CN116782462B - Atmosphere light control system and control method based on fountain injection height - Google Patents

Abstract

The invention discloses an atmosphere light control system and method based on fountain injection height, and belongs to the technical field of light control. The problem that the irradiation scheme of the existing atmosphere lamp cannot be adjusted in real time according to the spraying scheme of the fountain is solved. The control method comprises the following steps: acquiring a spraying scheme of a fountain, and determining each height node and a time axis according to the spraying scheme; according to the time axis and each height node; establishing a light library according to each height node, wherein each height node is bound with a light library; acquiring a lamplight database; determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and the lamplight actions; an illumination scheme is determined and executed based on each light library and the time axis. The control system comprises a server and a processing module, wherein the server is in signal connection with the processing module. The invention realizes the irradiation scheme of randomly producing atmosphere lamp light according to the jet height of the fountain in real time, and effectively improves the working efficiency.

Description

Atmosphere light control system and control method based on fountain injection height

Technical Field

The invention relates to the technical field of light control, in particular to an atmosphere light control system and method based on fountain injection height.

Background

The light fountain is a combination body which sprays water or other liquid into a specific shape through a spray head by a certain pressure, and is a general water pump for providing water pressure, and after years of development, the light fountain has been developed into several major categories: a music fountain; program control fountain; music + program control fountain; a laser water curtain film; fun fountain, etc. with specific lighting and control system, the utility model has the functions of purifying air and beautifying environment. The existing lamplight fountain is generally designed by directly carrying out fancy fountain through program control and the irradiation scheme of atmosphere lamplight according to fancy fountain design, but the fancy fountain and the atmosphere lamplight are designed in advance, if the fancy fountain needs to be replaced, the control scheme is more suitable for some large lamplight shows, errors can be reduced, and later-stage reproduction is facilitated. However, for some fountain landscapes (such as a fountain of a market or a fountain of a hotel) which are fixed relative to some fountain landscapes, a long-term fixed light matching scheme can lead to a stiff atmosphere lamp irradiation scheme, and the irradiation scheme of the atmosphere lamp cannot be adjusted according to the spraying scheme of the fountain in real time.

Disclosure of Invention

The invention mainly aims to provide an atmosphere light control system and an atmosphere light control method based on fountain spraying height, and aims to solve the problem that an irradiation scheme of an existing atmosphere lamp cannot be adjusted in real time according to a spraying scheme of a fountain.

In order to achieve the above object, the invention provides an atmosphere light control method based on fountain spraying height, which is characterized by comprising the following steps:

acquiring a spraying scheme of a fountain, and determining each height node and a time axis according to the spraying scheme;

determining the maintenance time of each height node according to the time axis and each height node;

establishing a lamplight library according to each height node, wherein each height node is bound with one lamplight library; the lamp light libraries and the height node libraries are equal in number;

acquiring a lamplight database, and acquiring each lamplight action according to the lamplight database;

determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and each lamplight action;

and determining and executing an illumination scheme according to each lamplight library and the time axis.

Preferably, after the step of determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and each lamplight action, the method includes:

acquiring current time and judging whether the current time is in a holiday or not;

when the current time is in a festival, adjusting the light color of each light action to be a first color; determining and executing an illumination scheme according to each of the light banks and the time axis adjusted to the first color;

and when the current time is not in the holiday, executing the step of determining and executing the illumination scheme according to each lamplight library and the time axis.

Preferably, when the current time is not in a holiday, the step of determining and executing an illumination scheme according to each light library and the time axis is executed, including:

when the current time is not in a holiday, acquiring a current day temperature interval, and judging whether the current time is in summer or not according to the current day temperature interval and the current time;

when the current time is in summer, adjusting the light color of each light action to be a second color; and said determining and executing said illumination scheme based on each of said light banks and said time axis adjusted to said second color;

and when the current time is not in summer, executing the step of determining and executing an illumination scheme according to each lamplight library and the time axis.

