A multi-angle light-emitting and angle-selectable light-emitting lamp

By designing a light partition plate and a microcontroller to coordinate the light source developing head on the lamp, the problem of existing lamps being unable to adjust the light emission angle is solved, achieving flexible lighting control and reducing light waste and pollution.

CN122236992APending Publication Date: 2026-06-19韩厚华

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
韩厚华
Filing Date
2026-04-10
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing lighting fixtures cannot adjust the beam angle and intensity according to needs, resulting in unnecessary waste and pollution of light.

Method used

Design a multi-angle light-emitting lamp with selectable light-emitting angle. The lampshade is divided into multiple grid recessed areas by light-emitting partitions on the lampshade. Each area is equipped with a light source or laser developing head. A microcontroller and a wireless remote control terminal are used to coordinate the opening, closing and light-emitting angle of the light source and developing head.

Benefits of technology

It enables the adjustment of the light-emitting angle and intensity of the lamps according to needs, reducing light waste and avoiding unnecessary light pollution.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention provides a multi-angle light-emitting lamp with selectable emission angles. The lampshade is divided into multiple grid-like recessed areas or grid-like recessed area segments by light-emitting partitions. These areas are overlapped in one or more layers, forming multiple layers. The number and size of each overlapping grid-like recessed area or grid-like recessed area segment may be the same or different. A light source or laser developing head is provided within or outside each recessed area. Multiple grid-like recessed areas of different shapes can be combined to form various shapes, or the light source or laser developing head can emit light within the recessed area to create a bright recess. The areas are combined into various shapes or geometric forms; the lampshade may or may not have a light-transmitting body for development, depending on the requirements; the user can select the number of light sources or laser developing heads in the recessed area or outside, and the light or shadow, pattern projected by the light source or laser developing head in different light-emitting surfaces onto the lampshade surface, depending on the requirements; the laser developing system and the light-transmitting body can also be set on the lamp holder to project light and shadow, depending on the requirements; the opening, closing, light emission angle or light emission segment selection of the light source or laser developing head on the lamp is coordinated by the microcontroller inside the lamp and remotely controlled by a switch, control terminal or wireless remote control terminal.
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Description

Technical Field

[0001] This invention relates to the field of lighting fixtures, and in particular to a lighting fixture that emits light from multiple angles and allows for selection of the emission angle. Background Technology

[0002] Most lighting fixtures on the market only have a single light-emitting function. For example, T5 lamps, T8 lampshades, screw-type lamps, clip-on lamps, and living room planar lights, among other series, all only offer this basic function. These fixtures, lampshades, and planar lights lack options for light emission angle, illumination direction, and intensity. Currently, when these lamps, lampshades, or planar lights are turned on, the entire lamp body emits light, scattering it in all directions at a 360° angle, illuminating many areas that don't need illumination. In many applications, only a certain angle of illumination is required, not omnidirectional illumination. Omnidirectional illumination wastes half the light. For example, when a bare lamp emits light, part of the light shines upwards and part shines downwards. The upward-shielded light is wasted, and the downward-shielded light shines onto areas that don't need illumination, resulting in insufficient lighting in those areas. Furthermore, some areas that don't need illumination are still illuminated, causing light pollution. These are the drawbacks of most lighting fixtures, lampshades, and planar lights currently on the market. Summary of the Invention

[0003] This invention provides a multi-angle light-emitting lamp with selectable emission angles. The lampshade is divided into multiple grid-like recessed areas or grid-like recessed area segments by light-emitting partitions. These areas are overlapped in one or more layers, forming multiple layers. The number and size of each overlapping grid-like recessed area or grid-like recessed area segment may be the same or different. A light source or laser developing head is provided within or outside each recessed area. Multiple grid-like recessed areas of different shapes can be combined to form various shapes, or the light source or laser developing head can emit light within the recessed area to create a bright recess. The areas are combined into various shapes or geometric forms; the lampshade may or may not have a light-transmitting body for development, depending on the requirements; the user can select the number of light sources or laser developing heads in the recessed area or outside, and the light or shadow, pattern projected by the light source or laser developing head in different light-emitting surfaces onto the lampshade surface, depending on the requirements; the laser developing system and the light-transmitting body can also be set on the lamp holder to project light and shadow, depending on the requirements; the opening, closing, light emission angle or light emission segment selection of the light source or laser developing head on the lamp is coordinated by the microcontroller inside the lamp and remotely controlled by a switch, control terminal or wireless remote control terminal.

[0004] A multi-angle light-emitting lamp with selectable light-emitting angle, the lamp comprising a lamp holder structure, a power data circuit, a light source, a power inlet, a lampshade, a light-emitting partition, and a light-transmitting film to form a planar lamp;

[0005] The lamp holder structure is composed of multiple shapes and components of arbitrary geometric shapes. The lamp holder structure is a rectangular frame structure with through holes or thin light-transmitting holes. The lamp holder structure is also a shape with one closed end and one recessed end, or one or more recessed or through holes, of any geometric shape. The light-transmitting film is tightly attached to the surface of the lamp holder structure. The lamp holder structure is an injection-molded body or a stamped metal sheet. The lamp holder structure may or may not have a light-transmitting geometric outline on or within the through holes. The lamp holder structure is circular, square, elliptical, or an irregular geometric shape with one closed, planar, recessed end. The light-transmitting plate is made of a long, translucent, opaque material composed of multiple connected long strips or other arbitrary geometric shapes, either strip-shaped or quincunx-shaped.

[0006] The power data circuit contains various functional electronic components on its PCB board. These components include resistors, capacitors, microprocessors forming integrated circuits, diodes, transistors, rectifier bridges, miniature transformers, metal conductors, and may or may not include data storage modules, image output and display modules, laser image display systems, solar panels, energy storage batteries and circuits, and wireless receiving and output modules. The power data circuit has one or more PCB boards, each with multiple light sources. The PCB board can be circular, square, rectangular, cylindrical, or any other arbitrary geometric shape. Alternatively, the power data circuit may also include a laser developing system comprising a laser developing head, developing system, and electronic components. The source and the laser developing system or laser developing head are placed individually or together on the PCB board or the conductive metal conductor to obtain power for light emission or developing; the laser developing system can display images, pictures, logos, fonts, different light intensities and colors, geometric lines, and patterns; the light source or laser developing system is simultaneously set on the lamp fixture, or only an independent light source is set on the lamp fixture, or only an independent laser developing system or laser developing head is set on the lamp fixture; the laser developing system has one or more laser developing heads; the laser developing system or laser developing head is set inside or outside the lamp cover, or one or more units, and the laser developing head is controlled by data stored in the microprocessor or imported from the outside to project light, shadow, patterns, text, or trademarks onto the lamp fixture, the wall or ceiling of the fixed lamp fixture, or any object within the space of the fixed lamp fixture;

[0007] The light source or laser developing head is placed or connected individually or in multiples on the PCB board or the metal conductor of the power data circuit to form a parallel power supply circuit, or multiple light sources are connected in series to form a series circuit, or multiple light sources are connected in a mixed series and parallel manner to form a current loop with the electronic components and microprocessor on the PCB board, forming a wired or remote control integrated control body; the PCB board body is adapted to the different shapes of the recessed space in the lampshade shape according to the size of the recessed space area; the power inlet is a conductive structure consisting of two cylindrical metal parallel conductive structures, a threaded conductive structure, a snap-on conductive structure, a plug conductive structure, or a power cord conductive structure to introduce high voltage and low voltage power to the lamp.

[0008] The lampshade is provided with a light partition plate; the lampshade and the light partition plate are integrally injection molded structures; or the light partition plate is assembled outside the lampshade and then inserted into the lampshade to form an integral unit; the light partition plate is provided with a notch or through hole to accommodate the vertical light partition plate to form an assembly; the lampshade is composed of multiple concave areas separated by the light partition plate to form an arbitrary geometric shape; the light partition plate in the concave area is a single color or other different colors or a mixture of multiple different colors to form the concave area; one or more light partition plates of horizontal, vertical, circular or other arbitrary geometric shapes are placed at intervals inside the lampshade to separate the lampshade into two or more concave areas. Up to multiple layers; different shaped light partitions isolate lampshades of different shapes into single-layer, double-layer, triple-layer, quadruple-layer, five-layer, or more overlapping recessed areas; each recessed area is adjacent to or spaced apart from another recessed area and arranged in sequence to form a circle, square, strip, letter, font, animal, plant, household appliance, or other arbitrary geometric shape. Two or more independent recessed areas constitute a shape forming a single-layer or multi-layer overlapping layer; the surface of the lampshade is provided with one or more concave and convex shapes forming a font, letter, number, logo, animal graphic, human portrait, marine fish, flower, plant, mountain and river, celestial body, aircraft, or motor vehicle shape pattern.

[0009] Each of the light-emitting partition plates is equipped with a light source or laser developing head within the recessed area or segment of the recessed area. The light source or laser developing head is located adjacent to the surface of the light-emitting partition plate, or is located within the recessed area or segment of the recessed area of ​​the light-emitting partition plate, or is located within the recessed area or segment of the recessed area on the PCB board to emit light or develop light. The light emitted by the light source within the recessed area cannot directly shine on or be reflected into another recessed area segment isolated by the horizontal light-emitting partition plate or into the recessed area of ​​the vertical light-emitting partition plate.

[0010] The lampshade is a circular hollow structure, a square hollow structure, an elliptical hollow structure, or any other geometric shape; or one end of the lampshade is a smooth tube and the middle part is an irregular geometric shape; the lampshade has one or more spiral threads or concave long strip through holes inside or outside the concave hollow port, or multiple arc-shaped long strip convex or concave ribs.

[0011] A light-transmitting plate is installed inside the lamp holder structure and is glued or fastened to the lamp holder structure via a through-hole surface. The power data circuit and the PCB board with a multi-body light source or laser imaging system are installed and fixed inside the lamp holder structure. The power inlet is connected to the power input end of the PCB board to introduce power. The lampshade has one or more spiral threads or recessed elongated through-holes, or arc-shaped convex or concave ribs that match the spiral threads or recessed elongated through-holes or arc-shaped convex or concave ribs on the lamp holder structure. They are combined in a spiral or snap-fit ​​manner, or glued together or embedded inside and outside to fix them. The lamp holder structure or the lampshade may or may not have a light-transmitting body installed in the holes.

[0012] The lamp holder structure, the power data circuit, the PCB board, the light source and laser developing system, the lampshade, the power inlet or the light-transmitting body or the laser developing system are combined to form a complete lamp. When the power is turned on, the light source emits light or the laser developing system projects images, pictures, or geometric lines through the light emitted by the light source. The light source or laser developing system can be simultaneously installed on the lamp, or only the light source can be installed on the lamp, or only the laser developing system can be installed on the lamp. The light source or laser developing system can be simultaneously installed on the lampshade, or only an independent light source can be installed on the lampshade, or only... An independent laser developing system is installed on the lampshade; the laser developing system has one or more laser developing heads; the lampshade is equipped with a single horizontal light isolation plate that divides the lampshade into two or more adjacent and connected concave sections; the lampshade is equipped with horizontal and vertical light isolation plates that divide the lampshade into two or more annular concave sections and two or more adjacent and connected concave sections; no light isolation plate is installed in the concave sections of the lampshade, and a light source or laser developing head is installed in the concave sections to run a brightness change program or to control the number of light sources or laser developing heads that are turned on or off by selecting the number of times they are turned on or off.

[0013] The opening of the lampshade with the light-emitting partition plate is parallel to or in contact with the surface of the PCB board. The "micro-distance" refers to the position where the light source or the laser developing head of the laser developing system enters the lampshade or the surface of the light-emitting partition plate. The distance between the plane of the light-emitting partition plate and the laser developing head of the light source or laser developing system is between -200 mm and +20 mm. Preferably, the distance is such that the laser developing head of the light source or laser developing system enters the plane area of ​​the light-emitting partition plate at a negative distance. The laser developing head on the light source or laser developing system on the PCB board faces the lampshade cavity surface; the number of laser developing heads on the light source or laser developing system on the PCB board is two or more; the shape of the PCB board matches the shape of the lampshade; or multiple elongated PCB boards with light sources or laser developing heads are provided on a power data circuit; the laser developing head is set on the light partition plate or on the lamp structure, and the distance between the laser developing head and the light partition plate is 5-500cm, which is the application distance;

[0014] Multiple elongated PCBs are connected in parallel or in series with metal conductors for power supply; multiple elongated PCBs are placed directly on the lampshade with light spacers isolating each recessed area for light emission; or one or more light sources are provided on a power data circuit, which are welded together with metal conductors to form a series circuit light source or a parallel circuit light source; the series circuit light source or parallel circuit light source welded together with metal conductors is placed in the recessed area isolated by each light spacer for light emission as required; the lampshade of the planar lamp is made by vacuum forming or injection molding; the middle surface of the lampshade of the planar lamp is a three-dimensional line or shape, which may be flat or concave-convex, in the shape of an animal, human, flower, plant, aircraft, vehicle, or flower, and may be decorated with matching colors or not.

[0015] Light emitted by a light source entering the recessed area isolated by the light partition within the lampshade will not directly or reflect into another recessed area isolated by the light partition; individual or multiple light sources entering the recessed area isolated by the light partition within the lampshade can be independently switched on / off or run a brightness change program under the control of the microprocessor; or controlled together with one or more other individual or multiple light sources within the recessed areas isolated by the light partition; the lampshade is a single-layer or multi-layer trapezoidal shape, and the trapezoidal or single-layer lampshade may or may not have concave-convex three-dimensional lines or shapes.

[0016] The light emitted by the laser developing head of the light source or laser developing system in the recessed area of ​​the lampshade isolated by the light partition is projected onto the six viewing surfaces of the recessed area of ​​the lampshade isolated by the light partition, with only one viewing surface being able to transmit light.

[0017] The light emitted by the laser developing head on the light source or laser developing system is projected onto the six viewing surfaces of the recessed area inside the lampshade of the light partition plate, so that only any two viewing surfaces can transmit light.

[0018] The light emitted by the laser developing head of the light source or laser developing system in the recessed area of ​​the lampshade of the light partition plate is projected onto the six viewing surfaces of the recessed area of ​​the lampshade of the light partition plate, and only any three viewing surfaces can transmit light.

[0019] The light emitted from the laser developing head of the light source or laser developing system within the recessed area of ​​the lampshade isolated by the light partition is projected onto the six viewing surfaces of the recessed area isolated by the light partition, allowing light to pass through only any four or five of the viewing surfaces; one or more light-transmitting bodies are provided on the light-transmitting surface of the recessed area, or none are provided; each light-transmitting body can only receive light transmitted from one light-transmitting viewing surface; the light-transmitting body is located on the surface of the recessed area of ​​the lampshade, or within a hole on the surface, or within a hole in the lamp holder structure.

[0020] The planar luminaire with a light-isolating partition may or may not contain liquid; the lamp holder structure or lampshade structure containing the liquid is equipped with a sealing cap and glue to seal the liquid and prevent leakage; the lampshade of the planar luminaire with a light-isolating partition may or may not contain a laser developing system, and an electronic component matching the laser developing system is compatible with the system; the lampshade with a light-isolating partition may or may not contain a light-transmitting body; the planar grid recessed area or the annular recessed area or the recessed area without a light-isolating partition in the planar luminaire contains a recessed area segment or a single annular planar layer or a planar grid layer or an annular planar overlapping layer or a planar grid overlapping layer or a recessed area layer without a light-isolating partition; the annular planar layer or the planar grid layer or the annular The overlapping layers consist of planar overlapping layers, planar grid overlapping layers, or recessed areas without light-emitting partitions, with one side of each layer overlapping adjacently or at a distance. These overlapping layers are connected by metal conductors, power lines, data lines, or geometric structures smaller or larger than the lampshade. Within these geometric structures, metal conductors, power lines, or data lines connect the upper and lower layers, outputting power or data to the light source or laser developing system to control the light source or laser developing head's brightness variation program. The laser developing system or laser developing head is located inside or outside the lampshade, or one or more independently located at any part of the lamp. Data stored in the microprocessor or imported from the outside controls the laser developing head to project light, shadows, patterns, text, or trademarks onto the lamp's shape, the wall or ceiling of the fixed lamp, or any object within the space of the fixed lamp.

