A luminaire controller as claimed in claim 3, characterized in that the inductive sensor further comprises a microwave sensor, an infrared sensor, an AI camera identification sensor and/or a bluetooth identification sensor in signal connection with the input module.

6. The lamp controller of claim 1, further comprising a detection module, wherein the control module is in signal connection with the detection module, and the detection module is configured to detect on-off of a current or a voltage flowing through the lighting lamp and transmit a signal to the control module for determining an on-off state of the lighting lamp.

7. The luminaire controller of claim 1, further comprising a protection module comprising a buck unit, the buck unit having an input coupled to an external power source and an input coupled to the control module.

8. A luminaire control system comprising a luminaire controller as claimed in any one of claims 1-7, characterized in that it further comprises a central control device which is in signal connection with the control module via an L O RA unit.

9. The lighting fixture control system of claim 8, further comprising a cloud end, wherein the signal transmission module further comprises an L T E4G unit in signal connection with the control module, and wherein the cloud end is in signal connection with the L T E4G unit.

10. A positioning system comprising a luminaire control system as claimed in claim 8, said luminaire control system comprising at least two of said luminaire controllers, characterized in that it further comprises a moving object and a transmitting module arranged on the moving object, at least two of said L O RA units being arranged to receive signals on the transmitting module and to transmit the signals to the control module and/or to the central control device.