Preferably, after the step of determining the irradiation scheme according to each light bank and the time axis, the method includes:

establishing an excellent project library, acquiring the flow of people in a preset area through a camera, and judging whether the flow of people is larger than the number of preset people;

when the people flow is larger than the preset number of people, storing the irradiation scheme into the excellent project library and marking the irradiation scheme as an excellent scheme;

when the people flow is smaller than the preset number of people, acquiring the execution time of the irradiation scheme being executed, and judging whether the execution time is larger than the preset number of times;

when the execution time is greater than or equal to the preset times, selecting one of the excellent schemes through the excellent item library, and executing the excellent scheme;

and when the execution time is smaller than the preset times, continuing to execute the irradiation scheme.

Preferably, when the traffic of people is smaller than the preset number of people, acquiring execution time of the irradiation scheme being executed, and judging whether the execution time is larger than a preset number of times, including:

when the people flow is smaller than the preset number of people, acquiring real-time, and judging whether the current people flow is normal or not according to the real-time and the people flow;

when the traffic is unreasonable, acquiring the execution time of the irradiation scheme being executed, and judging whether the execution time is greater than a preset number of times;

and when the flow of people is reasonable, continuing to execute the irradiation scheme.

Preferably, after the step of determining and executing the irradiation scheme according to each light library and the time axis, the method includes:

obtaining a standard scheme;

judging whether the real-time is on a weekday or at night according to the real-time;

when the real-time is on the white day, acquiring the light intensity, and adjusting the brightness of the standard scheme according to the light intensity so that the brightness of the standard scheme is larger than the light intensity;

when the real-time is at night, the brightness of the standard scheme is adjusted according to the preset brightness, so that the brightness of the standard scheme is larger than the preset brightness.

Preferably, when the real-time is at night, adjusting the brightness of the standard solution according to the preset brightness so that the brightness of the standard solution is greater than the preset brightness, including:

when the real-time is at night, acquiring the brightness of the lamp in the preset area through the camera; determining the preset brightness according to the light brightness; and adjusting the brightness of the standard scheme according to the preset brightness so that the brightness of the standard scheme is larger than the preset brightness.

In addition, in order to achieve the above purpose, the invention also provides an atmosphere light control system based on fountain spraying height, the control system is applied to execute the atmosphere light control method based on fountain spraying height, the control system comprises a server and a processing module, and the server is in signal connection with the processing module:

the server is used for acquiring a spraying scheme of the fountain and determining each height node and a time axis according to the spraying scheme; acquiring a lamplight database, and acquiring each lamplight action according to the lamplight database;

the processing module is used for determining the maintenance time of each height node according to the time axis and each height node; establishing a lamplight library according to each height node, wherein each height node is bound with one lamplight library; the lamp light libraries and the height node libraries are equal in number; determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and each lamplight action; and determining and executing an illumination scheme according to each lamplight library and the time axis.

Determining a height node and a time axis by determining an injection scheme, and determining the maintenance time of the injection height of the fountain; and each height node randomly records a corresponding number of lamplight actions according to the maintenance time, and finally produces and executes an irradiation scheme for the lamplight according to each lamplight library and the time axis, so that the irradiation scheme for producing atmosphere lamplight according to the jet height of the fountain in real time is realized, a user only needs to adjust the jet scheme, the irradiation scheme is directly adjusted, and the working efficiency is effectively improved.

Drawings

FIG. 1 is a schematic flow chart of an atmosphere light control method based on fountain spraying height;

fig. 2 is a schematic diagram of functional modules of an atmosphere light control method based on fountain spraying height.

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

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 invention.

In the following description, suffixes such as "module", "component", or "unit" for representing elements are used only for facilitating the description of the present invention, and have no specific meaning per se. Thus, "module," "component," or "unit" may be used in combination.

Referring to fig. 1, in order to achieve the above object, a first embodiment of the present invention provides an atmosphere light control method based on fountain spraying height, including:

step S10, acquiring a spraying scheme of a fountain, and determining each height node and a time axis according to the spraying scheme;

step S20, determining the maintenance time of each height node according to the time axis and each height node;

step S30, building a light library according to each height node, wherein each height node is bound with a light library; the number of the lamplight libraries is equal to the number of the height node libraries;

step S40, a lamplight database is obtained, and lamplight actions are obtained according to the lamplight database;

step S50, determining the number of lamplight actions in each lamplight library according to the lamplight library, the maintenance time and each lamplight action;

step S60, determining and executing an illumination scheme according to each lamplight library and the time axis.