[0021] The luminaire controls the on / off and program selection of the light source or laser developing system by controlling the duration of power-off; the luminaire controls the number of light sources or laser developing heads turned on within the recessed area by controlling the duration and number of power-off cycles; the power or data remote control of the light source or laser developing head within each recessed area of ​​the flexible luminaire is independently controlled by the microprocessor, while wired connection control is jointly controlled by the switch and the microprocessor; the light source selection within each annular recessed area or the transverse light partition isolates the recessed area, allowing selection of different annular recesses via wired or wireless methods. Within an empty area or a horizontal light partition, the light source or laser imaging system within the concave area is isolated. The system can be turned on or off, and the number of light sources or laser imaging systems within the concave area or the number of concave area segments activated each time can be set via a switch, control terminal, wireless remote control, mobile terminal, sound, vision system, or brain-computer interface. The wireless remote control panel or mobile terminal is equipped with a concave area or a multi-segment filter key to select whether the light source within each concave area is powered on, the current is specified, or the power is turned on, the current is turned off, or a brightness change program is running.

[0022] The wireless remote control device is a button-operated wireless remote control or a mobile terminal. This device can simultaneously control the laser developing system or laser developing head and light source on the lamp, including turning them on and off, adjusting current levels, selecting light source operating programs, setting programs, turning the light source on and off within an angle, turning segment light sources on and off, adjusting and selecting light source colors, importing new programs, controlling the display interface, and storing and deleting images on the microprocessor's storage module, selecting laser video / images, adjusting the clarity of laser video / images, importing laser images, importing videos or images from the internet or mobile network, adjusting the clarity of laser images, importing external video / images, importing television signals, and controlling the light source. The system includes functions for setting and starting the source timing, audio pitch and range adjustment, audio on / off, light source intensity, and wireless connection to the remote control device. It connects to the power and data circuit via one or more wireless signals (Wi-Fi, Bluetooth, infrared, ultrasonic, or radio frequency) at the same frequency to form a connection control. A single wireless remote control or mobile terminal can simultaneously control all light sources within a single lamp or multiple lamps, as well as all functional applications on the laser developing system. A setting panel or LCD control panel on the wireless remote control, mobile terminal, or lamp structure can simultaneously control the operation of the light source and the laser developing system or laser developing head.

[0023] The outer layer of the recessed area within the lampshade is adjacent to the middle layer, and the middle layer of the recessed area is adjacent to the inner layer of the recessed area. Each adjacent layer constitutes a lampshade with multiple recessed areas, forming a multi-angle light-emitting lamp with selectable light-emitting angles. All light sources or laser developing heads within the lampshade structure are powered on and off via power data circuits, mechanical switches, control terminals, or remote controls. The power data circuits control all light sources or laser developing heads within the lampshade structure to run a brightness change program. The control method is: wired switch or control terminal for on / off control; or wireless remote control for remote control. The recessed space within the lampshade is divided into two or more recessed areas by vertical light partitions, horizontal light partitions, or irregularly shaped light partitions. The recessed areas are annular recessed areas, planar grid recessed areas, recessed area segments, or other geometric recessed areas, or recessed areas without light partitions. The annular recessed areas or planar grid recessed areas are single-layer recessed areas and multi-layer overlapping annular recessed areas or overlapping planar grid recessed areas, or recessed areas without light partitions and grids. Overlapping layers consist of grid-like or annular recessed areas; the annular recessed areas of the overlapping layers are further divided into annular overlapping inner layers, annular overlapping middle layers, and annular overlapping outer layers; the grid recessed areas of the overlapping layers are further divided into overlapping planar grid overlapping inner layers, planar grid overlapping middle layers, and planar grid overlapping outer layers; multiple light sources or laser developing heads on the PCB board within the recessed areas form single-layer inner layers, single-layer middle layers, single-layer outer layers, or multiple single-layer overlaps to form overlapping layers; the inner layer consists of one or more layers or vertically arranged side by side, and the middle layer consists of one or more layers or vertically arranged side by side. The components are arranged side by side, with the outer layer consisting of one or more layers or arranged vertically side by side; the inner, middle, and outer layers of the annular concave area or planar grid concave area, or the inner, middle, and outer layers of the light source or laser developing head, each layer consisting of any number from 2 to 100 million as the application quantity, arranged in a regular or irregular order, each single layer consisting of an inner, middle, or outer layer; multiple single-layer concave areas overlapping to form a multi-body overlapping layer; multiple concave areas with single or multiple overlapping layers forming a lampshade, combined with other components to form a lamp fixture.

[0024] The recessed areas are formed by light isolation plates or by the outer wall of the lampshade itself, creating independent recessed areas for the lampshade. The lampshade is a long strip lampshade or a tubular open or closed hollow lampshade. The interior of the lampshade is divided into multiple recessed areas by light isolation plates, or the lampshade may not have light isolation plates. Two or more lampshades are connected in series to form a single lampshade structure, or connected in series by data cables, power cables, or metal conductors to form a single lampshade light source, laser developing system, or laser developing head. The lampshade light source, laser developing system, or laser developing head operates under the control of a switch or control terminal, which may reduce or increase the light emission or image display of a single lampshade or multiple lampshades light source or laser developing head, either individually or together. Quantity; Unlit square or elliptical unlit isolation panels with recessed areas, and light-lit isolation panels with overlapping geometric recessed areas to form overlapping lampshades and lamps. The unlit isolation panels may or may not have holes in the recessed areas, with one or more holes. Each hole contains a geometric developing body or lampshade, which may be hollow or solid and contain a light source or laser developing head. The number of light sources or laser developing heads inside the lampshade can be increased or decreased under the control of a brightness change program and a switch or control terminal. Recessed areas can be combined to form grid-like recessed areas, single-layer recessed area lampshades, or two or more single-layer recessed areas overlapping to form grid-like recessed area overlapping layer lampshades; multiple or single-layer... Multiple overlapping geometric recessed areas can be set within single-layer or multi-layer overlapping annular or grid recessed areas to form an independent lampshade with annular and planar grids; multiple overlapping annular recessed areas can be set within single-layer or multi-layer overlapping planar grid recessed areas to form an independent lampshade with annular and planar grids; multiple recessed areas without light-emitting partitions can be combined to form a lampshade of any number in annular, square, or other shapes to constitute a luminaire. The number of light sources or laser developing systems or laser developing heads inside the lampshade can be reduced or increased under the control of a light-changing program and a switch or control terminal; different shaped light-emitting partitions can separate lampshades of different shapes into single-layer, double-layer, triple-layer, or quadruple-layer overlapping. Overlapping or five or more layers of overlapping recessed areas, each recessed area is adjacent to or spaced apart from another recessed area, arranged in sequence to form a circle, square, strip, letter, font, animal, plant, household utensil, or other arbitrary geometric shape. Two or more independent recessed areas constitute a shape to form a single layer or overlapping layers; each layer consists of multiple planes or the aforementioned annular recessed areas are adjacent or spaced apart, or the annular recessed areas are connected at intervals, or the recessed areas are connected at intervals, or connected by power lines or PCB boards or the aforementioned metal conductors to connect light sources or laser developing systems or laser developing heads, and multiple bodies are combined to form an annular regular layer or a strip regular layer. The annular recessed areas are divided into an inner annular layer, an inner annular layer, and an outer annular layer.The planar grid recessed area is divided into an inner planar layer, a middle planar layer, and an outer planar layer. Each lamp has 1 to 1 billion layers, which is the application quantity. Each layer has 1 to 100 million annular recessed areas, planar grid recessed areas, or light isolation plates that isolate the recessed areas. Each lamp uses one to any number of layers as the application layer of this invention. The number of each layer is not fixed. The outer layer is adjacent to or spaced from the middle layer, and the middle layer is adjacent to the inner layer. Each adjacent layer is enclosed within a planar shape or a three-dimensional shape, or the layers form a three-dimensional or planar shape. Alternatively, each layer is a random layer without distinction between inner and outer layers. The light source is connected to the planar grid recessed area or the annular recessed area by power lines, PCB boards, or metal conductors. The recessed area forms an irregular connection layer in series within the grid. Each layer forms an irregular layer with irregular intersections or irregular distances. The recessed area within each layer is equipped with a light source or a laser developing head.

[0025] The microprocessor on the power data circuit controls the light source, laser developing system, or laser developing head inside the lampshade to run the light change program in sequence, either by internally storing the light change program or by externally implanting the program. The light change program has three configurations: 1. Horizontal light change program: The light source, laser developing system, or laser developing head within the concave area or layer is switched on in a sequential order from left to right or right to left, creating a time difference that causes the light source to flash, thus moving or arranging in a queue. Alternatively, the light source, laser developing system, or laser developing head within the concave area or layer may switch on and off or change the current simultaneously. 1. Color change; 2. Circular brightness change program: The light source or laser developing system or laser developing head in the concave area or layer forms a time difference light source or laser developing system or laser developing head flashing in a clockwise or counterclockwise circular sequence to form a rotating or circular arrangement, or the light source or laser developing system or laser developing head in the concave area or layer together changes the power supply or the amount of current to change the color; 3. Irregular brightness change program: The light source or laser developing system or laser developing head in the concave area or layer runs the horizontal brightness change program and the circular brightness change program in one or more layers, either sequentially or irregularly. The sequence and all single or multiple overlapping or single or multiple rows of concave areas contain light sources, laser developing systems, or laser developing heads that are randomly arranged without regard to order, and their on / off states or current variations are adjusted to change color. The concave area segment is any combination of two or more adjacent concave areas forming an open or closed concave area. A concave area segment is defined by connecting light sources, laser developing systems, or laser developing heads in series with conductors, wires, or data cables within or outside each combined shape of the lamp, either emitting light together or sequentially running a brightness change program. The brightness change program uses single or multiple overlapping concave areas containing light sources or laser developing systems. Under the control of a microprocessor, the laser heads emit light in sequence at intervals, in a stacked or flowing manner, or in a running or flowing manner, or in an intermittent jumping manner, or in a running or short-term flashing manner, or in a snake-like manner, or in a gradually brightening or dimming manner, or in a moving trail, or in a combination of letters or numbers. This is achieved by multiple light sources or multiple laser developing heads emitting light in sequence or together; they flash together simultaneously or appear continuously to form three-dimensional or two-dimensional circular or square or rectangular or letter-shaped or font-shaped or animal-shaped or plant-shaped or household utensil-shaped or human-shaped or flower-shaped or motor vehicle-shaped or aircraft-shaped or human-shaped or marine fish-shaped or geometric patterns. One or more different types of patterns appear together in or outside the concave area.

[0026] The vertical light-isolating partition isolates light sources or laser developing heads within two or more annular grid recessed areas, or within recessed areas without light-isolating partitions. A switch, control terminal, or remote control controls the initial power-on of all light sources or laser developing heads within these areas, ensuring they remain constantly lit for 1-3 seconds. The power is then cut off and reconnected within 0.1-2 seconds. During this time, the number of light sources or laser developing heads in each annular grid recessed area decreases by one angle, gradually decreasing until they turn off. Close; The power is continuously turned on and off within a time range of 0.1 to 2 seconds each time, with the light source or laser developing head gradually closing down within a ring-shaped recessed area or an area isolated by a light-free isolation plate until only one light source remains continuously lit within the last angle; The power is continuously turned on and off within a time range of 0.1 to 2 seconds each time, with the light source or laser developing head gradually closing down within the recessed area, reducing the number of light sources or laser developing heads on one surface of the elongated, ring-shaped, or planar PCB board to no longer emit light until only one light source remains on the last elongated or ring-shaped PCB board. The surface light source or laser developing head remains constantly lit; then the power is turned off and restarted, and all light sources or laser developing heads remain constantly lit, returning to the initial state; when the light source power is turned on, all annular grid recessed areas or unlit isolation plates in the recessed areas of the laser developing head remain constantly lit for 1-3 seconds, then the power is turned off again within a time range of 0.2 to 2 seconds, and then the power is turned on 3 times consecutively to change the brightness change program; the brightness change program runs automatically, and all light and shadow change settings within the program are executed; during the brightness change time, the power is turned off again... Power-on is completed within 0.1 to 1 second, and automatic operation switches to running a specific brightness change program. Power-off and power-on again switch to the next specific brightness change program. If the power-off time exceeds 5 seconds or longer, all brightness change programs are turned off, and the microprocessor controls the brightness change programs to return to the initial always-on, always-on state. Power-on returns to the always-on, always-on state. The lampshade controls the brightness change programs to turn on and off based on the power-off time. The number of light sources on the elongated PCB board in the recessed area is reduced in sequence or at intervals.

[0027] Inside the lampshade, two or more recessed sections are isolated by horizontal light partitions. All light sources or laser developing heads within these sections are controlled by a switch, control terminal, or remote control. Upon initial power-on, all light sources in the recessed sections remain continuously lit. After 1-3 seconds of continuous lighting, the power is cut off and then re-energized within a 0.1-2 second timeframe. Within each of the multiple recessed sections, one light source or laser developing head is deactivated, or one or more light sources or laser developing heads are deactivated, creating a continuous shutdown. This power-on and shutdown cycle repeats continuously within a 0.1-2 second timeframe. The process continues until only one light source or laser developing head remains continuously lit, or the number of light sources or laser developing heads decreases. Until only one or a few light sources or laser developing heads remain continuously lit, the power is turned off and then restarted, returning all light sources or laser developing heads to a continuous, lit state, returning to the initial state. If the power to the light sources or laser developing heads is switched on for 1-3 seconds within the recessed area, and then the power is switched off again within 0.2-2 seconds, and then switched on three times consecutively, the system switches to a brightness change program. The brightness change program runs automatically, executing all brightness change parameters within the set parameters. During the brightness change period of the lampshade, if the power is switched off and then switched on again within 0.1-1 seconds, the automatic operation switches to selecting a specific brightness change program. Switching to the next specific brightness change program involves switching back to the previous one after switching off and then on again. If the power is off for more than 5 seconds, all brightness change programs are switched off, and the microprocessor-controlled brightness change program returns to the initial continuous, lit state. Switching back to continuous, lit state upon power-on again completes the process.

[0028] The light source or laser developing head on the circular PCB board is distributed in one or more groups within an angular region or geometric region, and then repeated in two or more angular regions or geometric regions on the PCB board; the angular region or geometric region of the light source or laser developing head matches the angle and geometry of the recessed area isolated by the light partition plate inside the lampshade; the lamp holder structure is a circular cavity structure, a square cavity structure, an elliptical cavity structure, or other arbitrary geometric structure. The lamp holder structure may be a smooth tube at one end and an irregularly shaped geometric structure in the middle; the lampshade may have one or more spiral threads or long, recessed through holes inside or outside the recessed port, or multiple convex or concave ribs in the shape of arcs; the lamp holder structure may have through holes for light transmission, and a light-transmitting film may be provided inside or on the outer surface of the through holes; the recessed area on the lampshade may be a closed recessed area or a recessed area with an open opening, with one side of the open recessed area on the lampshade; the lampshade may have closed or open recessed areas. The area contains geometrically open or closed structures that match the concave shape. One or more open or closed structures are placed within the concave area of ​​the lampshade. The geometrically open or closed structures are made of any color. A single body of the same color is placed within the concave area, or multiple bodies of different colors are placed within the concave area to form geometrically open structures of different colors. The shape of the geometrically open structure can be that of a land animal, an insect, a marine animal, an aircraft, a motor vehicle, a plant, a flower, a mountain or river, a celestial body, or an ocean or ship. The concave area of ​​the lampshade, separated by a light partition of any geometric shape, is of any geometric shape. One or more light sources or laser developing heads are placed inside the hollow or solid geometrically open or closed structures. The light sources or laser developing heads in the geometrically open or closed structures are connected to one or more other light sources or laser developing heads via power lines and data lines, and then connected to a microprocessor to transmit data or form control.

