CN109958979B - Electronic switch control mechanism of lamp - Google Patents

Abstract

The invention relates to a lamp electronic switch control mechanism, comprising: the lamp main structure comprises an octagonal tube seat, a connecting pin, a support, a cathode, a mica shielding plate, an anode, a glass sleeve and a quartz window, wherein the glass sleeve is used for being sleeved with the support, the cathode, the mica shielding plate and the anode; and the electronic control switch is connected with the lamp main structure, is used for recovering the connection between the lamp main structure and the power supply terminal when receiving an opening control signal, and is also used for interrupting the connection between the lamp main structure and the power supply terminal when receiving a closing control signal. By the invention, the automation level of lamp switch control is improved.

Description

Electronic switch control mechanism of lamp

Technical Field

The invention relates to the field of lamp switch control, in particular to a lamp electronic switch control mechanism.

Background

Lamp, means the utensil that can pass through light, distribute and change light source light distribution, includes all spare parts except light source that all are used for fixed and protection light source needs, and the necessary circuit annex of being connected with the power.

Modern lamps include home lighting, commercial lighting, industrial lighting, roadway lighting, landscape lighting, specialty lighting, and the like. The home lighting is developed from the earliest incandescent bulb appearing in the birth of electricity, then developed to a fluorescent tube, then developed to the lighting of energy-saving lamps, halogen tungsten lamps, gas discharge lamps and LED special materials, and the like, and most of all lighting lamps are developed under the development of the light sources, such as electric lamp holders, fluorescent lamp supports, various kinds of craft lamp decorations, and the like.

Disclosure of Invention

In order to solve the technical problem that lamp switch control in the prior art is too dependent on manual work, the invention provides a lamp electronic switch control mechanism, based on the result of redundancy analysis of each target sub-image in an image, a preset number of target sub-images with minimum redundancy are taken as a plurality of output sub-images, and the key is that the image signal-to-noise ratio is inversely proportional to the preset number; the key point is that in the specific image processing, the reference brightness is determined based on the overall brightness of each output sub-image, so as to adjust the parameters of the lamp switch, and effectively reduce the energy consumption of the lamp.

According to an aspect of the present invention, there is provided a light fixture electronic switch control mechanism, the mechanism comprising:

the lamp main structure comprises an octagonal tube seat, a connecting pin, a support, a cathode, a mica shielding plate, an anode, a glass sleeve and a quartz window, wherein the glass sleeve is used for being sleeved with the support, the cathode, the mica shielding plate and the anode; the electronic control switch is connected with the lamp main structure, is used for recovering the connection between the lamp main structure and the power supply terminal when receiving an opening control signal, and is also used for interrupting the connection between the lamp main structure and the power supply terminal when receiving a closing control signal; the combined shooting equipment is arranged on a bracket of the lamp main structure and used for imaging the periphery of the bracket to obtain a corresponding image around the bracket; the fineness adjusting device is arranged on a bracket of the lamp main structure, is connected with the combined shooting device and is used for performing color fineness adjustment on the image around the bracket so as to obtain and output a fineness adjusting image; a distortion correction device connected to the fineness adjustment device for performing distortion correction processing on the fineness adjustment image to obtain and output a distortion correction image; the distribution detection equipment is connected with the distortion correction equipment and used for receiving the distortion correction image and identifying whether a target pixel point is in each pixel point in the distortion correction image based on a preset target gray threshold range; the TF storage equipment is connected with the distribution detection equipment, is used for pre-storing a preset target gray threshold range, and is also used for pre-storing the mapping relation between the image signal-to-noise ratio and the preset number; the shape fitting equipment is connected with the distribution ascertaining equipment and is used for receiving each target pixel point, fitting each target pixel point and removing isolated target pixel points to obtain each target sub-image in the distortion correction image; the subimage extraction equipment is respectively connected with the TF storage equipment and the shape fitting equipment and is used for analyzing the redundancy of each target subimage and sequencing the redundancy of each target subimage so as to take the preset number of target subimages with the minimum redundancy as a plurality of output subimages; the brightness identification device is connected with the sub-image extraction device and used for receiving the output sub-images, determining the overall brightness of each output sub-image and outputting the average value of the overall brightness of the output sub-images as reference brightness; and the signal analysis equipment is respectively connected with the brightness identification equipment and the electronic control switch and is used for sending out a closing control signal when the reference brightness exceeds a limited quantity and sending out an opening control signal when the reference brightness does not exceed the limited quantity.

More specifically, in the light fixture electronic switch control mechanism: identifying whether a target pixel point is performed on each pixel point in the distortion correction image based on a preset target gray threshold range comprises the following steps: and when the gray value of the pixel point is within the preset target gray threshold range, determining the pixel point as a target pixel point.