Specifically, the height nodes are the fountain spraying height and the spraying time of the height, and in the spraying scheme, the sequence along the time axis has the number of height changes and the number of height nodes.

Specifically, the lamplight actions in the lamplight database are randomly extracted from the lamplight database.

Determining a height node and a time axis by determining an injection scheme, and determining the maintenance time of the injection height of the fountain; and each height node randomly records a corresponding number of lamplight actions according to the maintenance time, and finally produces and executes an irradiation scheme for the lamplight according to each lamplight library and the time axis, so that the irradiation scheme for producing atmosphere lamplight according to the jet height of the fountain in real time is realized, a user only needs to adjust the jet scheme, the irradiation scheme is directly adjusted, and the working efficiency is effectively improved.

By using a PLC (programmable logic controller) as a core controller, nodes with different heights and time axes, and corresponding lamplight libraries and lamplight actions are determined according to the spraying scheme of the fountain, so that the lamplight effect which changes according to the height change of the fountain water column is realized.

The PLC is a microcomputer special for industrial control, and has various control functions, data acquisition, storage and processing functions, communication networking functions, input/output interface conditioning functions, human-computer interface functions and programming debugging functions. The PLC consists of a microprocessor (CPU), memory (EPROM, ROM), input output (I/O) components, power components, programmers, I/O expansion units, and other peripheral devices. The parts are connected by buses (power bus, control bus, address bus, data bus). The software system of the PLC refers to a collection of various programs used by the PLC, and can be generally divided into two major parts, i.e., a system program and a user program. The system program is a part which each PLC finished product must include, and is provided by a PLC manufacturer and used for controlling the running of the PLC, and the system program is solidified in the EPROM. The user program is a program written by a user according to control needs. The control program programmed by the user expresses the technological requirement of the production process and is stored in the user program memory of the PLC in advance. The operation is carried out piece by piece according to the content of the stored program so as to finish the operation required by the process flow. PLCs support a variety of programming languages, with Ladder Diagrams (LDs) and instruction tables (ILs) being the most common. The ladder diagram programming language is evolved from the schematic diagram of the relay control system. The basic ideas of the ladder diagram of the PLC are identical with those of the relay control system, and only a certain difference is made in terms of the use symbols and the expression modes. The instruction sheet programming language is similar to the mnemonic assembly language in a computer, which is the most basic programming language for programmable controllers. The atmosphere light control method based on fountain spraying height is realized by the following software: ladder or instruction sheet programming was performed using Siemens S7-200 series PLC as the core controller, and Siemens STEP 7 Micro/WIN software. The software can be edited, debugged and simulated on a PC, and is communicated with and downloaded from a PLC through an RS232 or RS485 interface. The software may also monitor and modify data or status values in data registers or flag registers in memory in the PLC.

Specifically, after step S50, the method includes:

step S51, judging whether the number of lamplight actions in the lamplight library is greater than two;

step S52, when the number of the lamplight actions in the lamplight library is greater than or equal to two, adjusting the lamplight actions in the lamplight library to the same hue;

and step S53, when the number of the lamplight actions in the lamplight library is smaller than two, the hue of each lamplight action in the lamplight library is kept unchanged.

The hue in the height node with longer maintenance time is consistent, and the saturation and the brightness are random, so that a large number of light sources with different hues can be avoided in the same height, and the light action which is frequently changed is prevented from being changed into light pollution.

Specifically, step S52, after that, includes:

step S53, obtaining hue data of the lamplight actions in each lamplight library, marking two lamplight libraries with the same hue as a special point along a time axis, and judging whether the hue of each lamplight action in the special point is consistent with the hue of each lamplight action in the two lamplight libraries along the time axis;

step S54, when the hue of each lamplight action in the special point is consistent with the hue of each lamplight action in the two adjacent lamplight libraries, modifying the hue of each lamplight action in the two adjacent lamplight libraries;

and step S55, when the hue of each lamplight action in the special point is not consistent with the hue of each lamplight action in the two adjacent lamplight libraries, maintaining the hue of each lamplight action in the two adjacent lamplight libraries.