[0029] The laser developing system is equipped with one or more laser developing heads, spaced at single-row, circular, or square grid intervals, to project and display images, videos, pictures, logos, fonts, lights of different intensities and colors, geometric lines, and patterns onto a PCB board, lamp holder structure, lamp, or light partition plate. The images are displayed in the recessed area inside the lampshade or on the outer surface of the lampshade. One laser developing system may have multiple laser developing heads displaying a single image together, or each laser developing head may display a single image. Each laser developing head projects, reflects, or refracts light within the recessed areas isolated by vertical or horizontal light partitions, on the surface of the lamp, on the wall or wall where the lamp is fixed, on the fabric around the lamp, or on the lamp structure. One laser developing head on the laser developing system displays an image. Multiple independent images are isolated by geometric shapes and projected onto the recessed areas isolated by vertical or horizontal light partitions, or onto the surface of the shapes; or multiple laser developing heads are mounted on the laser developing system, each laser developing head positioned within the recessed areas isolated by vertical or horizontal light partitions, or onto the surface of the shapes, the lamp holder structure, or the lampshade; the laser developing heads are mounted on the PCB board or on the horizontal or vertical light partitions; the light emitted from the laser developing heads travels from a first position on the elongated PCB board to a second position on the inner wall of the lampshade area isolated by the light partitions, and then is transmitted to the outer wall of the lampshade at a third position, scattering into the space; the light emitted from the laser developing heads inside the lampshade is projected onto the lampshade to form clear light and shadow lines and high and low light intensity contrast, with a high and low light intensity contrast ratio of 0.1-0.The light intensity and contrast ratio vary within any range of 7. Within the lampshade, in two or more recessed areas, or within annular recessed areas, or within horizontally isolated recessed areas, or within recessed areas without light-emitting isolation plates, the light source or laser developing head is directly connected or disconnected via a mechanical switch or control terminal. This allows selection of whether the light source or laser developing system or laser developing head in each recessed area is turned on simultaneously or selectively turned on in specific recessed areas. The laser developing system body is equipped with one or more laser developing heads arranged on the PCB board in single-row long strip intervals, annular intervals, square grid intervals, or any geometric shape to project and display images. The display includes images, logos, fonts, different light intensities and colors, geometric lines, and patterns, either inside or outside the lampshade. The laser developing system displays images isolated from each other, mapped together by multiple independent images, or by multiple laser developing heads arranged side-by-side at intervals, or in multiple rings, rhombuses, or triangles, mapped onto all vertically isolated concave areas, horizontally isolated concave areas, or concave areas isolated by unlit partitions, on surfaces, walls, canvases, translucent cloths, laser developing cloths, transparent reflective materials, lamp structures, LCD screens, or OLED screens. The images mapped by the laser developing heads are either edge-overlapping, edge-aligned, or image-mapped. The laser developing system can project light and shadow images by means of a distance between the laser developing heads or by one or more laser developing heads overlapping each other, creating an image that is embedded within the laser developing head. Alternatively, the laser developing system can have multiple laser developing heads, each positioned within a vertically isolated recessed area for developing, or within a recessed area isolated by a horizontal light partition, or within a recessed area isolated without a light partition. The laser developing system includes one or more laser developing heads, and one laser developing system drives multiple laser developing heads to develop simultaneously. The laser developing heads transmit digital image data or analog signal data via metal conductors or data cables, and are controlled by actuators such as electronic components within the laser developing heads. In a laser developing system, light emitted from one or more laser developing heads is directly transmitted to the mirror surface of one or more laser developing heads, where it is refracted, directly incident, reflected, refracted, magnified, and projected onto the surface of a lampshade, wall, display screen, curtain, transparent reflector, lamp structure, or any other object for development. The transmission of light signals from one laser developing head to another in the laser developing system can be done remotely in a vacuum, through air, via transparent fiber optic cable, via a protected outer sheath, via a concave cavity, or within a concave cavity. The laser developing system can also transmit light and shadow simultaneously from one developing head to multiple laser developing heads or transmit light and shadow one-to-one.

[0030] The lamp housing contains single-layer multi-recessed areas, two to five or more layers of multi-recessed areas, and multiple overlapping annular recessed areas. Each layer is controlled by a microprocessor on a power data circuit, or multiple microprocessors on a power data circuit control one or more light sources, laser developing systems, or laser developing heads within each layer or recessed area to run a brightness change program, power on / off, or display images / pictures. Alternatively, each of two to more layers of multi-recessed areas or overlapping layers is coordinated and controlled by a microprocessor on a power data circuit to run a brightness change program, power on / off, or display images / pictures within each layer or recessed area. Each layer or overlapping layer of the annular grid recessed area and the planar grid recessed area is controlled by a microprocessor on a power data circuit to operate independently, together, or in combination, using a set of brightness change programs to control one or more light sources or laser developing systems within each independent recessed area. The imaging system or the laser developing head operates a brightness change program, or switches power on / off, or displays images or pictures; each layer or each overlapping layer of the annular grid recessed area and the planar grid recessed area, or the recessed area without light isolation plate, is controlled independently, together, or in combination by one or more microprocessors on the power and data circuits. A set of brightness change programs controls the light source or laser developing system or laser developing head in each independent recessed area of ​​each layer to operate the brightness change program, or switch power on / off, or display images or pictures; the microprocessor is linked to another microprocessor, transmits signals, and exchanges data via wired or wireless connection; the wireless connection is Wi-Fi, Bluetooth, infrared light, ultrasound, or various high and low frequency radio frequency signals, one or more of one or more wireless signals combined as a wireless connection method; the light source is independently set in the recessed area, or together with the laser developing system or laser developing head set in all recessed areas or externally to emit light or display images or pictures.

[0031] The light source or laser developing head in the lamp fixture is always on and always lit. The number of light sources, laser developing systems, or laser developing heads activated, the different angles of light sources or laser developing heads, different colors, color temperatures, on / off timings, brightness changes, video, images, patterns, and geometric lines are all set by the microprocessor in the power data circuit using a memory circuit or internal energy storage battery. Each time the lamp is turned on again, the stored parameters are used as the initial startup parameters. The PCB board is composed of three layers of substrate material: an aluminum sheet substrate layer, a thermally conductive insulating layer, and a copper foil substrate layer, all overlapped and bonded together with adhesive. Alternatively, the PCB board can also be composed of three layers of substrate material: an aluminum sheet substrate layer, a thermally conductive insulating layer, and an aluminum sheet substrate layer, all overlapped and bonded together with adhesive. The PCB board can be configured as follows: A single or multiple copper, aluminum, or iron metal wires are laid together in a U-shaped groove on the aluminum substrate layer and secured by the left and right sides of the U-shaped groove, or glued and bonded within the U-shaped groove; or the metal wires are placed on the aluminum substrate layer and glued to form the application substrate. Alternatively, the PCB board can be configured as follows: A single or multiple copper, aluminum, or iron metal wires are laid together in a U-shaped groove on the plastic substrate layer and secured by the left and right sides of the U-shaped groove, or glued and bonded within the U-shaped groove; or the metal wires are placed on the plastic substrate layer and glued to form the application substrate. The metal wires are round, elliptical, or sheet-shaped, and the aluminum plate and plastic sheet are the application components of the PCB board of this invention.

[0032] The mobile terminal, remote control, or control panel on the lighting fixture can simultaneously control the light source, laser developing system, or laser developing head to turn on and off as needed, select functions, control the number of laser developing heads or light sources to turn on and off each time, or run brightness change programs or select parameters for brightness change programs. The mobile terminal has a display interface with virtual buttons, physical buttons, and various parameter function selection interfaces. The parameter interface includes functions for controlling light source number, light source naming, full or partial on / off, timing, brightness adjustment, automatic program operation selection, on / off of light sources within an angle, on / off of segment light sources, light source color adjustment and selection, specific program selection, program forward selection, program backward selection, single light source selection, automatic parameter memory function, simultaneous operation of multiple different independent light source numbers networked together, and light source operation signal display interface controlled simultaneously with text, icons, and virtual buttons. The display interface also includes virtual buttons and various parameter function selection interfaces. The parameter interface includes functions for controlling the laser developing system or laser developing head to turn on and off, selecting the number of laser developing systems or laser developing heads, selecting and storing video, importing video, selecting images, and displaying images. The laser display system includes functions for inputting video, storing and setting data parameters, selecting light intensity, importing external TV signals, setting audio volume, turning audio on / off, displaying and selecting wireless signal connections, controlling a single laser developing head interface, setting a single laser developing head, setting simultaneous display of multiple laser developing heads, selecting video sources for a single laser developing head and multiple laser developing heads, setting text display for laser developing heads, setting color display for laser developing heads, setting image display for laser developing heads, and setting laser developing head and lamp numbers via multi-microprocessor control. The laser display system control and setting interface is also described. The light source control interface can be operated and controlled in one window with two interfaces, or in two windows with two interfaces, or in multiple windows. The mobile terminal can be a vehicle display terminal, smartphone, tablet computer, laptop computer, desktop computer, smartwatch, AR glasses, handheld display terminal, or wearable device, constituting the application source of this invention. The mobile terminal may or may not have a hanging ring for hanging on a key ring or other ornaments that can accommodate hanging rings. The hanging ring is integrally manufactured with the wireless remote control shell or manufactured in other places and then assembled on the button wireless remote control or the mobile terminal.

[0033] The PCB board is configured with one or more long strip PCB boards, circular PCB boards, square PCB boards, or arbitrarily curved geometric PCB boards of the same shape according to the shape of the lamp holder structure or lampshade. The PCB board is connected to the light source, laser developing system, laser developing head, and electronic components via two or more power lines to form a power data circuit. The power data circuit is equipped with an energy storage battery or a photovoltaic panel to generate power for the circuit. The power data circuit has the following functions: voltage regulation, AC or DC output, energy storage, high or low voltage output, image storage, image receiving and output, wireless connection, program storage, program setting memory, self-programming, power on / off program selection and video output, brightness change program programming, brightness change program selection, multiple microprocessor coordination and synchronization, and brightness change program. The lamp includes the following functions: power-off selection, brightness change program memory, photosensitive power-on / power-off, mobile terminal interface settings, mobile terminal signal synchronization reception and output, mobile terminal interface interaction, mobile terminal interface programming, high-frequency current output, high-frequency synchronization, timing, RGB light source color digital control output, multi-channel light source output, digital signal output, analog signal output and reception, visual reception and output, mind control, camera-acquired digital signal storage and output, sound control, and infrared reception. All functions are integral to the light source or laser imaging system of the lamp, and may constitute all or some of the lamp's application functions. Each function is composed of corresponding electronic components and integrated circuits or functional modules and software adapters. All or some of these functions constitute a microprocessor and power / data circuits or an independent microprocessor.

[0034] The light source can be a single or a combination of LED SMD bulbs, LED plug-in bulbs, xenon bulbs, halogen bulbs, or tungsten filament bulbs. The light source can be powered by any high voltage within the range of 37-380V. Alternatively, it can be powered by a low voltage source within the range of 2-36V, achieved by stepping down high voltage AC mains power. The light source can also be powered by a storage battery or a solar photovoltaic panel. The power data circuit is equipped with a storage battery or a photovoltaic panel to provide power. The power data circuit uses AC mains power or electricity generated by the solar photovoltaic panel as its energy storage source. The power data circuit is equipped with a lithium or lead-acid battery for energy storage. At appropriate times, the photosensitive circuit on the power data circuit senses the light intensity and automatically activates the storage battery to supply power to the light source or laser imaging system, thus activating the light source for illumination or the laser imaging system for displaying images or patterns.

[0035] The microprocessor is composed of various electronic components and can execute arithmetic logic. It includes an arithmetic logic unit, a controller, registers, an internal bus, etc., which constitute the ability to receive and output data. It includes general-purpose high-performance microprocessors, embedded microprocessors, digital signal processing microprocessors, etc. The microprocessor includes commonly used execution devices on the market, including microcontrollers, microcomputers, microelectronic execution units, IC modules, PLCs, etc. The microprocessor includes all existing microprocessors on the market as application components. The mechanical switch or control terminal is a multi-contact, multi-level output. The switch includes push button switches, remote control switches, rocker switches, rotary switches, pull-cord switches, tactile switches, touch switches, resistive touch switches, capacitive touch switches, micro switches, double-control switches, inductive switches, timer switches, etc., and various switches or control terminals used on the market are the application switches of this invention. The invention can include all structures disclosed in this invention, including circuits, lamp covers, light sources, laser developing systems including laser developing heads, geometric shapes, manufacturing processes, manufacturing procedures, etc. The invention can use existing technologies on the market as the application source of this invention or the processes disclosed in this invention as the application source of this invention. The laser developing system includes a laser developing head, which is based on any existing laser developing system, laser developing head, laser, laser developing method, or any existing developing method on the market. It includes all components, shapes, circuits, electronic components, imaging methods, driving circuits, color, image storage methods, wireless connections, and external data input methods—all elements constituting the developing system are the application source of this invention. The laser developing system includes one or more laser developing heads, with one laser developing system driving multiple laser developing heads for simultaneous developing. The laser developing heads transmit image digital data or analog data via metal conductors or data cables. The simulated signal data is controlled by the actuators such as electronic components inside the laser developing head to develop the light or the light emitted by one or more laser developing heads in the laser developing system. The light is directly transmitted to the mirror surface of one or more laser developing heads and then refracted, directly incident, reflected, refracted and magnified, and projected onto the surface of the lampshade, or onto a wall, or onto a display screen, or onto a screen, or onto a transparent reflector or other arbitrary object for development. The transmission of light signals from one laser developing head to another in the laser developing system is done in a vacuum, in the air, or via a transparent optical fiber cable, or via a protected optical cable, or via a pipe for isolation and protection, or via a concave cavity.The mirror on the laser developing head is a flat mirror, or a mirror with one flat and one concave side, or a mirror with one flat and one convex side. The mirror on the laser developing head has one or more overlapping mirrors spaced at intervals, reflecting the light and shadow emitted from the developing head of the laser developing system. The overlapping lenses are lenses of the same shape or different shapes, arranged in a relatively spaced arrangement to form the laser developing head. The mirror on the laser developing head is round, square, or elliptical, and is mounted on a movable or fixed bracket. The movable bracket can move back and forth to adjust the distance between the mirrors, or rotate 180 degrees to adjust the light incident angle between the mirror and another mirror. Alternatively, the movable bracket may have both a forward moving and a rotating mechanism. The movement of the movable bracket can be manually adjusted by threads on the fixed seat and an adjustment button, or by an electric worm gear drive mechanism on the movable bracket to drive the mirror to move back and forth or rotate. The drive mechanism can be a servo drive, a stepper motor drive, or a motor reduction mechanism to drive the mirror forward, backward, and rotation. The laser... Each mirror on the developing head can move forward, backward, and rotate to adjust its angle, or some mirrors can move forward, backward, and rotate to adjust their angle; multiple mirrors on the laser developing head can magnify or reduce the projected image; the laser developing head can move back and forth to adjust the size of the projected image; the edges of the projected image are overlapped or edge-aligned; one or more laser developing heads or independent laser developing heads on the laser developing system are set at a uniform distance on the same horizontal plane, or partially set on the same horizontal plane and partially distributed in a fan-shaped or trumpet-shaped angle, projecting images at intervals onto the surface of a lampshade, wall, display screen, screen, transparent reflector, or other arbitrary object to form a single projected image or multiple projected images; one developing head in the laser developing system simultaneously transmits light and shadow to multiple laser developing heads, or multiple laser developing heads transmit light and shadow one-to-one to multiple laser developing heads to display images; one laser developing head in the laser system projects light and shadow to each projecting laser developing head at the same frequency in a matrix scanning manner. Attached Figure Description

[0036] Figures 1 to 3 This is a schematic diagram illustrating the three-dimensional and partial cross-sectional structure of a multi-angle light-emitting lamp with selectable light-emitting angle.

[0037] Figures 4 to 10 A schematic diagram illustrating the program operation and structure of a multi-angle light-emitting lamp with selectable light-emitting angle.

[0038] Physical implementation

[0039] The specific embodiments of the present invention will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and are not intended to limit the scope of the invention.