More specifically, in the light fixture electronic switch control mechanism: identifying whether a target pixel point is performed on each pixel point in the distortion correction image based on a preset target gray threshold range comprises the following steps: and when the gray value of the pixel point is out of the preset target gray threshold range, determining the pixel point as a non-target pixel point.

More specifically, in the light fixture electronic switch control mechanism: in the TF storage device, the image signal-to-noise ratio is inversely proportional to the preset number.

More specifically, in the light fixture electronic switch control mechanism: the subimage extraction device further comprises a signal-to-noise ratio measurement unit for measuring a real-time signal-to-noise ratio of the distortion correction image to determine a preset number required by the subimage extraction device based on the real-time signal-to-noise ratio and the mapping relation.

More specifically, in the light fixture electronic switch control mechanism: the equipment is shot in combination includes that first shooting subassembly, second shoot subassembly and third shoot the subassembly, and first shooting subassembly and second shoot the subassembly and be 90 degrees connections, and the third shoots the subassembly and is 90 degrees connections with the second shooting subassembly.

More specifically, in the light fixture electronic switch control mechanism: the first shooting assembly comprises a plastic shell, an annular container, a first shooting component and a first connecting fastener, wherein the annular container, the first shooting component and the first connecting fastener are all positioned in the plastic shell; wherein, first camera shooting part sets up the outer end towards at plastic casing, and first connecting fastener sets up the inner end towards at plastic casing, and first camera shooting part embedding is inside annular container for outwards carry out high definition image acquisition in order to obtain first high definition image to the place ahead.

More specifically, in the light fixture electronic switch control mechanism: the second shooting assembly comprises a plastic shell, an annular container, a second shooting component and a second connecting fastener, wherein the annular container, the second shooting component and the second connecting fastener are all positioned in the plastic shell; wherein, the second part of making a video recording sets up the outer end towards at plastic casing, and the second is connected the fastener and is set up the inner end towards at plastic casing, and the second part of making a video recording embedding is inside annular container for outwards carry out high definition image acquisition in order to obtain the second high definition image to the place ahead.

More specifically, in the light fixture electronic switch control mechanism: the third shooting assembly comprises a plastic shell, an annular container, a third shooting component and a third connecting fastener, wherein the annular container, the third shooting component and the third connecting fastener are all positioned in the plastic shell; wherein, the third part of making a video recording sets up the end towards the outer end at plastic casing, and the third is connected the fastener and is set up the end towards the inner side at plastic casing, and the third part of making a video recording imbeds inside annular container for outwards carry out high definition image acquisition in order to obtain the third high definition image to the place ahead.

More specifically, in the light fixture electronic switch control mechanism: the combined shooting equipment further comprises an image screening component which is respectively connected with the first shooting component, the second shooting component and the third shooting component and used for respectively receiving the first high-definition image, the second high-definition image and the third high-definition image; the combined shooting equipment is further used for determining the image with the highest complexity in the first high-definition image, the second high-definition image and the third high-definition image as the image around the stent.

Detailed Description

The following will describe in detail embodiments of the electronic switch control mechanism of the lamp according to the present invention.

Lamps are classified into two categories according to installation location: outdoor lamps and indoor lamps. The outdoor can be divided into landscape lamps, garden lamps, street lamps, contour lamps, lawn lamps, underground lamps, floodlights, projection lamps, ladder lamps, tree lamps, underwater lamps and the like according to the purposes. Indoor is generally: ceiling lamps, wall lamps, bracket lamps, ceiling lamps, table lamps and the like.

The light sources are divided into: energy-saving lamp, fluorescent lamp, LED lamp, halide lamp, sodium lamp, mercury lamp, cold cathode tube, etc

The wall lamp is suitable for lighting bedrooms and toilets. Commonly used double-ended magnolia wall lamps, double-ended olive wall lamps, illuminating lamps, magnolia cover flower lamps, olive ceiling lamps and the like used in family rooms are divided into ceiling lamps, ceiling lamps and wall lamps. Common bulbs are suitable to be arranged in the wall lamp and the desk lamp. The down lamps can be arranged on the peripheral ceiling of the bedroom, the living room and the toilet.

In order to overcome the defects, the invention builds the electronic switch control mechanism of the lamp, and can effectively solve the corresponding technical problem.