The color phases of the adjacent light libraries of the special points are modified, so that the color phases of the special points and the adjacent two light libraries are inconsistent, the consistent light color phases in a long time are avoided, and the color of a light scheme is enriched.

Specifically, the number of actions of each lamplight library in the special point is greater than or equal to two.

In a second embodiment of the fountain jet height-based atmosphere light control method according to the present invention, based on the first embodiment, after step S50, the method includes:

step S70, acquiring current time and judging whether the current time is in a holiday or not;

step S71, when the current time is in a festival, the lamplight color of each lamplight action is adjusted to be a first color; determining and executing an illumination scheme according to each lamplight library and the time axis which are adjusted to the first color;

step S72, when the current time is not in the holiday, the step of determining and executing the illumination scheme according to each lamplight library and the time axis is executed.

Specifically, the first color includes at least one of red, yellow and violet, and the first color is a holiday use color that meets Chinese aesthetic requirements.

Specifically, the current time includes year, month and day.

And adjusting the light color according to the national holiday so that the color of the whole atmosphere lamp is more in line with the holiday atmosphere.

In a third embodiment of the fountain jet height-based atmosphere light control method according to the present invention, based on the second embodiment, step S71 includes:

step S73, when the current time is not in the festival, acquiring a current day temperature interval, and judging whether the current time is in summer according to the current day temperature interval and the current time;

step S74, when the current time is in summer, the lamplight color of each lamplight action is adjusted to be a second color; determining and executing an illumination scheme according to each lamplight library and the time axis which are adjusted to the second color;

step S75, when the current time is not in summer, the step of determining and executing the illumination scheme according to each lamplight library and the time axis is executed.

Specifically, the second color is at least one of cyan, blue, and violet, and the second color is a cool tone.

When the current time is not in holidays, the summer and other seasons are distinguished according to the temperature, the cold tone is displayed in summer, and the influence of the over-warm tone on the moods of nearby people is avoided.

In a fourth embodiment of the fountain jet height-based atmosphere light control method according to the present invention, after step S60, the method includes:

step S61, an excellent project library is established, the flow of people in a preset area is obtained through a camera, and whether the flow of people is larger than the number of preset people is judged;

step S62, when the people flow is larger than the preset number of people, storing the irradiation scheme into an excellent project library and marking the irradiation scheme as an excellent scheme;

step S63, when the people flow is smaller than the preset number of people, acquiring the execution time of the executing irradiation scheme, and judging whether the execution time is larger than the preset number of times;

step S64, when the execution time is greater than or equal to the preset times, selecting one of the excellent schemes through the excellent item library, and executing the excellent scheme;

step S65, when the execution time is less than the preset times, continuing to execute the irradiation scheme.

The irradiation scheme is selected according to the traffic volume, so that the overall ornamental value is improved.

Specifically, step S64 includes:

step S66, when the execution time is greater than or equal to the preset times, the number of each excellent scheme is obtained through the excellent project library, and whether the number of the excellent schemes is greater than the preset number is judged;

step S67, when the number of the excellent schemes is greater than or equal to the preset number, the storage times of each excellent scheme are obtained, and whether the storage times of the excellent schemes are greater than the preset times is judged;

step S68, when the storage times of the excellent schemes are larger than or equal to the preset times, marking the excellent schemes as first schemes, selecting one of the first schemes, and executing the first scheme;

step S69, when the storage times of the excellent scheme is smaller than the preset times, marking the excellent scheme as a second scheme;

in step S610, when the number of the excellent schemes is smaller than the preset number, one of the second schemes is selected through the excellent item library, and the second scheme is executed.

The popularity of the irradiation scheme is judged according to the input times of the irradiation scheme, and the irradiation scheme with high environmental degree is played under the general condition of the traffic, so that the attraction to the traffic is effectively improved.

Specifically, after step S610, the method includes:

step S611, obtaining the warehousing time of each first scheme, and judging whether the warehousing time of the first scheme exceeds a preset time period according to the warehousing time;

step S612, when the warehouse-in time of the first scheme is greater than or equal to the preset time period, resetting the storage times of the first scheme, and modifying the first scheme into the second scheme;

in step S613, when the warehouse-in time of the first scheme is less than the preset time period, the number of times of storing the first scheme is kept unchanged.