[0040] In the description of this invention, unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The term "and / or" as used herein includes any and all combinations of one or more of the associated listed items. Furthermore, the terms "left," "right," "upper," "lower," "inner," etc., indicating orientation or positional relationships based on the orientation or positional relationships shown in the accompanying drawings, are used only for the convenience of describing the invention and for simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore should not be construed as limiting the invention. In addition, the terms "installation" and "connection" should be interpreted broadly, for example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two elements. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances. Furthermore, the technical features involved in the different embodiments of the invention described below can be combined with each other as long as they do not conflict with each other.

[0041] See Figure 1 , Figure 2The diagram shows a lampshade with an outer layer adjacent to the middle layer of the recessed area, and a middle layer adjacent to the inner layer of the recessed area. Each adjacent layer forms a lampshade with multiple recessed areas, constituting a multi-angle light-emitting lamp 01 with selectable light-emitting angle. The lamp 01 includes a lamp holder structure D1, a power and data circuit D2, a light source D3 or a laser developing head D22, a power inlet D4, a lampshade D5, a light partition D6, and a light-transmitting film D7, forming a planar lamp D01. The lamp holder structure D1 is composed of a polymorphic, multi-part structure D101 with arbitrary geometric shapes. The lamp holder structure D1 is a rectangular frame structure D102, with through holes D103 or thin light-transmitting holes D104 on the frame structure D102. The lamp holder structure D1 is closed at one end. The lamp holder structure includes a recessed or other recessed or through-hole shape of any geometric form; a light-transmitting film D7 is tightly attached to the surface D1 of the lamp holder structure; the lamp holder structure D1 is an injection-molded or stamped metal sheet; a light-transmitting geometric outline D8 may or may not be provided on the lamp holder structure or within the through-hole D11; the lamp holder structure D1 is a circular, square, elliptical, or irregular geometric shape with one closed, flat, recessed end; the light-transmitting plate D7 is a long, translucent, or opaque material composed of multiple connected long strips or other arbitrary geometric shapes; various functional electronic components are placed on the PCB board D21 within the power and data circuit D2; these electronic components include resistors, capacitors, etc. The microprocessor is composed of integrated circuits, diodes, transistors, rectifier bridges, miniature transformers, metal conductors, and may or may not include data storage modules, image output and display modules, laser image display systems, solar panels, energy storage batteries and circuits, and wireless receiver and output modules. The power data circuit D1 has one or more PCB boards D21, each PCB board D21 containing multiple light sources D3 or laser developing heads D221. The PCB board D21 can be circular, square, rectangular, cylindrical, or any other arbitrary geometric shape. Alternatively, the power data circuit D1 may also include a laser developing system D22. The laser developing head D221, developing system, and electronic components, light source D3, and laser developing system body D22 are individually or jointly placed on the PCB board D21 or fixed on a conductive metal conductor to obtain power for emitting light or developing; the laser developing system D22 can display images, pictures, logos, fonts, lights of different intensities and colors, geometric lines, and patterns; the electronic components are selected and arranged in different quantities, with different parameters, different functions, different power, and different functional components to adapt to different functions and power requirements of the planar lamps D01; multiple light sources D3 are set on the surface of the PCB board D21; the power inlet body D4 is a power cord D45 or a plug with a power cord D44.

[0042] Light source D3 or laser developing head D221 are placed or connected individually or in multiples on the PCB board D21 or metal conductor D213 within the power data circuit D1 to form a parallel power supply circuit, or multiple light sources D3 are connected in series to form a series circuit, or multiple light sources D3 are connected in a mixed series and parallel manner to form a current loop with the electronic components and microprocessor on the PCB board D21, forming a wired or remote control integrated control body; the PCB board D21 body is adapted to the different shapes of the recessed space within the lampshade D5 shape, either in a straight shape or a bent shape; the power inlet body D4 is a conductive structure consisting of two cylindrical metal parallel bodies, or a threaded conductive structure D47, or a snap-on conductive structure D46, or a plug conductive structure D44, or a power cord conductive structure D45, which introduces high-voltage or low-voltage power to the lamp 01.

[0043] The lampshade D5 is provided with a light partition plate D6; the lampshade D6 and the light partition plate D6 are integrally injection molded into a structural body D61; or the light partition plate D62 is assembled outside the lampshade D5 and then inserted into the lampshade D5 to form an integral unit; the light partition plate D6 is provided with a notch D603 or a through hole to accommodate the vertical light partition plate D65 to form an assembly; the multiple recessed areas D63 of the lampshade D5 separated by the light partition plate D6 are combined to form an arbitrary geometric shape; the light partition plate D6 in the recessed area D63 is a single color or other different colors or a mixture of multiple different colors to form the recessed area D63; the lampshade 5 is provided with a horizontal Place one or more light-shading partitions D6 at intervals in the shape of D64, vertical D65, ring, or other arbitrary geometric shapes to isolate the lampshade D5 into two or more recessed areas, or two or more layers; light-shading partitions D6 of different shapes isolate lampshades D5 of different shapes into single-layer, double-layer, triple-layer, quadruple-layer, five-layer, or more overlapping recessed areas; each recessed area is adjacent to or spaced apart from another recessed area and arranged sequentially with another recessed area to form a circle, square, rectangular, letter-shaped, font-shaped, animal-shaped, plant-shaped, household appliance-shaped, or other arbitrary geometric shape. Two or more independent recessed areas form a single layer. The lampshade may have multiple overlapping layers; or the surface of the lampshade may be decorated with one or more concave and convex shapes forming fonts, letters, numbers, logos, animal figures, human portraits, marine life, fish, flowers, plants, mountains, rivers, celestial bodies, aircraft, or motor vehicles; each light partition D6 has a light source D3 or a laser developing head D221 installed within its recessed area D66. The light source D3 or laser developing head D221 is installed adjacent to the surface of the light partition D6, either within the recessed area D66 of the light partition or within the recessed area D66 of the PCB board D21. The light emitted by the light source D3 in the recessed area cannot be directly or reflected into the other recessed area section D66 isolated by the horizontal and vertical light partitions D64 and D65, or into the recessed area isolated by the vertical light partition; the lampshade D5 is a circular cavity structure D51, a square cavity structure D52, an elliptical cavity structure, or other arbitrary geometric shapes; or one end of the lampshade D5 is a smooth tube, and the middle part is an irregularly shaped geometric structure; the recessed port of the lampshade D53 is provided with one or more spiral threads D533 or recessed elongated through holes, or multiple arc-shaped elongated convex or concave ribs.

[0044] A light-transmitting plate D7 is installed inside the lamp holder structure D1 and is glued or clipped to the lamp holder structure D1 with the through hole D11. A power inlet D4 is connected to the power input terminal of the PCB board D21 to introduce power. The lampshade D5 has one or more spiral threads D533 or recessed elongated through holes, or one or more arc-shaped convex or concave ribs, which match the spiral threads D534 or one or more recessed elongated through holes, or arc-shaped convex or concave ribs D13 on the lamp holder structure D1. They are assembled by spiral or snap-fit ​​methods, glued together, or embedded internally and externally. The light-transmitting plate D7 is installed inside the through hole D11 on the lamp holder structure D1 or the lampshade D5. A light-transmitting body D8 may or may not be provided on the lampshade D5; the lamp holder structure D1, power and data circuit D2, PCB board D21, light source D3, laser developing system D22, lampshade D5, power input body D4 or light-transmitting body D8 or laser developing system D71 are combined into a complete planar lamp D01; when the power is turned on, the light source D3 will emit light or the laser developing system body D71 will project images, pictures, or the light-transmitting body D8 will transmit geometric lines through the light emitted by the light source D3; the light source D3 or the laser developing system D22 may be provided on the lamp D01, or only the light source D3 may be provided on the lamp D01, or only the laser developing system D22 may be provided on the lamp D01.

[0045] The opening of the lampshade D5, which is isolated by the light-emitting partition D6, is parallel to or slightly adjacent to the surface of the PCB board D21. This slight distance D31 is the position where the light source D3 or the laser developing head D221 of the laser developing system D22 enters the lampshade D3 or the surface of the light-emitting partition D6. The distance between the plane D67 of the light-emitting partition and the light source D3 or the laser developing head D221 of the laser developing system D22 is between -200 mm and +20 mm, which is the slight distance D31. Preferably, the light source enters the light-emitting partition D6 at a negative distance D32. Within the plane D67 area; the light-emitting surface of the light source D3 on the PCB board D21 or the laser developing head D221 on the laser developing system faces the cavity surface of the lampshade D5; the number of laser developing heads D221 on the PCB board D21 is two or more; the shape of the PCB board D21 matches the shape of the lampshade D5; or a power data circuit D2 is equipped with multiple long strip PCB boards D211 with light source D3 or laser developing heads; the light spacer is a sheet with multiple concave openings spaced apart, and the concave openings are relatively matched with multiple intervals to form multiple phases. The grid-like structure matches the shape of the lampshade, isolating the lampshade into grid-like recessed areas. Within these recessed areas, sheet-like light spacers with openings are bent into S-shaped, O-shaped, U-shaped, or N-shaped geometric shapes, further isolating the planar grid-like recessed areas into various different geometric shapes; or single or identical shapes of different shapes; the light spacers have multiple recesses arranged in a circular shape with angular spacing, radially arranged recessed areas, or S-shaped, any letter shape, font shape, human shape, animal shape, flower shape, plant shape, aircraft shape, vehicle shape, celestial shape, mountain and river shape, or sea shape. One or more concave areas of ocean ship hull shape or irregular geometry are stacked in one or more layers inside the lampshade and combined with the lampshade to form a single-layer or multi-layer overlapping concave area; or the light partition is integrally injection molded into an S-shape or any letter shape or font shape or human shape or animal shape or flower shape or plant shape or aircraft shape or motor vehicle shape or celestial shape or mountain and river shape or ocean ship hull shape or irregular geometry of multicave areas of concave area shape. One or more concave areas of ocean ship hull shape or irregular geometry are stacked in one or more layers inside the lampshade and combined with the lampshade to form a single-layer or multi-layer overlapping concave area.

[0046] The lampshade contains one or more light-emitting partitions distributed on the inner surface of the lampshade structure, which divide the 360-degree inner surface of the closed circular, square, or elliptical lampshade into 10- to 350-degree angle regions. Multiple elongated PCBs D211 are connected in parallel or in series with metal conductors D212 for power supply. Multiple elongated PCBs D211 are placed directly on the lampshade D5, and the light-emitting partitions isolate each recessed area D63 for light emission. Alternatively, a power data circuit D2 may have one or more light sources D3 soldered to it with metal conductors D213 to form a series or parallel circuit light source. D3; The metal conductor D213 is welded in series to form a light source D3 or a parallel circuit to form a light source D3. The light source D3 is positioned as needed within the recessed area D63 isolated by each light partition; or it emits light within each recessed area inside the lampshade without light partitions. The lampshade D5 on the planar lamp D01 is made by vacuum forming or injection molding. The middle surface D572 of the lampshade D5 on the planar lamp D01 is a three-dimensional line or shape, either flat or convex / concave 3D animal, human, flower, plant, aircraft, vehicle, or floral shape. Matching colors may or may not be provided on the shape or lines. The color of the shape may be achieved through screen printing, oil printing, printing, or heat treatment. Made by transfer printing; the light emitted by the light source within the recessed area of ​​the light partition D6 inside the lampshade D5 will not directly shine or reflect into another recessed area isolated by the light partition; the single light source D33 or multiple light sources D34 within the recessed area of ​​the light partition D6 inside the lampshade D5 can independently realize on / off switching or run a brightness change program under the control of a microprocessor; or be controlled together with one or more other single or multiple light sources D34 within the recessed area D63 isolated by the light partition D6; the lampshade D5 is a single-layer shape D571 or a multi-layer trapezoidal shape D57, and the multi-layer trapezoidal lampshade D57 or the single-layer lampshade D571 is provided with concave and convex three-dimensional lines or shapes or not. The light emitted by the light source D3 or the laser developing head D221 from the recessed area D63 of the lampshade D5, isolated by the light partition D6, is projected onto the six viewing surfaces A1-A6 of the recessed area D63. These six viewing surfaces refer to the basic physical components of an object, with only one to five viewing surfaces capable of transmitting light. The light-transmitting body D8 can only receive light transmitted from one of the viewing surfaces. The light-transmitting body D8 is located on the recessed area D55 of the lampshade D5, within a hole D56 on the surface, or within a through hole D11 in the lamp holder structure. Liquid may or may not be placed inside the planar luminaire D01 isolated by the light partition.The lamp holder structure for the liquid lamp is equipped with a sealing cap D15 and glue to seal the liquid and prevent leakage. The sealing cap D15 is fitted to the shape of the lampshade D5 and is located on the upper part of the light partition plate D6 at one end of the lampshade D5. The sealing cap D15 has a liquid injection port D151 and a liquid-sealing rubber stopper D152. After the liquid is injected into the lampshade D5, the rubber stopper D152 seals the liquid and prevents leakage. Geometric reflective elements are set inside the liquid as needed. The liquid lampshade D5 is made of transparent or semi-transparent material. The liquid can be water, alcohol, wine, kerosene, plant juice, or any liquid that can flow on Earth. The liquid can be transparent or semi-transparent and may or may not contain color. The liquid is either transparent or colored. A transparent liquid; the liquid may be colored or colorless; the colored liquid may be a mixture of three primary colors of any color; the liquid is distributed within a single-layer concave region or multiple isolated concave region layers; the liquid color may be the same or different in each layer; the transparent liquid may be an impurity-free insulating transparent liquid or a non-insulating transparent liquid; the transparent liquid contains photon-exciting reflective particles, the reflective material having the same or lower specific gravity as water, and the reflective material is suspended in the liquid as microparticles or thin sheets; the laser developing system D22 or laser developing head D221 is located inside or outside the lamp cover D5, or one or more independently located at any part of the lamp D5, and controls the laser developing head D22 by storing data in the microprocessor or importing data from the outside. 21. Projecting light, shadow, patterns, text, or trademarks onto the shape of the luminaire 01, the wall or ceiling of the fixed luminaire 01, or any object within the space of the fixed luminaire 01; A laser developing system D71 may or may not be installed inside the lampshade D5 of a planar luminaire D01 with a light-shaping partition D6, and electronic components matching the laser developing system D71 are compatible with the system; A light-transmitting body D8 may or may not be installed inside or outside the lampshade D5 with a light-shaping partition; The light-shaping partition D6 is a vertically elongated strip-shaped light-shaping partition D65 or a horizontally annular strip-shaped light-shaping partition D64, with one or more recessed openings D603 spaced at intervals; Multiple vertically elongated strip-shaped light-shaping partitions D65 with recessed openings D603. Multiple concave openings D603 at intervals are matched and combined to form a planar grid-like concave area body D68; multiple planar grid-like concave area bodies D68 are overlapped with one or more vertical strip-shaped light spacers D65 in the middle to form a multi-layer planar overlapping layer body D681; multiple vertical strip-shaped light spacers D65 with concave openings D603 and multiple annular strip-shaped light spacers D64 with concave openings D603 at intervals are matched and combined to form an annular grid concave area body D69; multiple annular strip-shaped light spacers D64 with concave openings D603 at overlapping intervals are combined to form an annular grid concave area body D691;The planar grid-shaped recessed area D68 and the annular grid-shaped recessed area D69 are configured to match the shape of the lampshade D5, isolating the lampshade D5 into either the planar grid-shaped recessed area D68 or the annular recessed area D69. The on / off control of the light source within each recessed area is independently controlled by a microprocessor. The light source within each annular recessed area, or within a recessed area isolated by a horizontal light partition, or within a recessed area without a partition, can be turned on, off, set, or selected via wired or wireless means. The lamp is configured via a switch or control terminal, a wireless remote control, a mobile terminal, a sound setting, a vision system setting, or a brain-computer interface setting. The wireless remote control panel or the mobile terminal has a selection button on the annular recessed area or the recessed area's multi-segment filter key to select whether the light source within a single recessed area is powered on or off, or whether a brightness change program is running within a single recessed area segment.