The electronic switch control mechanism of the lamp according to the embodiment of the invention comprises:

the lamp main structure comprises an octagonal tube seat, a connecting pin, a support, a cathode, a mica shielding plate, an anode, a glass sleeve and a quartz window, wherein the glass sleeve is used for being sleeved with the support, the cathode, the mica shielding plate and the anode;

the electronic control switch is connected with the lamp main structure, is used for recovering the connection between the lamp main structure and the power supply terminal when receiving an opening control signal, and is also used for interrupting the connection between the lamp main structure and the power supply terminal when receiving a closing control signal;

the combined shooting equipment is arranged on a bracket of the lamp main structure and used for imaging the periphery of the bracket to obtain a corresponding image around the bracket;

the fineness adjusting device is arranged on a bracket of the lamp main structure, is connected with the combined shooting device and is used for performing color fineness adjustment on the image around the bracket so as to obtain and output a fineness adjusting image;

a distortion correction device connected to the fineness adjustment device for performing distortion correction processing on the fineness adjustment image to obtain and output a distortion correction image;

the distribution detection equipment is connected with the distortion correction equipment and used for receiving the distortion correction image and identifying whether a target pixel point is in each pixel point in the distortion correction image based on a preset target gray threshold range;

the TF storage equipment is connected with the distribution detection equipment, is used for pre-storing a preset target gray threshold range, and is also used for pre-storing the mapping relation between the image signal-to-noise ratio and the preset number;

the shape fitting equipment is connected with the distribution ascertaining equipment and is used for receiving each target pixel point, fitting each target pixel point and removing isolated target pixel points to obtain each target sub-image in the distortion correction image;

the subimage extraction equipment is respectively connected with the TF storage equipment and the shape fitting equipment and is used for analyzing the redundancy of each target subimage and sequencing the redundancy of each target subimage so as to take the preset number of target subimages with the minimum redundancy as a plurality of output subimages;

the brightness identification device is connected with the sub-image extraction device and used for receiving the output sub-images, determining the overall brightness of each output sub-image and outputting the average value of the overall brightness of the output sub-images as reference brightness;

and the signal analysis equipment is respectively connected with the brightness identification equipment and the electronic control switch and is used for sending out a closing control signal when the reference brightness exceeds a limited quantity and sending out an opening control signal when the reference brightness does not exceed the limited quantity.

Next, a detailed description of the lamp electronic switch control mechanism according to the present invention will be further described.

In the light fixture electronic switch control mechanism: identifying whether a target pixel point is performed on each pixel point in the distortion correction image based on a preset target gray threshold range comprises the following steps: and when the gray value of the pixel point is within the preset target gray threshold range, determining the pixel point as a target pixel point.

In the light fixture electronic switch control mechanism: identifying whether a target pixel point is performed on each pixel point in the distortion correction image based on a preset target gray threshold range comprises the following steps: and when the gray value of the pixel point is out of the preset target gray threshold range, determining the pixel point as a non-target pixel point.

In the light fixture electronic switch control mechanism: in the TF storage device, the image signal-to-noise ratio is inversely proportional to the preset number.

In the light fixture electronic switch control mechanism: the subimage extraction device further comprises a signal-to-noise ratio measurement unit for measuring a real-time signal-to-noise ratio of the distortion correction image to determine a preset number required by the subimage extraction device based on the real-time signal-to-noise ratio and the mapping relation.

In the light fixture electronic switch control mechanism: the equipment is shot in combination includes that first shooting subassembly, second shoot subassembly and third shoot the subassembly, and first shooting subassembly and second shoot the subassembly and be 90 degrees connections, and the third shoots the subassembly and is 90 degrees connections with the second shooting subassembly.

In the light fixture electronic switch control mechanism: the first shooting assembly comprises a plastic shell, an annular container, a first shooting component and a first connecting fastener, wherein the annular container, the first shooting component and the first connecting fastener are all positioned in the plastic shell;

wherein, first camera shooting part sets up the outer end towards at plastic casing, and first connecting fastener sets up the inner end towards at plastic casing, and first camera shooting part embedding is inside annular container for outwards carry out high definition image acquisition in order to obtain first high definition image to the place ahead.

In the light fixture electronic switch control mechanism: the second shooting assembly comprises a plastic shell, an annular container, a second shooting component and a second connecting fastener, wherein the annular container, the second shooting component and the second connecting fastener are all positioned in the plastic shell;

wherein, the second part of making a video recording sets up the outer end towards at plastic casing, and the second is connected the fastener and is set up the inner end towards at plastic casing, and the second part of making a video recording embedding is inside annular container for outwards carry out high definition image acquisition in order to obtain the second high definition image to the place ahead.

