CN113825287A - Underwater lamp control system based on 5G technology - Google Patents

Abstract

The invention requests to protect an underwater lamp control system based on a 5G technology, which is characterized by comprising the following components: the detection device is used for acquiring the illumination condition of the underwater lamp control system, adopts a light source brightness sensor and an infrared detector and a 5G network, adopts NSA to carry out 5G networking, adopts the existing LTE as a 5G covering layer and adopts 5G NR as a capacity layer and adopts an NSA mode to carry out networking; the starting circuit is used for receiving the sensing signal of the detection device and providing a starting or stopping signal for the driving circuit; the signal transmitting unit, the signal receiving unit, the CPU and the LED light source are arranged; the CPU counts the results after the logic processing and sends corresponding data results to the LED control unit; after receiving the instruction of the CPU, the LED control unit controls whether the LED light source is turned off or not according to the instruction; the LED light source is used for underwater illumination.

Description

Underwater lamp control system based on 5G technology

Technical Field

The invention belongs to the technical field of light emitting diodes, and particularly relates to an underwater lamp control system based on a 5G technology.

Background

With the continuous progress of technology, light emitting diodes have been widely used for displays, television lighting, and illumination. The existing LED underwater lighting device is mostly electrically controlled, has insufficient underwater sensitivity, high initial cost, poor color rendering, low efficiency of a high-power LED and constant current driving. In an underwater environment, the problem of difficult communication exists when the LED communication is carried out, if real-time control and control signals are required to be obtained, a communication line needs to be adopted independently, so that higher equipment and maintenance cost is caused, but the change of light can be controlled remotely based on a 5G technology, the quick control of an underwater large-scale light combination scene is realized, and the underwater aesthetic feeling which is dazzled by people is realized. The data transmission can be carried out as long as a 5G network module is provided without setting up a network again. Therefore, 5G technology can be applied to underwater light systems.

Disclosure of Invention

The present invention is directed to solving the above problems of the prior art. An underwater lamp control system based on 5G technology is provided. The technical scheme of the invention is as follows:

an underwater light control system based on 5G technology, comprising:

the detection device is used for acquiring the illumination condition of the underwater lamp control system, adopts a light source brightness sensor and an infrared detector, is arranged near the underwater lamp and is used for detecting the illumination condition of the underwater lamp control system, the infrared detector is used for detecting whether other objects approach, and the detection device is connected with the starting circuit through a 5G network;

the method comprises the steps that a 5G network is adopted, NSA is adopted for 5G networking, existing LTE is used as a 5G covering layer, 5G NR is used as a capacity layer, NSA mode is adopted for networking, when a 5G wireless network address is selected, a 5G base station to be deployed is obtained through hot spot area statistics, a 5G stock station is obtained through analyzing communication service in a planned area, wireless network user conditions and service conditions in the 5G network area to be deployed are integrated to obtain a 5G network deployment suggestion value, 5G staged deployment is carried out according to the 5G network deployment suggestion value, and the geographic positions and the priorities of the base station to be deployed and the stock station are continuously adjusted and optimized in the deployment process;

the starting circuit is used for receiving the sensing signal of the detection device and providing a starting or stopping signal for the driving circuit;

the signal transmitting unit, the signal receiving unit, the CPU and the LED light source are arranged; the starting unit is a switch of the whole system, the starting unit can send a signal to start the whole system after the infrared sensor senses a corresponding signal, and meanwhile, the starting unit can transmit the signal sent by the infrared sensor to the signal receiving unit; the signal sending unit is used for sending out a signal sent by the starting circuit; the signal receiving unit is used for receiving the signal sent by the signal sending unit and converting the received signal into a data signal which can be processed by the CPU; the CPU carries out logic processing on the data signals of the signal receiving unit, namely, whether the LED illuminating lamp needs to be turned on or off is judged, and the CPU carries out statistics on the results after the logic processing and sends corresponding data results to the LED control unit; after receiving the instruction of the CPU, the LED control unit controls whether the LED light source is turned off or not according to the instruction; the LED light source is used for underwater illumination.

Further, the start-up circuit includes: the transistor comprises a PMOS tube M1, an NMOS tube M2 and an NMOS tube M3, wherein the source electrode of the PMOS tube M1 is connected with the drain electrode of the NMOS tube M3 and an external power supply VDD respectively, the drain electrode of the PMOS tube M1 is connected with the gate electrode of the NMOS tube M3 and the drain electrode of the NMOS tube M2 respectively, and the source electrode of the NMOS tube M2 is connected with an external ground GND.

Further, the calculating a 5G grid deployment recommendation value and the performing priority classification on the grid to be deployed specifically includes:

calculating the area of the 5G grid to be deployed and the stock station grid;

respectively calculating 5G flow density, SMS business density and grid income density in the 5G grids to be deployed according to the total wireless network flow, the total SMS business amount and the total grid income in the p grids to be deployed and the q grids of stock stations, and the area of the 5G grids to be deployed;

and adding the 5G flow density, the SMS business density and the grid income density in the 5G grid to be deployed to obtain the calculated 5G grid deployment suggestion value.