The stored times of the first scheme are cleaned through a preset time period, and repeated playing of the same irradiation scheme for a plurality of times and a long time is avoided.

In a fifth embodiment of the fountain jet height-based atmosphere light control method according to the present invention, based on the fourth embodiment, step S63 includes:

step S614, when the people flow is smaller than the preset number of people, acquiring real-time, and judging whether the current people flow is normal or not according to the real-time and the people flow;

step S615, when the flow of people is unreasonable, acquiring the execution time of the irradiation scheme being executed, and judging whether the execution time is greater than the preset times;

step S615, when the traffic is reasonable, continuing to execute the irradiation scheme.

Whether the current people flow is reasonable is judged according to the real-time, so that the phenomenon of excessive use in unmanned time periods such as late night is avoided, and the energy loss is reduced.

Specifically, the real-time includes time, minutes, and seconds.

In a sixth embodiment of the fountain jet height-based atmosphere light control method according to the present invention, based on the fifth embodiment, after step S60, the method includes:

step S80, obtaining a standard scheme;

step S81, judging that the real-time is located on the day or at night according to the real-time;

step S82, when the real-time is on the white day, acquiring the light intensity, and adjusting the brightness of the standard scheme according to the light intensity so that the brightness of the standard scheme is larger than the light intensity;

step S83, when the real-time is at night, the brightness of the standard scheme is adjusted according to the preset brightness so that the brightness of the standard scheme is larger than the preset brightness.

The standard scheme is a lighting scheme welcome by important clients, and the importance of the clients is highlighted by adjusting the brightness.

In the seventh embodiment of the fountain jet height-based atmosphere light control method according to the present invention, based on the sixth embodiment, step S83 includes:

when the real-time is at night, acquiring the brightness of the lamp in the preset area through the camera; determining preset brightness according to the brightness of the lamplight; and adjusting the brightness of the standard scheme according to the preset brightness so that the brightness of the standard scheme is larger than the preset brightness.

Example 1:

# import correlation module

import numpy as np

import matplotlib.pyplot as plt

import random

# definition fountain spray scheme

Assume that the fountain has 10 groups of spray heads, each group of spray heads can spray water columns with different heights

Let # assume that the fountain can change the spray height once per second

Assume a fountain spray scheme for 10 seconds

The fountain spray scheme is represented by a 10x10 matrix, each row representing one second, each column representing a spray head, and each element representing a spray height (in meters)

spray_plan = np.array([[5, 3, 4, 6, 7, 8, 9, 10, 2, 1],

[4, 5, 6, 7, 8, 9, 10, 2, 1, 3],

[3, 4, 5, 6, 7, 8, 9, 1, 2, 4],

[2, 3, 4, 5, 6, 7, 8, 2, 3, 5],

[1, 2, 3, 4, 5, 6, 7, 3, 4, 6],

[2, 1, 2, 3, 4, 5, 6 ,4 ,5 ,7],

[3 ,2 ,1 ,2 ,3 ,4 ,5 ,5 ,6 ,8],

[4 ,3 ,2 ,1 ,2 ,3 ,4 ,6 ,7 ,9],

[5 ,4 ,3 ,2 ,1 ,2 ,3 ,7 ,8 ,10],

[6 ,5 ,4 ,3 ,2 ,1 ,2 ,8 ,9 ,10]])

# determination of each altitude node and time axis according to injection scheme

Let # assume that the height node is the maximum of the fountain jet height, i.e. the largest element of each row

Let # assume the time axis as the duration of the fountain spray scheme, i.e. the number of rows of the matrix

height_nodes=np.max (array_plan, axis=1) # gives a one-dimensional array of length 10, representing the maximum spray height per second

time_axis=len (spray_plan) # gives an integer representing the duration of the fountain spray scheme

Establishing a lamplight library according to each height node, wherein each height node is bound with a lamplight library

Assume that the lamplight library is a dictionary, the key is a height node, the value is a list, and lamplight actions corresponding to the height node are stored in the list