[0047] The planar luminaire D01 contains light-isolating partitions D6, which separate one or more planar grid recessed areas D68, forming two or more planar overlapping layers D681. Annular recessed areas D69 overlap to form two or more annular overlapping layers D691. Each layer consists of multiple adjacent planar or annular recessed areas, or planar or annular recessed areas that are spaced apart or connected, or connected by power lines, PCB boards D21, or metal conductors D213, and light sources D3 combined to form an annular or elongated regular layer. The annular recessed areas D69 are divided into an inner annular layer D692, a middle annular layer D693, and an outer annular layer D694. The planar grid recessed areas D68 are divided into an inner planar layer D682, a middle planar layer D683, and an outer planar layer D684. Each luminaire has 1-1 billion layers, with the number of layers being the application quantity. Each layer has 1-100 million annular recessed areas. The recessed area can be isolated by a planar grid or a light isolation plate; each lamp has one or any number of layers as the application layers of the lamp of this invention. The number of each layer is not fixed and can be arranged in a single way or in various different shapes. The outer layer is adjacent to or spaced near the middle layer, and the middle layer is adjacent to or spaced near the inner layer. Each adjacent layer is enclosed in a planar shape or a three-dimensional shape, or the layers form a three-dimensional or planar shape; or each layer is a random layer without distinguishing between inner and outer layers. The light source is connected by a power line, PCB board or metal conductor and set in the recessed area D68 of the planar grid or the annular recessed area D69, D68. The recessed area grid forms a series of irregular connection layers. Each layer forms irregular layers with irregular intersections or irregular distances; the planar lamp D01 includes the recessed area segment D66 and multiple layers in the planar grid recessed area D68.

[0048] See Figures 1 to 10The diagram shows that the outer layer of the recessed area inside the lampshade is adjacent to the middle layer, and the middle layer of the recessed area is adjacent to the inner layer of the recessed area. Each adjacent layer forms a multi-recessed area lampshade, which constitutes a multi-angle light-emitting lamp 01 with selectable light-emitting angle. The working principle of the lamp is explained by the light source or the laser development system operating the brightness change program when the power is turned on. The control of the light source or laser development system inside the lamp is divided into single-layer and multi-layer recessed area light source control mode, ring single-layer and multi-layer recessed area light source control mode, recessed area segment light source control mode, and switch or control terminal control mode.

[0049] All light sources 3 or laser imaging heads 221 within the lampshade 5 structure of lamp fixture 01 are powered on and off via power data circuit 2, mechanical switch, control terminal, or remote control. Power data circuit 2 controls all light sources 3 or laser imaging heads 221 within the lampshade 5 structure to run a brightness change program. The control methods are: wired switch or control terminal connection; wireless remote control connection; virtual switch or control terminal formed by fonts, numbers, or icons on the interface of a mobile terminal connected via wireless signal; or the sound receiving module on the power data circuit receives a specific sound from the outside and then connects to control; or the visual system on the power data circuit receives a specific gesture or facial expression and then connects to control; or the brain-computer interface system on the power data circuit receives a thought signal from the brain-computer interface and then connects to control. The wired control is achieved by connecting the switch to the control terminal via wired connection. The power supply or data cable connects to the power data circuit on the lamp to control the light source and laser development system. The wired connection control terminal is a logically linked interface control terminal with physical buttons or a display control terminal with a display window, such as a PLC panel or a monitor panel. The wireless connection control uses the power data circuit to emit a wireless signal and connects with a mobile terminal or remote control using the same spectrum signal. The wireless signal can be Wi-Fi, Bluetooth, infrared light, ultrasound, or various high and low frequency radio frequency signals. One or more of these wireless signals are used together as the wireless connection signal in this invention. Alternatively, the light source or laser development system can be automatically controlled according to a programmed sequence to turn the light source power on and off, adjust the light intensity, change colors, and turn the laser development system power on and off, as well as select video, images, patterns, lines, and colors.

[0050] The microprocessor on the power data circuit 2 controls the light source 3, laser developing system 22, or laser developing head 221 within the lampshade 5. This is achieved by using an internally stored or externally implanted light change program. The light source 3, laser developing system 22, or laser developing head 221 are sequentially powered on, creating a multi-body concave area where the light source 3, laser developing system 22, or laser developing head 221 emits light and develops light in a strobe, continuous, or gradually brightening / dimming manner, forming a flowing or left-right stacking pattern. The light changes can be arranged in a series of patterns or images, including accumulation, flowing motion, intermittent jumping, back-and-forth running, short-duration flashing, snake-like movement, gradual brightening or dimming, letter combinations, or number combinations forming patterns or images. The brightness changes are programmed to control the sequence of light emission, power on / off, light intensity, color changes, and the power on / off of the laser developing system, as well as the transformation of images, patterns, lines, and colors. There are three automatic brightness change programs: 1. Horizontal brightness change program: Within the concave area, light source 51, light source 3, or laser developing system 22, or laser developing head 221 are arranged in pairs from left to right or from right to left. The left-hand light source 3, laser developing system 22, or laser developing head 221 in the concave area are switched on and off simultaneously according to the time difference, forming a time difference in the flashing of the light source, indicating movement or a queue arrangement. 2. The circumferential brightness change procedure is as follows: The light source 3, laser developing system 22, or laser developing head 221 in the concave area 51 flashes in a clockwise or counterclockwise circular motion according to the time difference, forming a rotation or... 3. Irregular brightness change program: The light source 3, laser developing system 22, or laser developing head 221 in the concave area 51 are powered on and off together in a horizontal brightness change program and a ring brightness change program, one to multiple layers, in sequence or out of sequence. The horizontal brightness change program and the ring brightness change program and the light source 3, laser developing system 22, or laser developing head 221 in all single-layer, multi-layer, single-row or multi-row concave areas are randomly arranged and switched on and off at different times without regard to the arrangement order.

[0051] The recessed space inside the lampshade 5 of the lamp fixture is divided into two or more recessed areas 51 by the vertical light partition 71, the horizontal light partition 73, or the irregular light partition. The recessed area 51 is a ring-shaped recessed area 52, a planar grid recessed area 53, a recessed area segment 54, or other geometric recessed areas 57, or a recessed area 58 without a light partition. The ring-shaped recessed area 52 or the planar grid recessed area 53 is a single-layer recessed area 511 and multiple layers of overlapping ring-shaped recessed areas 521, planar... The overlapping layers 531 and 58 are: a grid-recessed recessed area layer 531, a light-free partition recessed area layer 58, and a grid or annular recessed area overlapping layer 541; the annular recessed area of ​​the overlapping layer is further divided into annular overlapping inner layer 56A, annular overlapping middle layer 56B, and annular overlapping outer layer 56C; the grid recessed area of ​​the overlapping layer is further divided into overlapping planar grid overlapping inner layer 55A, planar grid overlapping middle layer 55B, and planar grid overlapping outer layer 55C; multiple light sources 3 or laser developing heads 221 on the PCB board 21 within the recessed area 51 constitute a single... Layer 59 forms a single inner layer 59A, a single middle layer 59B, a single outer layer 59C, or multiple single layers 59 overlapping to form an overlapping layer 590; the inner layer consists of one or more layers or vertically arranged side by side, the middle layer consists of one or more layers or vertically arranged side by side, and the outer layer consists of one or more layers or vertically arranged side by side; the annular concave area or planar grid concave area, the inner, middle, and outer layers, or the inner, middle, and outer layers of the light source or laser developing head, each layer consists of any number from 200 million to 100 million as the application quantity, ordered according to rules. The lampshade is composed of an inner, middle, or outer layer, or an irregular arrangement of single-layer concave areas. Multiple single-layer concave areas overlap to form a multi-body overlapping layer. A number of concave areas with single or multiple overlapping layers form a lampshade. Combined with other components, the lampshade 01 is a lamp fixture. The concave area 51 is formed by the light isolation plate 7 or by the lampshade's outer wall forming a concave area, making it an independent lampshade. The lampshade 5 is a long strip lampshade or a tubular open or closed hollow lampshade. The interior of the lampshade is divided into multiple concave area segments 54 by the light isolation plate 7. Figure 4 A, 4B, 4C) or no light isolation panel 7 isolation lampshade 5 ( Figure 4 D) Two or more lampshades 50 spaced apart, made of metal, plastic or wood, are connected in series to form a lamp fixture 01. Alternatively, they are connected in series with data cables, power cables or metal conductors 5A2 to form a lamp fixture 01 containing light sources or laser developing systems 22 or laser developing heads 221. The lamp fixture 01 contains multiple lampshades 5, and the light sources 3 or laser developing systems 22 or laser developing heads 221 operate a brightness change program and are controlled by a switch or control terminal to reduce or increase the number of light sources 3 or laser developing heads 221 within a single lampshade 5 or multiple lampshades. This reduction or increase in the number of light emitted or image displayed is either singular or collective. Figure 4The recessed area 58 of the square or elliptical light-free isolation plate 7 and the recessed area 57 of the light-free isolation plate are stacked to form an overlapping layer of lampshade 5 and lamp fixture 01. The recessed area 58 of the light-free isolation plate 7 may or may not have holes 581. The number of holes 581 is one or more. Each hole 581 contains a geometric developing body 8 or a lampshade 5. The geometric developing body 8 or lampshade 5 is a hollow body or a solid body containing a light source or laser developing head 22. The number of light sources 3 or laser developing systems 22 or laser developing heads 221 in the lampshade 5 is reduced or increased under the control of the brightness change program and the switch or control terminal. Figure 8 ); The concave areas 51 combine to form a grid of concave areas. A single layer of concave areas 511 forms a lampshade 5, or two or more single layers of concave areas 511 overlap to form a grid of concave areas. An overlapping layer of concave areas 531 forms a lampshade 5. Figure 9 A); Multiple or single-layer or multi-layer overlapping geometric recessed areas 57 are set within single-layer or multi-layer overlapping annular or grid recessed areas 52, 53 to form an independent lampshade with annular and planar grid 5( Figure 9 B); Multiple or single-layer or multi-layer overlapping annular recessed areas 52 are set within single-layer or multi-layer overlapping planar grid recessed areas 53 to form an independent lampshade 5( with annular and planar grids). Figure 9 C); Multiple recessed areas 58 without light-emitting partitions form lampshades 5A, which are combined in any number of rings, squares or other shapes to form a lamp fixture 01. The light source 3 or laser developing system 22 or laser developing head 221 inside the lamp fixture 01 lampshade 5 operates a brightness change program and is controlled by a switch or control terminal to reduce or increase the number of light source 3 or laser developing head 221 inside the lampshade 5. Figure 10C); Different shaped light partitions 7 isolate lampshades 5 into single-layer, double-layer, triple-layer, quadruple-layer, or five-layer or more overlapping recessed areas 521, 531. Each recessed area 51 is adjacent to or spaced apart from another recessed area 51, arranged in sequence to form a circle, square, rectangular, letter-shaped, font-shaped, animal-shaped, plant-shaped, household appliance-shaped, or other arbitrary geometric shape. Two or more independent recessed areas form a single-layer or overlapping layer. The light partitions 7 isolate the lampshades 5 into an inner layer of one or more adjacent bodies, a middle layer of one or more adjacent bodies, and an outer layer of one or more adjacent bodies. Each adjacent body is independently isolated and closely connected to form a single parallel layer or multiple adjacent bodies. The annular recessed area is divided into an inner annular layer, an inner annular layer, and an outer annular layer. The planar grid recessed area is divided into a planar inner layer, a planar middle layer, and a planar outer layer. The lamp has 1 to 1 billion layers as the application quantity; each layer has 1 to 100 million annular recessed areas, planar grid recessed areas, or light isolation plates to isolate recessed areas, arranged in a regular or irregular order to form a single layer; each lamp has one to any number of layers as the application layer of the lamp of the present invention, the number of each layer is not fixed, the outer layer is adjacent to or spaced from the middle layer, the middle layer is adjacent to or spaced from the inner layer, each layer is adjacent to each other and is enclosed in a planar shape or a three-dimensional shape, or the layers form a three-dimensional or planar shape; or each layer is a random layer without distinguishing between inner and outer layers, the light source is connected by power lines, PCB boards or metal conductors and set in the planar grid recessed areas or the annular recessed areas to form a series of irregular connection layers, and each layer forms an irregular layer with irregular intersections or irregular distances.

[0052] The lamp fixture 01 is composed of a single-layer multi-recessed hollow area 511, or multiple overlapping annular hollow area layers 521, or multiple overlapping planar grid hollow area layers 531, or multiple overlapping hollow area layers without light-emitting isolation plates 541 within the lamp shade 5. A microprocessor on a power data circuit 2 controls each hollow area 52, 53, 54, 57, 58 within each layer to run a brightness change program, power on / off, or display images / pictures. Alternatively, two or more layers of multi-recessed hollow areas 52, 53, 54, 57, 58, or overlapping layers 511, 521, 531, 541, each layer is coordinated and controlled by a microprocessor on a power data circuit 6. 57, 58 The light source 3 or laser developing system or laser developing head operates a brightness change program or power on / off or displays images / pictures; each layer or each overlapping layer is controlled by a microprocessor on a power data circuit 2 to operate independently, together, or in combination. A set of brightness change programs controls each layer. Each independent recessed area 52, 53, 54, 57, 58 The light source 3 or laser developing system or laser developing head operates a brightness change program or power on / off or displays images / pictures; Single-layer and multi-layer recessed area layers 52, 53, 54, 57, 58 are composed of multiple recessed areas. 58 or overlapping layers 521, 531, 541, each layer or each overlapping layer independently operates a set of brightness change programs to control the light source 3 or laser developing system 22 or laser developing head 221 in each independent concave area of ​​each layer to operate the brightness change program, or power on / off, or display images / pictures; or single layers and two to more layers together with overlapping layers form a multi-concave area layer, each layer and overlapping layers 511, 521, 531, 541 jointly operate a set of brightness change programs to control the light source or laser developing system or laser developing head in each independent concave area of ​​each layer to operate the brightness change program; or single layers and two to more layers together form a multi-concave area body, each layer jointly operate a set of brightness change programs to control the light source 3 or laser developing system 221 in each independent concave area of ​​each layer to operate the brightness change program. The laser developing system or laser developing head operates a brightness change program, or switches power on / off, or displays images or pictures; within the annular grid recessed area 52 and the planar grid recessed area 53, or within the recessed area segment 54 or other geometric recessed areas 57, or within the recessed area 58 of the light-free partition plate, each layer or each overlapping layer is controlled independently, together, or in combination by a microprocessor on one or more power data circuits 2. A set of brightness change programs controls the light source 3 or laser developing system 22 or laser developing head 221 within each independent recessed area 52, 53, 54, 57, 58 of each layer to operate a brightness change program, or switch power on / off, or display images or pictures; the microprocessor is linked to another microprocessor, transmits signals, and exchanges data via wired or wireless connection;The wireless connection can be Wi-Fi, Bluetooth, infrared light, ultrasound, or one or more high and low frequency radio frequency signals, or a combination of one or more wireless signals; the light source 3 is independently set in the recessed area 51, or together with the laser developing system 22 or the laser developing head 221, it is set in the recessed area 51 to emit light or display images or pictures.

[0053] The inner lampshade 5 of the lamp fixture 01 is composed of an inner ring layer 56A, a middle ring layer 56B, or an outer ring layer 56C within an inner ring concave region 52 and an overlapping layer 521. When the power is on, all light sources 3, laser developing system 22, or laser developing head 221 within the inner ring layer 56A, middle ring layer 56B, or outer ring layer 56C of the inner ring concave region 52 are constantly on and lit, or the inner ring layer 56A and middle ring layer 56B are constantly on and lit, while the outer ring layer 56C is not lit, or the inner ring layer 56A is constantly on and lit, while the middle ring layer 56B and outer ring layer 56C are not lit. Within the concave region 52, the light source 3 of the annular inner layer 56C, the laser developing system 22, or the laser developing head 221 operates a brightness change program, keeping the annular inner layer 56A and the annular middle layer 56B constantly lit; or, when the power is turned on, the light source 3 of the annular inner layer 56C and the annular middle layer 56B, the laser developing system 22, or the laser developing head 221 within the annular concave region 52 operates a brightness change program, keeping the annular inner layer 56A constantly lit; or, when the power is turned on, the light source 3 of the annular inner layer 56C and the annular middle layer 56B within the annular concave region 52, the annular inner layer 56A, or the laser developing head 221 ... System 22 or laser developing head 221 are in a continuously lit state. Then, the power is turned off, and within a 1-5 second time period, the power is turned on again, decreasing the power of light source 3 or laser developing system 22 or laser developing head 221 by one layer. Then, the power is turned off again, and within a 1-5 second time period, the power is turned on again, decreasing the power of light source 3 or laser developing system 22 or laser developing head 221 by one layer. Then, the power is turned on again, and all are continuously lit. Alternatively, the power is turned on to the inner ring layer 56C, middle ring layer 56B, and inner ring layer 56A in the annular concave area 52, using light source 3 or laser. The developing system 22 or the laser developing head 221 is in a continuously lit state. Then, the power is turned off and restarted within a 1-5 second range to decrease the light source 3 or the laser developing system 22 or the laser developing head 221 by one layer, running the brightness change program. Then, the power is turned off and restarted within a 2 second range to decrease the light source 3 or the laser developing system 22 or the laser developing head 221 by one layer, running the brightness change program. Then, the power is turned on again and all lights are continuously lit or all brightness change programs are running. The power can be started by a wired switch, a control terminal, or a remote wireless start.