And sequencing the 5G grids to be deployed according to the 5G network deployment suggestion values from large to small to obtain a priority list.

Further, the CPU employs a PLC 300.

Further, the 5G network performs 5G networking by using NSA, and specifically includes:

the 4G base station (eNB) and the 5G base station (gNB) share a 5G core network (NGCN), the gNB is a master station, and the eNB is a slave station.

The invention has the following advantages and beneficial effects:

the invention applies the power line carrier communication to the intelligent system of the underwater lamp for the first time, realizes the real-time communication and control of the underwater lamp and does not need to generate extra erection cost. At present, in a power line broadband carrier communication system, only a communication route from a PCO/STA node to a CCO or from the CCO to the PCO/STA node can be provided, and the communication between the PCO/STA node and the PCO/STA node cannot be supported, so that the application capability of the power line broadband carrier communication system is limited. The invention provides a method for establishing and using a route from a PCO/STA to a PCO/STA node on the basis of the existing power line broadband carrier communication system.

Drawings

FIG. 1 is a block diagram of an underwater light system in which the present invention provides a preferred embodiment power carrier technology;

fig. 2 is a schematic diagram of a start-up circuit.

Detailed Description

The technical solutions in the embodiments of the present invention will be described in detail and clearly with reference to the accompanying drawings. The described embodiments are only some of the embodiments of the present invention.

The technical scheme for solving the technical problems is as follows:

as shown in fig. 1, an underwater light control system based on 5G technology includes:

the detection device is used for acquiring the illumination condition of the underwater lamp control system, adopts a light source brightness sensor and an infrared detector, is arranged near the underwater lamp and is used for detecting the illumination condition of the underwater lamp control system, the infrared detector is used for detecting whether other objects approach, and the detection device is connected with the starting circuit through a 5G network;

the method comprises the steps that a 5G network is adopted, NSA is adopted for 5G networking, existing LTE is used as a 5G covering layer, 5G NR is used as a capacity layer, NSA mode is adopted for networking, when a 5G wireless network address is selected, a 5G base station to be deployed is obtained through hot spot area statistics, a 5G stock station is obtained through analyzing communication service in a planned area, wireless network user conditions and service conditions in the 5G network area to be deployed are integrated to obtain a 5G network deployment suggestion value, 5G staged deployment is carried out according to the 5G network deployment suggestion value, and the geographic positions and the priorities of the base station to be deployed and the stock station are continuously adjusted and optimized in the deployment process;

the starting circuit is used for receiving the sensing signal of the detection device and providing a starting or stopping signal for the driving circuit;

the signal transmitting unit, the signal receiving unit, the CPU and the LED light source are arranged; the starting unit is a switch of the whole system, the starting unit can send a signal to start the whole system after the infrared sensor senses a corresponding signal, and meanwhile, the starting unit can transmit the signal sent by the infrared sensor to the signal receiving unit; the signal sending unit is used for sending out a signal sent by the starting circuit; the signal receiving unit is used for receiving the signal sent by the signal sending unit and converting the received signal into a data signal which can be processed by the CPU; the CPU carries out logic processing on the data signals of the signal receiving unit, namely, whether the LED illuminating lamp needs to be turned on or off is judged, and the CPU carries out statistics on the results after the logic processing and sends corresponding data results to the LED control unit; after receiving the instruction of the CPU, the LED control unit controls whether the LED light source is turned off or not according to the instruction; the LED light source is used for underwater illumination.

Further, the start-up circuit includes: the transistor comprises a PMOS tube M1, an NMOS tube M2 and an NMOS tube M3, wherein the source electrode of the PMOS tube M1 is connected with the drain electrode of the NMOS tube M3 and an external power supply VDD respectively, the drain electrode of the PMOS tube M1 is connected with the gate electrode of the NMOS tube M3 and the drain electrode of the NMOS tube M2 respectively, and the source electrode of the NMOS tube M2 is connected with an external ground GND.

Further, the calculating a 5G grid deployment recommendation value and the performing priority classification on the grid to be deployed specifically includes:

calculating the area of the 5G grid to be deployed and the stock station grid;

respectively calculating 5G flow density, SMS business density and grid income density in the 5G grids to be deployed according to the total wireless network flow, the total SMS business amount and the total grid income in the p grids to be deployed and the q grids of stock stations, and the area of the 5G grids to be deployed;

and adding the 5G flow density, the SMS business density and the grid income density in the 5G grid to be deployed to obtain the calculated 5G grid deployment suggestion value.

And sequencing the 5G grids to be deployed according to the 5G network deployment suggestion values from large to small to obtain a priority list.

Further, the CPU employs a PLC 300.

Further, the 5G network performs 5G networking by using NSA, and specifically includes:

the 4G base station (eNB) and the 5G base station (gNB) share a 5G core network (NGCN), the gNB is a master station, and the eNB is a slave station.