Let # assume that the light action is a tuple comprising three elements: hue, brightness and flicker frequency of light

# assume that the hue of the light is a string of characters, e.g. "red", "green", "blue", etc

# assume that the luminance is an integer between 0 and 100, representing a percentage

# suppose that the flicker frequency is an integer between 0 and 10, representing the number of flicker per second

light_library= { } # creates an empty dictionary

for node in height _nodes: # traverse each height node

light_library [ node ] = [ ] # creates an empty list for each height node

According to the lamplight libraries, the maintenance time and the lamplight actions, determining the number of lamplight actions in each lamplight library

Let # assume the sustain time is the number of seconds per altitude node, i.e., X seconds

# assume that the number of light events is proportional to the sustain time, i.e. there is one light event per second

# assume that the light actions are randomly extracted from a light database, which is a list in which all possible light actions are stored

light_database= [ ("red", 100, 0), ("green", 100, 0), ("blue", 100, 0), # static hue

("red", 50, 0), ("green", 50, 0), ("blue", 50, 0), # dim hue

("Red", 100, 5), ("Green", 100, 5), ("blue", 100, 5), # high frequency flicker

("red", 50, 5), ("green", 50, 5), ("blue", 50, 5), # low-light flicker

("Red", 100, 1), ("Green", 100, 1), ("blue", 100, 1), # blinks slowly

("red", 50, 1), ("green", 50, 1), ("blue", 50, 1) ] # dim and flash slowly

for node in height _nodes: # traverse each height node

main_time=x# maintenance time of X seconds

The number of light_action_number=main_time# light actions is equal to the sustain time

for i in range (light_action_number): # number of traversal per light action

light_action=random. Choice (light_database) # randomly extracts a light action from a light database

light_library [ node ]. Application #, adds light actions to the corresponding light library.

Referring to fig. 2, the fountain spray height-based atmosphere light control system is applied to execute any of the fountain spray height-based atmosphere light control methods, and the control system comprises a server and a processing module, wherein the server is in signal connection with the processing module:

the server is used for acquiring the spraying scheme of the fountain and determining each height node and a time axis according to the spraying scheme; acquiring a lamplight database, and acquiring each lamplight action according to the lamplight database;

the processing module is used for determining the maintenance time of each height node according to the time axis and each height node; establishing a light library according to each height node, wherein each height node is bound with a light library; the number of the lamplight libraries is equal to the number of the height node libraries; determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and the lamplight actions; an illumination scheme is determined and executed based on each light library and the time axis.

From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present invention may be embodied essentially or in part in the form of a software product stored in a computer readable storage medium (e.g. ROM/RAM, magnetic disk, optical disk) as described above, comprising instructions for causing a terminal device to enter the method according to the embodiments of the present invention.

In the description of the present specification, descriptions of terms "one embodiment," "another embodiment," "other embodiments," or "first embodiment through X-th embodiment," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, method steps or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or system 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 system. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or system that comprises the element.

The foregoing embodiment numbers of the present invention are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (8)

1. The atmosphere light control method based on the fountain spraying height is characterized by comprising the following steps of:

acquiring a spraying scheme of a fountain, and determining each height node and a time axis according to the spraying scheme; the height nodes are fountain spraying height and spraying time of the height, and in the spraying scheme, the number of height changes and the number of height nodes are in sequence along a time axis; each height node randomly records a corresponding number of lamplight actions according to the maintenance time;

determining the maintenance time of each height node according to the time axis and each height node;

establishing a lamplight library according to each height node, wherein each height node is bound with one lamplight library; the lamp light libraries and the height node libraries are equal in number;

acquiring a lamplight database, and acquiring each lamplight action according to the lamplight database; the lamplight actions in the lamplight database are randomly extracted from the lamplight database;

determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and each lamplight action; the lamplight library is a dictionary, keys are height nodes, the values are a list, and lamplight actions corresponding to the height nodes are stored in the list; the lamplight database is a list, and all possible lamplight actions are stored in the list;

and determining and executing an illumination scheme according to each lamplight library and the time axis.