[0054] The inner lampshade 5 of the lamp fixture 01 is composed of multiple planar grid recessed areas 51 or multiple recessed areas 512 or overlapping layers 531. The inner layer 55A of the planar grid is a light source or the inner layer 59A of the laser developing head, the middle layer 55B of the planar grid is a light source or the middle layer 59B of the laser developing head, and the middle layer 55C of the planar grid is a light source or the inner layer 59C of the laser developing head. When the power is turned on, all the light sources 3 or laser developing heads 221 within the inner layer 55A of the planar grid or the inner layer 59A of the laser developing head, the middle layer 55B of the planar grid or the middle layer 59B of the laser developing head, the inner layer 55C of the planar grid or the inner layer 59C of the laser developing head are present. The light source is always on and always lit; or when the power is on, the light source 55A in the inner layer of the planar grid or the light source 59A in the inner layer of the laser developing head, the light source 55B in the middle layer of the planar grid or all light sources 3 in the middle layer of the laser developing head 59B, or all light sources 221 in the laser developing head are always on and always lit, while the light source 55C in the inner layer of the planar grid or the light source 59C in the inner layer of the laser developing head is not lit; or when the power is on, the light source 55A in the inner layer of the planar grid or all light sources 3 in the inner layer of the laser developing head 59A, or all light sources 221 in the laser developing head are always on and always lit, while the light source 55B in the middle layer of the planar grid or the light source 55C in the inner layer of the planar grid or the light source 59C in the inner layer of the laser developing head is not lit. Figure 10 A) Then turn off the power and restart it within 2 seconds, decreasing the power of one layer of light source 3 or laser developing system 22 or laser developing head 221. Then turn off the power and restart it within 2 seconds, decreasing the power of one layer of light source 3 or laser developing head 221. Then turn on the power again, keeping all layers constantly on and lit; or turn on the power, and all light sources 3 or laser developing heads 221 within the inner layer 55A of the planar grid or the inner layer 59A of the laser developing head, the middle layer 55B of the planar grid or the middle layer 59B of the laser developing head, the inner layer 55C of the planar grid or the inner layer 59C of the laser developing head will run the brightness change program; or turn on the power, and all light sources 3 or laser developing heads 221 within the inner layer 55A of the planar grid or the inner layer 59A of the laser developing head, the middle layer 55B of the planar grid or the middle layer 59B of the laser developing head will run the brightness change program. The light source 55C or the inner layer 59C of the laser developing head is kept constantly on and lit; or, when the power is turned on, all light sources 3 or laser developing heads 221 within the inner layer 55A of the planar grid or the inner layer 59A of the laser developing head run the brightness change program, and all light sources 55B or the inner layer 59C of the planar grid or the inner layer 55C of the laser developing head run constantly on and lit; then, the power is turned off and restarted within a 2-second time range, decreasing the light source 3 or laser developing head 221 by one layer to run the brightness change program, changing to constant on and lit; then, the power is turned off and restarted within a 2-second time range, decreasing the light source 3 or laser developing system 22 or laser developing head 221 by one layer to run the brightness change program, changing to constant on and lit; then, the power is turned on again and all run the brightness change program; the power is started by a wired switch or control terminal or by remote wireless start; the recessed area 51 contains Figures 4 to 10 Diagram shown.

[0055] When the power to lamp 01 is first turned on via a wired connection using a switch or control terminal, all light sources 3, laser developing systems 22, or laser developing heads 221 within the annular recessed area 52, planar grid recessed area 53, recessed area segment 54, or other geometric recessed areas 57, or recessed areas without light-emitting partitions 58 of lamp 01, are continuously on and lit. The power is then cut off within 1-3 seconds and turned on again within 0.1-2 seconds. The number of light sources 3, laser developing systems 22, or laser developing heads 221 within the annular recessed area 52, planar grid recessed area 53, recessed area segment 54, or other geometric recessed areas 57, or recessed areas without light-emitting partitions 58 decreases as they gradually close. This continuous cycle of turning the power on and off within 0.1-2 seconds continues until only one light source remains. The light source 3, laser developing system 22, or laser developing head 221 within one or a group of annular recessed areas 52, planar grid recessed areas 53, recessed area segments 54, or other geometric recessed areas 57, or recessed areas without light-emitting partitions 58, are continuously on and lit, then the power is turned off and then on again, returning to the initial state; or the number of light sources 3, laser developing system 22, or laser developing head 221 within the annular recessed areas 52, planar grid recessed areas 53, recessed area segments 54, or other geometric recessed areas 57, or recessed areas without light-emitting partitions 58, is controlled to remain continuously on and lit, returning to the initial state; or the power is controlled incrementally by a switch or control terminal to control the number of light sources 3, laser developing system 22, or laser developing head 221 within the annular recessed areas 52, planar grid recessed areas 53, recessed area segments 54, or other geometric recessed areas 57, or recessed areas without light-emitting partitions 58, each time they are turned on.

[0056] When the power to lamp 01 is first switched on via wired connection using a switch or control terminal, all light sources 3, laser developing system 22, or laser developing head 221 within the annular recessed area 52, planar grid recessed area 53, recessed area segment 54, or other geometric recessed areas 57 or recessed areas without light-emitting partitions 58 of lamp 01 remain continuously on and lit. The power is then switched off again within 1-3 seconds, and then switched on again within 0.2-2 seconds three times consecutively, changing the operation to a brightness change program. The brightness change program runs automatically, executing all light and shadow change settings within the program. During the brightness change operation time, the power is switched off and then switched on again within 0.1 to... Within 1 second, the automatic operation changes to selecting a specific brightness change program. Power is then turned off and on again to switch to the next specific brightness change program. If the power is off for more than 5 seconds, all brightness change programs are turned off, and the microprocessor controls the brightness change programs to return to the initial always-on, always-on state. Power is then turned on again, returning to always-on, always-on state. The lamp controls the brightness change program's on / off state based on the power-off time. Alternatively, a switch or control terminal connected via wire can control the power on / off state in an incremental manner to control the light source 3, laser developing system 22, or laser developing head 221 to run brightness change programs and select specific programs.

[0057] When the power to lamp 01 is first turned on via a wired switch or control terminal, all light sources 3, laser developing systems 22, or laser developing heads 221 within the recessed area 54 of lamp 01 remain constantly on. Within 1-3 seconds, the power is then turned off, and within 0.1-2 seconds, the power is turned on again. Within the recessed area 54, the light sources 3, laser developing systems 22, or laser developing heads 221 within each segment decrease in number, becoming closed. This process is repeated continuously within 0.1-2 seconds, turning the power on and off. One or more light sources 3, laser developing systems 22, or laser developing heads 221 within the recessed area 54 are turned off, decreasing in number until only one light source 3, laser developing system 22, or laser developing head 221 remains constantly on. Then, the power is turned off again and turned on again, and all light sources 3, laser developing systems 22, or laser developing heads 221 within the recessed area 54 remain constantly on, returning to the initial state.

[0058] When the power to lamp 01 is first turned on via wired connection using a switch or control terminal, all light sources 3, laser developing systems 22, or laser developing heads 221 within the recessed area 54 of lamp 01 remain constantly on and lit. If the power is then cut off within 1-3 seconds and then turned on again 3 times within a 0.2-2 second timeframe, the system switches to a brightness change program. This program runs automatically, controlling all light and shadow changes within the program's parameters. If the power is cut off and then turned on again within 0.1-1 second during the brightness change period, the automatic operation switches to selecting a specific light source. The brightness change program, when the power is turned off and then on again, changes to the next specific brightness change program; if the power is off for more than 5 seconds, all brightness change programs are turned off, and the microprocessor controls the brightness change program to return to the initial long-on, long-bright state, and when the power is turned on, it returns to the long-on, long-bright state; the lamp controls the brightness change program to be turned on and off based on the length of time the power is off; or the switch or control terminal is wired connected to control the power to be turned on and off in an incremental manner to control the light source 3 or the laser developing system 22 or the laser developing head 221 to run the brightness change program and select a specific program.

[0059] When the power is turned on, the light sources in the multiple concave areas of layers one to five emit light simultaneously in a long-term, continuous on / off state. Then, the power is turned off and restarted within a 1-5 second period. The light sources in the multiple concave areas of layers two, three, four, five, and beyond then run a single or multiple different brightness change programs in sequence, automatically cycling through the changes. This process is repeated, with the power being turned off and restarted within a 2-second period. The number of layers with continuous, continuous on / off light increases by one, increasing to two. The number of layers running the brightness change program decreases by one until all layers with the brightness change program become continuously on / off. The power cycle is repeated again, with the number of layers increasing from one to five and beyond while the number of layers with the brightness change program decreases. This process of turning the power on and off is repeated. The number of layers continuously lit increases while the number of layers in the operating program decreases, repeating a cycle. Alternatively, the first time, layers one to five or more are continuously lit, then the power is cut off and turned on again, with the number of continuously lit layers decreasing and the number of light change program layers increasing, continuously repeating the cycle of turning the power on and off. Alternatively, after selecting the number of continuously lit layers and the number of light change program layers, the microprocessor on the power data circuit automatically records the selected number of layers and defines the number of layers to start the next power-on after 2-10 hours of power-on, instead of the initial power-on of five or more layers being continuously lit. The power data circuit has a storage power source to maintain the memory of the light change program and the continuous lit operation. The light source layers in the multiple concave areas within layers one to five or more can run different light change programs in an interleaved manner.