The above embodiments illustrate that, in addition to the start-up circuit, the drive circuit may be used to control the start-up and the stop of the LED light source, and the drive circuit includes: the device comprises a medium-temperature region negative feedback compensation circuit, a first-order band gap reference circuit and a high-temperature region negative feedback compensation circuit, wherein the signal output end of the first-order band gap reference circuit is respectively connected with the signal input ends of the starting circuit, the medium-temperature region negative feedback compensation circuit and the high-temperature region negative feedback compensation circuit; the first-order band gap reference circuit generates a first-order band gap reference voltage, and the medium-temperature region negative feedback compensation circuit and the high-temperature region negative feedback compensation circuit are respectively connected with the first-order band gap reference circuitA negative feedback loop is formed with the first-order band gap reference circuit, and the current of a PMOS tube M11 of the medium-temperature region negative feedback compensation circuit generates a voltage V on a resistor R5 and a resistor R6_NL1And the current of the PMOS tube M16 of the high-temperature region negative feedback compensation circuit generates a voltage V on a resistor R6_NL2Voltage V of_NL1And voltage V_NL2And respectively compensating the first-order band-gap reference voltage generated by the first-order band-gap reference circuit, wherein the starting circuit provides a starting signal for the first-order band-gap reference circuit.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The above examples are to be construed as merely illustrative and not limitative of the remainder of the disclosure. After reading the description of the invention, the skilled person can make various changes or modifications to the invention, and these equivalent changes and modifications also fall into the scope of the invention defined by the claims.

Claims (5)

1. An underwater lamp control system based on 5G technology is characterized by comprising:

the detection device is used for acquiring the illumination condition of the underwater lamp control system, adopts a light source brightness sensor and an infrared detector, is arranged near the underwater lamp and is used for detecting the illumination condition of the underwater lamp control system, the infrared detector is used for detecting whether other objects approach, and the detection device is connected with the starting circuit through a 5G network;

the method comprises the steps that a 5G network is adopted, NSA is adopted for 5G networking, existing LTE is used as a 5G covering layer, 5G NR is used as a capacity layer, NSA mode is adopted for networking, when a 5G wireless network address is selected, a 5G base station to be deployed is obtained through hot spot area statistics, a 5G stock station is obtained through analyzing communication service in a planned area, wireless network user conditions and service conditions in the 5G network area to be deployed are integrated to obtain a 5G network deployment suggestion value, 5G staged deployment is carried out according to the 5G network deployment suggestion value, and the geographic positions and the priorities of the base station to be deployed and the stock station are continuously adjusted and optimized in the deployment process;

the starting circuit is used for receiving the sensing signal of the detection device and providing a starting or stopping signal for the driving circuit;

the signal transmitting unit, the signal receiving unit, the CPU and the LED light source are arranged; the starting unit is a switch of the whole system, the starting unit can send a signal to start the whole system after the infrared sensor senses a corresponding signal, and meanwhile, the starting unit can transmit the signal sent by the infrared sensor to the signal receiving unit; the signal sending unit is used for sending out a signal sent by the starting circuit; the signal receiving unit is used for receiving the signal sent by the signal sending unit and converting the received signal into a data signal which can be processed by the CPU; the CPU carries out logic processing on the data signals of the signal receiving unit, namely, whether the LED illuminating lamp needs to be turned on or off is judged, and the CPU carries out statistics on the results after the logic processing and sends corresponding data results to the LED control unit; after receiving the instruction of the CPU, the LED control unit controls whether the LED light source is turned off or not according to the instruction; the LED light source is used for underwater illumination.

2. An underwater light control system based on 5G technology as claimed in claim 1, wherein the starting circuit comprises: the transistor comprises a PMOS tube M1, an NMOS tube M2 and an NMOS tube M3, wherein the source electrode of the PMOS tube M1 is connected with the drain electrode of the NMOS tube M3 and an external power supply VDD respectively, the drain electrode of the PMOS tube M1 is connected with the gate electrode of the NMOS tube M3 and the drain electrode of the NMOS tube M2 respectively, and the source electrode of the NMOS tube M2 is connected with an external ground GND.

3. The underwater lamp control system based on the 5G technology as claimed in claim 1, wherein the calculating of the 5G grid deployment recommendation value specifically includes:

calculating the area of the 5G grid to be deployed and the stock station grid;

respectively calculating 5G flow density, SMS business density and grid income density in the 5G grids to be deployed according to the total wireless network flow, the total SMS business amount and the total grid income in the p grids to be deployed and the q grids of stock stations, and the area of the 5G grids to be deployed;

adding the 5G flow density, the SMS service density and the grid income density in the 5G grid to be deployed to obtain the calculated 5G grid deployment suggestion value,

and sequencing the 5G grids to be deployed according to the 5G network deployment suggestion values from large to small to obtain a priority list.

4. The underwater lamp control system based on 5G technology as claimed in claim 1, wherein the CPU employs a PLC 300.

5. The underwater lamp control system based on 5G technology according to claim 1, wherein the 5G network performs 5G networking by using NSA, specifically comprising:

the 4G base station (eNB) and the 5G base station (gNB) share a 5G core network (NGCN), the gNB is a master station, and the eNB is a slave station.

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