2. The fountain jet height-based atmosphere light control method according to claim 1, wherein after the step of determining the number of light actions in each light bank according to the light bank, the maintenance time, and each light action, it comprises:

acquiring current time and judging whether the current time is in a holiday or not;

when the current time is in a festival, adjusting the light color of each light action to be a first color; determining and executing an illumination scheme according to each of the light banks and the time axis adjusted to the first color;

and when the current time is not in the holiday, executing the step of determining and executing the illumination scheme according to each lamplight library and the time axis.

3. The fountain spray height-based atmosphere light control method according to claim 2, wherein the step of determining and executing an illumination scheme according to each light bank and the time axis is performed when the current time is not in a holiday, comprising:

when the current time is not in a holiday, acquiring a current day temperature interval, and judging whether the current time is in summer or not according to the current day temperature interval and the current time;

when the current time is in summer, adjusting the light color of each light action to be a second color; and said determining and executing said illumination scheme based on each of said light banks and said time axis adjusted to said second color;

and when the current time is not in summer, executing the step of determining and executing an illumination scheme according to each lamplight library and the time axis.

4. A fountain spray height based atmosphere light control method according to any one of claims 1-3, wherein after the step of determining an illumination scheme from each light bank and the time axis, it comprises:

establishing an excellent project library, acquiring the flow of people in a preset area through a camera, and judging whether the flow of people is larger than the number of preset people;

when the people flow is larger than the preset number of people, storing the irradiation scheme into the excellent project library and marking the irradiation scheme as an excellent scheme;

when the people flow is smaller than the preset number of people, acquiring the execution time of the irradiation scheme being executed, and judging whether the execution time is larger than the preset number of times;

when the execution time is greater than or equal to the preset times, selecting one of the excellent schemes through the excellent item library, and executing the excellent scheme;

and when the execution time is smaller than the preset times, continuing to execute the irradiation scheme.

5. The fountain jet height-based atmosphere light control method according to claim 4, wherein when the traffic of people is smaller than the preset number of people, the step of acquiring execution time of the irradiation scheme being executed and judging whether the execution time is larger than a preset number of times, comprises:

when the people flow is smaller than the preset number of people, acquiring real-time, and judging whether the current people flow is normal or not according to the real-time and the people flow;

when the traffic is unreasonable, acquiring the execution time of the irradiation scheme being executed, and judging whether the execution time is greater than a preset number of times;

and when the flow of people is reasonable, continuing to execute the irradiation scheme.

6. The fountain spray height based atmosphere light control method according to claim 5, wherein after the step of determining and executing the irradiation scheme according to each light bank and the time axis, it comprises:

obtaining a standard scheme;

judging whether the real-time is on a weekday or at night according to the real-time;

when the real-time is on the white day, acquiring the light intensity, and adjusting the brightness of the standard scheme according to the light intensity so that the brightness of the standard scheme is larger than the light intensity;

when the real-time is at night, the brightness of the standard scheme is adjusted according to the preset brightness, so that the brightness of the standard scheme is larger than the preset brightness.

7. The fountain jet height-based atmosphere light control method of claim 6, wherein adjusting the brightness of the standard solution according to the preset brightness so that the brightness of the standard solution is greater than the preset brightness when the real-time is at night comprises:

when the real-time is at night, acquiring the brightness of the lamp in the preset area through the camera; determining the preset brightness according to the light brightness; and adjusting the brightness of the standard scheme according to the preset brightness so that the brightness of the standard scheme is larger than the preset brightness.

8. The fountain jet height-based atmosphere light control system is characterized in that the control system is applied to executing the fountain jet height-based atmosphere light control method according to any one of claims 1-7, and comprises a server and a processing module, wherein the server is in signal connection with the processing module:

the server is used for acquiring a spraying scheme of the fountain and determining each height node and a time axis according to the spraying scheme; acquiring a lamplight database, and acquiring each lamplight action according to the lamplight database;

the processing module is used for determining the maintenance time of each height node according to the time axis and each height node; establishing a lamplight library according to each height node, wherein each height node is bound with one lamplight library; the lamp light libraries and the height node libraries are equal in number; determining the number of the lamplight actions in each lamplight library according to the lamplight library, the maintenance time and each lamplight action; and determining and executing an illumination scheme according to each lamplight library and the time axis.