Claims

1. A multi-angle light-emitting lamp with selectable light-emitting angle, the lamp comprising a lamp holder structure, a power data circuit, a light source, a power inlet, a lampshade, a light-emitting partition, and a light-transmitting film to form a planar lamp; The lamp holder structure is composed of multiple shapes and components of arbitrary geometric shapes. The lamp holder structure is a rectangular frame structure with through holes or thin light-transmitting holes. The lamp holder structure is also a shape with one closed end and one recessed end, or one or more recessed or through holes, of any geometric shape. The light-transmitting film is tightly attached to the surface of the lamp holder structure. The lamp holder structure is an injection-molded body or a stamped metal sheet. The lamp holder structure may or may not have a light-transmitting geometric outline on or within the through holes. The lamp holder structure is circular, square, elliptical, or an irregular geometric shape with one closed, planar, recessed end. The light-transmitting plate is made of a long, translucent, opaque material composed of multiple connected long strips or other arbitrary geometric shapes, either strip-shaped or quincunx-shaped. The power data circuit contains various functional electronic components on its PCB board. These components include resistors, capacitors, microprocessors forming integrated circuits, diodes, transistors, rectifier bridges, miniature transformers, metal conductors, and may or may not include data storage modules, image output and display modules, laser image display systems, solar panels, energy storage batteries and circuits, and wireless receiving and output modules. The power data circuit has one or more PCB boards, each with multiple light sources. The PCB board can be circular, square, rectangular, cylindrical, or any other arbitrary geometric shape. Alternatively, the power data circuit may also include a laser developing system comprising a laser developing head, developing system, and electronic components. The source and the laser developing system or laser developing head are placed individually or together on the PCB board or the conductive metal conductor to obtain power for light emission or developing; the laser developing system can display images, pictures, logos, fonts, different light intensities and colors, geometric lines, and patterns; the light source or laser developing system is simultaneously set on the lamp fixture, or only an independent light source is set on the lamp fixture, or only an independent laser developing system or laser developing head is set on the lamp fixture; the laser developing system has one or more laser developing heads; the laser developing system or laser developing head is set inside or outside the lamp cover, or one or more units, and the laser developing head is controlled by data stored in the microprocessor or imported from the outside to project light, shadow, patterns, text, or trademarks onto the lamp fixture, the wall or ceiling of the fixed lamp fixture, or any object within the space of the fixed lamp fixture; The light source or laser developing head is placed or connected individually or in multiples on the PCB board or the metal conductor of the power data circuit to form a parallel power supply circuit, or multiple light sources are connected in series to form a series circuit, or multiple light sources are connected in a mixed series and parallel manner to form a current loop with the electronic components and microprocessor on the PCB board, forming a wired or remote control integrated control body; the PCB board body is adapted to the different shapes of the recessed space in the lampshade shape according to the size of the recessed space area; the power inlet is a conductive structure consisting of two cylindrical metal parallel conductive structures, a threaded conductive structure, a snap-on conductive structure, a plug conductive structure, or a power cord conductive structure to introduce high voltage and low voltage power to the lamp. The lampshade is provided with a light partition plate; the lampshade and the light partition plate are integrally injection molded structures; or the light partition plate is assembled outside the lampshade and then inserted into the lampshade to form an integral unit; the light partition plate is provided with a notch or through hole to accommodate the vertical light partition plate to form an assembly; the lampshade is composed of multiple concave areas separated by the light partition plate to form an arbitrary geometric shape; the light partition plate in the concave area is a single color or other different colors or a mixture of multiple different colors to form the concave area; one or more light partition plates of horizontal, vertical, circular or other arbitrary geometric shapes are placed at intervals inside the lampshade to separate the lampshade into two or more concave areas. Up to multiple layers; different shaped light partitions isolate lampshades of different shapes into single-layer, double-layer, triple-layer, quadruple-layer, five-layer, or more overlapping recessed areas; each recessed area is adjacent to or spaced apart from another recessed area and arranged in sequence to form a circle, square, strip, letter, font, animal, plant, household appliance, or other arbitrary geometric shape. Two or more independent recessed areas constitute a shape forming a single-layer or multi-layer overlapping layer; the surface of the lampshade is provided with one or more concave and convex shapes forming a font, letter, number, logo, animal graphic, human portrait, marine fish, flower, plant, mountain and river, celestial body, aircraft, or motor vehicle shape pattern. Each of the light-emitting partition plates is equipped with a light source or laser developing head within the recessed area or segment of the recessed area. The light source or laser developing head is located adjacent to the surface of the light-emitting partition plate, or is located within the recessed area or segment of the recessed area of ​​the light-emitting partition plate, or is located within the recessed area or segment of the recessed area on the PCB board to emit light or develop light. The light emitted by the light source within the recessed area cannot directly shine on or be reflected into another recessed area segment isolated by the horizontal light-emitting partition plate or into the recessed area of ​​the vertical light-emitting partition plate. The lampshade is a circular hollow structure, a square hollow structure, an elliptical hollow structure, or any other geometric shape; or one end of the lampshade is a smooth tube and the middle part is an irregular geometric shape; the lampshade has one or more spiral threads or concave long strip through holes inside or outside the concave hollow port, or multiple arc-shaped long strip convex or concave ribs. A light-transmitting plate is installed inside the lamp holder structure and is glued or fastened to the lamp holder structure via a through-hole surface. The power data circuit and the PCB board with a multi-body light source or laser imaging system are installed and fixed inside the lamp holder structure. The power inlet is connected to the power input end of the PCB board to introduce power. The lampshade has one or more spiral threads or recessed elongated through-holes, or arc-shaped convex or concave ribs that match the spiral threads or recessed elongated through-holes or arc-shaped convex or concave ribs on the lamp holder structure. They are combined in a spiral or snap-fit ​​manner, or glued together or embedded inside and outside to fix them. The lamp holder structure or the lampshade may or may not have a light-transmitting body installed in the holes. The lamp holder structure, the power data circuit, the PCB board, the light source and laser developing system, the lampshade, the power inlet or the light-transmitting body or the laser developing system are combined to form a complete lamp. When the power is turned on, the light source emits light or the laser developing system projects images, pictures, or geometric lines through the light emitted by the light source. The light source or laser developing system may be simultaneously installed on the lamp, or only the light source may be installed on the lamp, or only the laser developing system may be installed on the lamp. The light source or laser developing system may be simultaneously installed on the lampshade, or only an independent light source may be installed on the lampshade, or only an independent laser developing system may be installed on the lampshade. The laser developing system has one or more laser developing heads. The lampshade is provided with a single horizontal light isolation plate to divide the lampshade into two or more adjacent and connected recessed areas; the lampshade is provided with horizontal and vertical light isolation plates to divide the lampshade into two or more annular recessed areas and two or more adjacent and connected recessed areas; no light isolation plate is provided in the recessed areas of the lampshade, and a light source or laser developing head is provided in the recessed areas to run a brightness change program or to control the number of times the light source or laser developing head is turned on or off by selecting the number of times. The opening of the lampshade with the light-emitting partition plate is parallel to or in contact with the surface of the PCB board. The "micro-distance" refers to the position where the light source or the laser developing head of the laser developing system enters the lampshade or the surface of the light-emitting partition plate. The distance between the plane of the light-emitting partition plate and the laser developing head of the light source or laser developing system is between -200 mm and +20 mm. Preferably, the distance is such that the laser developing head of the light source or laser developing system enters the plane area of ​​the light-emitting partition plate at a negative distance. The laser developing head on the light source or laser developing system on the PCB board has its glossy surface facing the lampshade cavity surface; the number of laser developing heads on the light source or laser developing system on the PCB board is two or more. The PCB board shape is matched with the lampshade shape; or a power data circuit is provided with multiple long strip PCB boards with light sources or laser developing heads; the laser developing head is set on the light partition plate or on the lamp structure, and the distance between the laser developing head and the light partition plate is 5-500cm, which is the application distance. Multiple elongated PCBs are connected in parallel or in series with metal conductors for power supply; multiple elongated PCBs are placed directly on the lampshade with light spacers isolating each recessed area for light emission; or one or more light sources are provided on a power data circuit, which are welded together with metal conductors to form a series circuit light source or a parallel circuit light source; the series circuit light source or parallel circuit light source welded together with metal conductors is placed in the recessed area isolated by each light spacer for light emission as required; the lampshade of the planar lamp is made by vacuum forming or injection molding; the middle surface of the lampshade of the planar lamp is a three-dimensional line or shape, which may be flat or concave-convex, in the shape of an animal, human, flower, plant, aircraft, vehicle, or flower, and may be decorated with matching colors or not. Light emitted by a light source entering the recessed area isolated by the light partition within the lampshade will not directly or reflect into another recessed area isolated by the light partition; individual or multiple light sources entering the recessed area isolated by the light partition within the lampshade can be independently switched on / off or run a brightness change program under the control of the microprocessor; or controlled together with one or more other individual or multiple light sources within the recessed areas isolated by the light partition; the lampshade is a single-layer or multi-layer trapezoidal shape, and the trapezoidal or single-layer lampshade may or may not have concave-convex three-dimensional lines or shapes. The light emitted by the laser developing head of the light source or laser developing system in the recessed area of ​​the lampshade isolated by the light partition is projected onto the six viewing surfaces of the recessed area of ​​the lampshade isolated by the light partition, with only one viewing surface being able to transmit light. The light emitted by the laser developing head on the light source or laser developing system is projected onto the six viewing surfaces of the recessed area inside the lampshade of the light partition plate, so that only any two viewing surfaces can transmit light. The light emitted by the laser developing head of the light source or laser developing system in the recessed area of ​​the lampshade of the light partition plate is projected onto the six viewing surfaces of the recessed area of ​​the lampshade of the light partition plate, and only any three viewing surfaces can transmit light. The light emitted from the laser developing head of the light source or laser developing system within the recessed area of ​​the lampshade isolated by the light partition is projected onto the six viewing surfaces of the recessed area isolated by the light partition, allowing light to pass through only any four or five of the viewing surfaces; one or more light-transmitting bodies are provided on the light-transmitting surface of the recessed area, or none are provided; each light-transmitting body can only receive light transmitted from one light-transmitting viewing surface; the light-transmitting body is located on the surface of the recessed area of ​​the lampshade, or within a hole on the surface, or within a hole in the lamp holder structure. The planar luminaire with a light-isolating partition may or may not contain liquid; the lamp holder structure or lampshade structure containing the liquid is equipped with a sealing cap and glue to seal the liquid and prevent leakage; the lampshade of the planar luminaire with a light-isolating partition may or may not contain a laser developing system, and an electronic component matching the laser developing system is compatible with the system; the lampshade with a light-isolating partition may or may not contain a light-transmitting body; the planar grid recessed area or the annular recessed area or the recessed area without a light-isolating partition in the planar luminaire contains a recessed area segment or a single annular planar layer or a planar grid layer or an annular planar overlapping layer or a planar grid overlapping layer or a recessed area layer without a light-isolating partition; the annular planar layer or the planar grid layer or the annular The overlapping layers consist of planar overlapping layers, planar grid overlapping layers, or recessed areas without light-emitting partitions, with one side of each layer overlapping adjacently or at a distance. These overlapping layers are connected by metal conductors, power lines, data lines, or geometric structures smaller or larger than the lampshade. Within these geometric structures, metal conductors, power lines, or data lines connect the upper and lower layers, outputting power or data to the light source or laser developing system to control the light source or laser developing head's brightness variation program. The laser developing system or laser developing head is located inside or outside the lampshade, or one or more independently located at any part of the lamp. Data stored in the microprocessor or imported from the outside controls the laser developing head to project light, shadows, patterns, text, or trademarks onto the lamp's shape, the wall or ceiling of the fixed lamp, or any object within the space of the fixed lamp. The luminaire controls the on / off and program selection of the light source or laser developing system by controlling the duration of power-off; the luminaire controls the number of light sources or laser developing heads turned on within the recessed area by controlling the duration and number of power-off cycles; the power or data remote control of the light source or laser developing head within each recessed area of ​​the flexible luminaire is independently controlled by the microprocessor, while wired connection control is jointly controlled by the switch and the microprocessor; the light source selection within each annular recessed area or the transverse light partition isolates the recessed area, allowing selection of different annular recesses via wired or wireless methods. Within an empty area or a horizontal light partition, the light source or laser imaging system within the concave area is isolated. The system can be turned on or off, and the number of light sources or laser imaging systems within the concave area or the number of concave area segments activated each time can be set via a switch, control terminal, wireless remote control, mobile terminal, sound, vision system, or brain-computer interface. The wireless remote control panel or mobile terminal is equipped with a concave area or a multi-segment filter key to select whether the light source within each concave area is powered on, the current is specified, or the power is turned on, the current is turned off, or a brightness change program is running. The wireless remote control device is a button-operated wireless remote control or a mobile terminal. This device can simultaneously control the laser developing system or laser developing head and light source on the lamp, including turning them on and off, adjusting current levels, selecting light source operating programs, setting programs, turning the light source on and off within an angle, turning segment light sources on and off, adjusting and selecting light source colors, importing new programs, controlling the display interface, and storing and deleting images on the microprocessor's storage module, selecting laser video / images, adjusting the clarity of laser video / images, importing laser images, importing videos or images from the internet or mobile network, adjusting the clarity of laser images, importing external video / images, importing television signals, and controlling the light source. The system includes functions for setting and starting the source timing, audio pitch and range adjustment, audio on / off, light source intensity, and wireless connection to the remote control device. It connects to the power and data circuit via one or more wireless signals (Wi-Fi, Bluetooth, infrared, ultrasonic, or radio frequency) at the same frequency to form a connection control. A single wireless remote control or mobile terminal can simultaneously control all light sources within a single lamp or multiple lamps, as well as all functional applications on the laser developing system. A setting panel or LCD control panel on the wireless remote control, mobile terminal, or lamp structure can simultaneously control the operation of the light source and the laser developing system or laser developing head.

2. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The outer layer of the recessed area in the lampshade is adjacent to the middle layer, and the middle layer of the recessed area is adjacent to the middle layer of the recessed area. Each layer is adjacent to form a lampshade with multiple recessed areas, which constitutes a lamp with multi-angle light emission and selectable light emission angle. All light sources or laser developing heads within the lampshade structure of the lamp fixture are powered on and off via a power data circuit, mechanical switch, control terminal, or remote control. The power data circuit controls the brightness change program of all light sources or laser developing heads within the lampshade structure. The control method is: wired switch or control terminal for on / off control; or wireless remote control for remote control. The recessed space within the lampshade of the lamp fixture is divided into two or more recessed areas by vertical light partitions, horizontal light partitions, or irregularly shaped light partitions. The recessed areas are annular recessed areas, planar grid recessed areas, recessed area segments, or other geometric recessed areas, or recessed areas without light partitions. The annular recessed areas or planar grid recessed areas are single-layer recessed areas and multi-layer overlapping annular recessed areas, or overlapping layers of planar grid recessed areas, or overlapping layers of recessed areas without light partitions and grid or annular recessed areas. The overlapping annular recessed areas are further divided into annular overlapping inner layers, annular... Overlapping middle layer, ring-shaped overlapping outer layer; the overlapping layer grid concave area is further divided into overlapping planar grid overlapping inner layer, planar grid overlapping middle layer, and planar grid overlapping outer layer; multiple light sources or laser developing heads on the PCB board in the concave area form a single layer, forming a single inner layer, a single middle layer, a single outer layer, or multiple single layers overlapping to form an overlapping layer; the inner layer is composed of one or more layers or vertically arranged side by side, the middle layer is composed of one or more layers or vertically arranged side by side, and the outer layer is composed of one or more layers or vertically arranged side by side; the ring-shaped concave area or the planar grid concave area inner layer, middle layer, outer layer or the light source or laser developing head inner layer, middle layer, outer layer, each layer is composed of any number within 2 to 100 million as the application quantity, arranged in a regular or irregular order to form each single inner layer, middle layer or outer layer; multiple single concave areas overlap to form a multi-body overlapping layer; multiple concave areas with one or more or more single or multiple overlapping layers form a lampshade and combine with other components to form a lamp.

3. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The recessed area is formed by the isolation of the light-emitting partition or by the recessed area itself on the outer wall of the lampshade, making it an independent lampshade. The lampshade is a long strip lampshade or a tubular open or closed hollow lampshade. The interior of the lampshade is divided into multiple recessed areas by the light-emitting partition, or the lampshade is not isolated by the light-emitting partition. Two or more lampshades are connected in series by a structure to form a lamp fixture, or the light source or laser developing system or laser developing head inside the lampshade is connected in series by a data cable, power cable, or metal conductor to form a lamp fixture. The light source or laser developing system or laser developing head inside the lampshade operates a brightness change program and is controlled by a switch or control terminal to reduce or increase the number of light sources or laser developing heads in a single lampshade or multiple lampshades, either individually or together, to reduce or increase the number of light sources or image displays. The recessed area without light-emitting partition is a square or oval shape without a light-emitting partition and is related to the light source. The isolation plates isolate geometrically recessed areas to form overlapping lampshades and lamps. The recessed areas of the isolation plates without light may or may not have holes, with one or more holes in total. Each hole contains a geometric developing body or lampshade. The geometric developing body or lampshade is either hollow or solid, containing a light source or laser developing head. The number of light sources or laser developing heads inside the lampshade is increased or decreased under the control of a brightness change program and a switch or control terminal. The recessed areas can be combined to form a grid-like recessed area lampshade, or two or more single-layer recessed areas can be overlapped to form an overlapping grid-like recessed area lampshade. Multiple or single-layer or multi-layer overlapping geometrically recessed areas can be set within a single-layer or multi-layer overlapping annular or grid-like recessed area to form an independent lampshade with annular and planar grids. Multiple or single-layer or multi-layer overlapping annular recessed areas are set within single-layer or multi-layer overlapping planar grid recessed areas to form an independent lampshade with annular and planar grids; Multiple recessed areas without light-emitting partitions form a lampshade, and any number of such areas can be combined in a ring, square, or other shape to form a lamp fixture. The light source, laser developing system, or laser developing head inside the lampshade operates a brightness change program and is controlled by a switch or control terminal to increase or decrease the number of light sources or laser developing heads within the lampshade. Different shaped light-emitting partitions separate lampshades of different shapes into single, double, triple, quadruple, five, or more overlapping recessed areas. Each recessed area is adjacent to or spaced apart from another recessed area, arranged sequentially in a circular, square, rectangular, letter, font, animal, plant, household appliance, or other arbitrary geometric shape. Two or more independent recessed areas form a single or overlapping layer. Each layer consists of multiple planar or ring-shaped recessed areas that are adjacent or spaced apart, or connected by a distance between the ring-shaped recessed areas, or connected by a distance between the recessed areas, or connected by a power line, PCB board, or metal conductor to the light source, laser developing system, or laser developing head combination. Multiple components together form a ring-shaped regular layer or a long strip-shaped regular layer. The ring-shaped concave area is divided into an inner ring layer, a middle ring layer, and an outer ring layer. The planar grid concave area is divided into a planar inner layer, a planar middle layer, and a planar outer layer. Each lamp has 1 to 1 billion layers, which is the number of application layers. Each layer has 1 to 100 million ring-shaped concave areas, planar grid concave areas, or light isolation plates that isolate concave areas. Each lamp has one to any number of layers as the application layer of this invention. The number of each layer is not fixed. The outer layer is adjacent to or spaced from the middle layer, and the middle layer is adjacent to the inner layer. Each layer is adjacent and enclosed in a planar shape or a three-dimensional shape, or the layers form a three-dimensional or planar shape. Alternatively, each layer is a random layer without inner or outer layers. The light source is connected by power lines, PCB boards, or metal conductors and set in the planar grid concave area or the ring-shaped concave area. The concave area grid forms a series of irregularly connected layers. Each layer forms irregular layers with irregular intersections or irregular distances. The concave area of ​​each layer is set with a light source or a laser developing head.

4. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The microprocessor on the power data circuit controls the light source, laser developing system, or laser developing head inside the lampshade to run the light change program in sequence by internally storing the light change program or externally implanting the light change program. The light change program has three configuration methods:

1. Horizontal light change program: The light source, laser developing system, or laser developing head in the concave area or layer is turned on in a row from left to right or from right to left according to the time difference, forming a time difference light source flashing to form movement or in a queue, or the light source, laser developing system, or laser developing head in the concave area or layer together performs power switching or current change and color change.

2. The circumferential brightness change program is as follows: within the concave area or layer, the light source, laser developing system, or laser developing head forms a time difference by flashing in a clockwise or counterclockwise circular pattern, creating a rotating or circular arrangement. Alternatively, the light source, laser developing system, or laser developing head within the concave area or layer may simultaneously switch on / off power or change current levels and color.

3. The irregular brightness change program is as follows: within the concave area or layer, the light source, laser developing system, or laser developing head operates in a cross-sectional manner with one or more layers of lateral and circumferential brightness change programs, either sequentially or irregularly. All single or multiple overlapping layers or single or multiple rows of light source, laser developing system, or laser developing head within the concave area are randomly arranged without regard to arrangement order, switching on / off power or changing current levels and color. The concave area segment is any combination of two or more adjacent concave areas forming an open or closed concave area. The recessed area segment is defined as a light source, laser developing system, or laser developing head connected in series with a conductive material, wire, or data cable within each combined shape of the lamp fixture. The light source or laser developing head emits light in sequence or at intervals within the recessed area, controlled by a microprocessor. This light change is achieved through stacking, flowing stacking, left-right running stacking, flowing running, intermittent jumping, left-right back-and-forth running, short-duration flashing, snake-like movement, gradual brightening or dimming, moving trails, letter combinations, or number combinations. Multiple light sources or laser developing heads emit light in an arranged sequence or simultaneously. These simultaneous flashes or continuous appearances form three-dimensional or two-dimensional circular, square, rectangular, letter-shaped, font-shaped, animal-shaped, plant-shaped, household appliance-shaped, human-shaped, flower-shaped, vehicle-shaped, aircraft-shaped, human-shaped, marine fish-shaped, or geometric patterns. One or more different types of patterns appear together within or outside the recessed area.

5. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The vertical light partition isolates two or more annular grid recessed areas, or isolates light sources or laser developing heads in recessed areas without a light partition. The power is turned on for the first time by a switch, control terminal, or remote control. All light sources or laser developing heads in the annular grid recessed areas or recessed areas without a light partition are kept on and lit for 1-3 seconds. The power is then turned off and turned on again within 0.1 to 2 seconds. The light sources or laser developing heads in the annular grid recessed areas or recessed areas without a light partition are turned off and closed in descending order of an angle. Each time the power is continuously turned on and off within a range of 0.1 to 2 seconds, the light source or laser developing head gradually shuts down one ring-shaped recessed area or an area isolated by a light-free isolation plate until only one light source in the last angle remains constantly lit. Each time the power is continuously turned on and off within a range of 0.1 to 2 seconds, the light source or laser developing head gradually shuts down one light source or laser developing head on one surface of the elongated, ring-shaped, or planar PCB board within the recessed area until only one light source or laser developing head on the last elongated or ring-shaped PCB board remains constantly lit. Then the power is turned off and restarted, and all light sources or laser developing heads remain constantly lit, returning to the initial state. When the power to the light source or laser developing head is turned on, all light sources or laser developing heads in the ring-shaped grid recessed areas or areas isolated by a light-free isolation plate remain constantly lit for 1-3 seconds. Within a few seconds, if the power is cut off and then switched on three times within a time range of 0.2 to 2 seconds, the brightness change program will be activated. The brightness change program will run all the light and shadow change settings in the program automatically. If the power is cut off and switched on again within a time range of 0.1 to 1 second during the brightness change operation of the light source or laser developing head, the automatic operation will switch to running a specific brightness change program. If the power is turned off and then on again, the next specific brightness change program will be selected. If the power is off for more than 5 seconds, all brightness change programs will be turned off. The microprocessor controls the brightness change program to return to the initial long-on and long-bright state. When the power is turned on, it will return to the long-on and long-bright state. The lampshade controls the opening and closing of the brightness change program based on the length of time the power is off. The number of light sources on the long strip PCB board in the recessed area will be reduced in sequence or at intervals.

6. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that... The lampshade is separated into two or more recessed sections by horizontal light partitions. All light sources or laser developing heads within these sections are controlled by a switch, control terminal, or remote control. Upon initial power-on, all light sources in the recessed sections remain continuously lit for 1-3 seconds. Power is then cut off and re-energized within a 0.1-2 second timeframe. Within each recessed section, one light source or laser developing head is deactivated, or one or more light sources or laser developing heads are deactivated, creating a continuous shutdown. This power-on and shutdown cycle repeats continuously within a 0.1-2 second timeframe. The process continues until only one light source or laser developing head remains continuously lit, or until all light sources or laser developing heads are deactivated. Until only one or a few light sources or laser developing heads remain continuously lit, the power is turned off and then restarted, returning all light sources or laser developing heads to a continuous, lit state, returning to the initial state. If the power to the light sources or laser developing heads is switched on for 1-3 seconds within the recessed area, and then the power is switched off again within 0.2-2 seconds, and then switched on three times consecutively, the system switches to a brightness change program. The brightness change program runs automatically, executing all brightness change parameters within the set parameters. During the brightness change period of the lampshade, if the power is switched off and then switched on again within 0.1-1 seconds, the automatic operation switches to selecting a specific brightness change program. Switching to the next specific brightness change program involves switching back to the previous one after switching off and then on again. If the power is off for more than 5 seconds, all brightness change programs are switched off, and the microprocessor-controlled brightness change program returns to the initial continuous, lit state. Switching back to continuous, lit state upon power-on again completes the process.

7. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The light source or laser developing head on the circular PCB board is distributed in one or more groups within an angular region or geometric region, and then repeated in two or more angular regions or geometric regions on the PCB board; the angular region or geometric region of the light source or laser developing head matches the angle and geometry of the recessed area isolated by the light partition plate inside the lampshade; the lamp holder structure is a circular cavity structure, a square cavity structure, an elliptical cavity structure, or other arbitrary geometric structure. The lamp holder structure may be a smooth tube at one end and an irregularly shaped geometric structure in the middle; the lampshade may have one or more spiral threads or long, recessed through holes inside or outside the recessed port, or multiple convex or concave ribs in the shape of arcs; the lamp holder structure may have through holes for light transmission, and a light-transmitting film may be provided inside or on the outer surface of the through holes; the recessed area on the lampshade may be a closed recessed area or a recessed area with an open opening, with one side of the open recessed area on the lampshade; the lampshade may have closed or open recessed areas. The area contains geometrically open or closed structures that match the concave shape. One or more open or closed structures are placed within the concave area of ​​the lampshade. The geometrically open or closed structures are made of any color. A single body of the same color is placed within the concave area, or multiple bodies of different colors are placed within the concave area to form geometrically open structures of different colors. The shape of the geometrically open structure can be that of a land animal, an insect, a marine animal, an aircraft, a motor vehicle, a plant, a flower, a mountain or river, a celestial body, or an ocean or ship. The concave area of ​​the lampshade, separated by a light partition of any geometric shape, is of any geometric shape. One or more light sources or laser developing heads are placed inside the hollow or solid geometrically open or closed structures. The light sources or laser developing heads in the geometrically open or closed structures are connected to one or more other light sources or laser developing heads via power lines and data lines, and then connected to a microprocessor to transmit data or form control.

8. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The laser developing system is equipped with one or more laser developing heads, spaced at single-row, circular, or square grid intervals, to project and display images, videos, pictures, logos, fonts, lights of different intensities and colors, geometric lines, and patterns onto a PCB board, lamp holder structure, lamp, or light partition plate. The images are displayed in the recessed area inside the lampshade or on the outer surface of the lampshade. One laser developing system may have multiple laser developing heads displaying a single image together, or each laser developing head may display a single image. Each laser developing head projects, reflects, or refracts light within the recessed areas isolated by vertical or horizontal light partitions, on the surface of the lamp, on the wall or wall where the lamp is fixed, on the fabric around the lamp, or on the lamp structure. One laser developing head on the laser developing system displays an image. Multiple independent images are isolated by geometric shapes and projected onto the recessed areas isolated by vertical or horizontal light partitions, or onto the surface of the shapes; or multiple laser developing heads are mounted on the laser developing system, each laser developing head positioned within the recessed areas isolated by vertical or horizontal light partitions, or onto the surface of the shapes, the lamp holder structure, or the lampshade; the laser developing heads are mounted on the PCB board or on the horizontal or vertical light partitions; the light emitted from the laser developing heads travels from a first position on the elongated PCB board to a second position on the inner wall of the lampshade area isolated by the light partitions, and then is transmitted to the outer wall of the lampshade at a third position, scattering into the space; the light emitted from the laser developing heads inside the lampshade is projected onto the lampshade to form clear light and shadow lines and high and low light intensity contrast, with a high and low light intensity contrast ratio of 0.1-0.The light intensity and contrast ratio vary within any range of 7. Within the lampshade, in two or more recessed areas, or within annular recessed areas, or within horizontally isolated recessed areas, or within recessed areas isolated by no light-emitting isolation plates, the light source or laser developing head is directly connected or disconnected via a mechanical switch or control terminal. This allows selection of whether the light source or laser developing system or laser developing head in each recessed area is turned on simultaneously or selectively turned on in specific recessed areas. The laser developing system body is equipped with one or more laser developing heads arranged on the PCB board in single-row long strip intervals, annular intervals, square grid intervals, or any geometric shape for projection display. The display includes images, pictures, logos, fonts, different light intensities and colors, geometric lines, and patterns, either inside or outside the lampshade. The laser developing system displays images isolated from each other, mapped together by multiple independent images, or by multiple laser developing heads arranged side-by-side at intervals, or in multiple rings, rhombuses, or triangles, mapping all vertically isolated concave areas, or horizontally isolated concave areas, or on surfaces, walls, canvases, translucent cloths, laser developing cloths, transparent reflective materials, lamp structures, LCD screens, or OLED screens. The images mapped by the laser developing heads are either edge-overlapping or edge-aligned. The mapping surfaces are spaced apart, or one or more laser developing heads are interleaved to project light and shadow images, creating an embedded image; or the laser developing system has multiple laser developing heads, each positioned within a vertically isolated recessed area for developing, or a horizontal light partition separating the recessed area for developing, or no light partition separating the recessed area for developing; the laser developing system includes one or more laser developing heads, and one laser developing system drives multiple laser developing heads to develop simultaneously. The laser developing heads transmit digital image data or analog signal data via metal conductors or data lines, and are controlled by electronic components and actuators within the laser developing heads. In a laser developing system, light emitted from one or more laser developing heads is directly transmitted to the mirror surface of one or more laser developing heads, where it is refracted, directly incident, reflected, refracted, magnified, and projected onto the surface of a lampshade, wall, display screen, curtain, transparent reflector, lamp structure, or any other object for development. The transmission of light signals from one laser developing head to another in the laser developing system can be done remotely in a vacuum, through air, via transparent fiber optic cable, via a protected outer sheath, via a concave cavity, or within a concave cavity. The laser developing system can also transmit light and shadow simultaneously from one developing head to multiple laser developing heads or transmit light and shadow one-to-one.

9. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The lamp housing contains single-layer multi-recessed areas, two to five or more layers of multi-recessed areas, and multiple overlapping annular recessed areas. Each layer is controlled by a microprocessor on a power data circuit, or multiple microprocessors on a power data circuit control one or more light sources, laser developing systems, or laser developing heads within each layer or recessed area to run a brightness change program, power on / off, or display images / pictures. Alternatively, each of two to more layers of multi-recessed areas or overlapping layers is coordinated and controlled by a microprocessor on a power data circuit to run a brightness change program, power on / off, or display images / pictures within each layer or recessed area. Each layer or overlapping layer of the annular grid recessed area and the planar grid recessed area is controlled by a microprocessor on a power data circuit to operate independently, together, or in combination, using a set of brightness change programs to control one or more light sources or laser developing systems within each independent recessed area. The imaging system or the laser developing head operates a brightness change program, or switches power on / off, or displays images or pictures; each layer or each overlapping layer of the annular grid recessed area and the planar grid recessed area, or the recessed area without light isolation plate, is controlled independently, together, or in combination by one or more microprocessors on the power and data circuits. A set of brightness change programs controls the light source or laser developing system or laser developing head in each independent recessed area of ​​each layer to operate the brightness change program, or switch power on / off, or display images or pictures; the microprocessor is linked to another microprocessor, transmits signals, and exchanges data via wired or wireless connection; the wireless connection is Wi-Fi, Bluetooth, infrared light, ultrasound, or various high and low frequency radio frequency signals, one or more of one or more wireless signals combined as a wireless connection method; the light source is independently set in the recessed area, or together with the laser developing system or laser developing head set in all recessed areas or externally to emit light or display images or pictures.

10. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The light source or laser developing head in the lamp fixture is always on and always lit. The number of light sources, laser developing systems, or laser developing heads activated, the different angles of light sources or laser developing heads, different colors, color temperatures, on / off timings, brightness changes, video, images, patterns, and geometric lines are all set by the microprocessor in the power data circuit using a memory circuit or internal energy storage battery. Each time the lamp is turned on again, the stored parameters are used as the initial startup parameters. The PCB board is composed of three layers of substrate material: an aluminum sheet substrate layer, a thermally conductive insulating layer, and a copper foil substrate layer, all overlapped and bonded together with adhesive. Alternatively, the PCB board can also be composed of three layers of substrate material: an aluminum sheet substrate layer, a thermally conductive insulating layer, and an aluminum sheet substrate layer, all overlapped and bonded together with adhesive. The PCB board can be configured as follows: A single or multiple copper, aluminum, or iron metal wires are laid together in a U-shaped groove on the aluminum substrate layer and secured by the left and right sides of the U-shaped groove, or glued and bonded within the U-shaped groove; or the metal wires are placed on the aluminum substrate layer and glued to form the application substrate. Alternatively, the PCB board can be configured as follows: A single or multiple copper, aluminum, or iron metal wires are laid together in a U-shaped groove on the plastic substrate layer and secured by the left and right sides of the U-shaped groove, or glued and bonded within the U-shaped groove; or the metal wires are placed on the plastic substrate layer and glued to form the application substrate. The metal wires are round, elliptical, or sheet-shaped, and the aluminum plate and plastic sheet are the application components of the PCB board of this invention.

11. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The mobile terminal, remote control, or control panel on the lighting fixture can simultaneously control the light source, laser developing system, or laser developing head to turn on and off as needed, select functions, control the number of laser developing heads or light sources to turn on and off each time, or run brightness change programs or select parameters for brightness change programs. The mobile terminal has a display interface with virtual buttons, physical buttons, and various parameter function selection interfaces. The parameter interface includes functions for controlling light source number, light source naming, full or partial on / off, timing, brightness adjustment, automatic program operation selection, on / off of light sources within an angle, on / off of segment light sources, light source color adjustment and selection, specific program selection, program forward selection, program backward selection, single light source selection, automatic parameter memory function, simultaneous operation of multiple different independent light source numbers in a network, and light source operation signal display interface controlled simultaneously with text, icons, and virtual buttons. The display interface includes virtual buttons and various parameter function selection interfaces. The parameter interface controls the on / off state of the laser developing system or laser developing head, and the number of laser developing systems or laser developing heads. The system includes functions for selecting and storing video, importing video, selecting images, inputting images, setting data parameters, selecting light intensity, importing external TV signals, setting audio pitch, turning audio on / off, displaying and selecting wireless signal connections, controlling a single laser developing head interface, setting a single laser developing head, setting simultaneous display of multiple laser developing heads, selecting video sources for a single laser developing head, selecting video sources for multiple laser developing heads, setting text display for a laser developing head, setting color display for a laser developing head, setting image display for a laser developing head, and setting the number of laser developing heads and lamps controlled by multiple microprocessors. The laser display system control and setting interface and the light source control interface are operated and controlled in one window, or in two separate windows, or in multiple separate windows. The mobile terminal can be a vehicle-mounted display terminal, smartphone, tablet, laptop, desktop computer, smartwatch, AR glasses, handheld display terminal, or wearable device. The mobile terminal may or may not have a hanging ring for attaching to a key ring or other suitable ornament.

12. A multi-angle light-emitting lamp with selectable light-emitting angle according to claim 1, characterized in that; The PCB board is configured with one or more long strip PCB boards, circular PCB boards, square PCB boards, or arbitrarily curved geometric PCB boards of the same shape according to the shape of the lamp holder structure or lampshade. The PCB board is connected to the light source, laser developing system, laser developing head, and electronic components via two or more power lines to form a power data circuit. The power data circuit is equipped with an energy storage battery or a photovoltaic panel to generate power for the circuit. The power data circuit has the following functions: voltage regulation, AC or DC output, energy storage, high or low voltage output, image storage, image receiving and output, wireless connection, program storage, program setting memory, self-programming, power on / off program selection and video output, brightness change program programming, brightness change program selection, multiple microprocessor coordination and synchronization, and brightness change program. The lamp includes the following functions: power-off selection, brightness change program memory, photosensitive power-on / power-off, mobile terminal interface settings, mobile terminal signal synchronization reception and output, mobile terminal interface interaction, mobile terminal interface programming, high-frequency current output, high-frequency synchronization, timing, RGB light source color digital control output, multi-channel light source output, digital signal output, analog signal output and reception, visual reception and output, mind control, camera-acquired digital signal storage and output, sound control, and infrared reception. All functions are integral to the light source or laser imaging system of the lamp, and may constitute all or some of the lamp's application functions. Each function is composed of corresponding electronic components and integrated circuits or functional modules and software adapters. All or some of these functions constitute a microprocessor and power / data circuits or an independent microprocessor.