In the light fixture electronic switch control mechanism: the third shooting assembly comprises a plastic shell, an annular container, a third shooting component and a third connecting fastener, wherein the annular container, the third shooting component and the third connecting fastener are all positioned in the plastic shell;

wherein, the third part of making a video recording sets up the end towards the outer end at plastic casing, and the third is connected the fastener and is set up the end towards the inner side at plastic casing, and the third part of making a video recording imbeds inside annular container for outwards carry out high definition image acquisition in order to obtain the third high definition image to the place ahead.

In the light fixture electronic switch control mechanism: the combined shooting equipment further comprises an image screening component which is respectively connected with the first shooting component, the second shooting component and the third shooting component and used for respectively receiving the first high-definition image, the second high-definition image and the third high-definition image;

the combined shooting equipment is further used for determining the image with the highest complexity in the first high-definition image, the second high-definition image and the third high-definition image as the image around the stent.

In addition, the TF storage device may be replaced with a DRAM device. Dram (dynamic Random access memory), which is a dynamic Random access memory, is the most common system memory. DRAM can hold data only for a short time. To retain data, DRAM uses capacitive storage, so must be refreshed (refresh) once at intervals, and if the memory cells are not refreshed, the stored information is lost. Dynamic RAM is also comprised of a number of basic memory cells multiplexed by row and column address pins.

The structure of the DRAM is simple and efficient, and each bit only needs one transistor and one capacitor. However, the capacitance inevitably has leakage phenomenon, which causes data error if the charge is insufficient, and therefore, the capacitance must be periodically refreshed (precharged), which is also a big feature of the DRAM. Moreover, the charging and discharging of the capacitor requires a process, and the refresh frequency cannot be raised infinitely (frequency barrier), which results in that the frequency of the DRAM can easily reach the upper limit, and even if the advanced process is supported, the effect is very small. With the advancement of technology and the desire of people to overclock, these frequency barriers are being solved slowly.

By adopting the electronic switch control mechanism of the lamp, aiming at the technical problem of low automation level of lamp switch control in the prior art, the preset number of target sub-images with minimum redundancy are taken as a plurality of output sub-images based on the redundancy analysis result of each target sub-image in the image, and the key is that the image signal-to-noise ratio is inversely proportional to the preset number; meanwhile, reference brightness is determined based on the overall brightness of each output subimage, so that parameters of the lamp switch are adjusted, and energy consumption of the lamp is effectively reduced; thereby solving the technical problem.

It is to be understood that while the present invention has been described in conjunction with the preferred embodiments thereof, it is not intended to limit the invention to those embodiments. It will be apparent to those skilled in the art from this disclosure that many changes and modifications can be made, or equivalents modified, in the embodiments of the invention without departing from the scope of the invention. Therefore, any simple modification, equivalent change and modification made to the above embodiments according to the technical essence of the present invention are still within the scope of the protection of the technical solution of the present invention, unless the contents of the technical solution of the present invention are departed.

Claims (6)

1. A light fixture electronic switch control mechanism, said mechanism comprising:

the lamp main structure comprises an octagonal tube seat, a connecting pin, a support, a cathode, a mica shielding plate, an anode, a glass sleeve and a quartz window, wherein the glass sleeve is used for being sleeved with the support, the cathode, the mica shielding plate and the anode;

the electronic control switch is connected with the lamp main structure, is used for recovering the connection between the lamp main structure and the power supply terminal when receiving an opening control signal, and is also used for interrupting the connection between the lamp main structure and the power supply terminal when receiving a closing control signal;

the combined shooting equipment is arranged on a bracket of the lamp main structure and used for imaging the periphery of the bracket to obtain a corresponding image around the bracket;

the fineness adjusting device is arranged on a bracket of the lamp main structure, is connected with the combined shooting device and is used for performing color fineness adjustment on the image around the bracket so as to obtain and output a fineness adjusting image;

a distortion correction device connected to the fineness adjustment device for performing distortion correction processing on the fineness adjustment image to obtain and output a distortion correction image;

the distribution detection equipment is connected with the distortion correction equipment and used for receiving the distortion correction image and identifying whether a target pixel point is in each pixel point in the distortion correction image based on a preset target gray threshold range;

the TF storage equipment is connected with the distribution detection equipment, is used for pre-storing a preset target gray threshold range, and is also used for pre-storing the mapping relation between the image signal-to-noise ratio and the preset number;

the shape fitting equipment is connected with the distribution ascertaining equipment and is used for receiving each target pixel point, fitting each target pixel point and removing isolated target pixel points to obtain each target sub-image in the distortion correction image;

the subimage extraction equipment is respectively connected with the TF storage equipment and the shape fitting equipment and is used for analyzing the redundancy of each target subimage and sequencing the redundancy of each target subimage so as to take the preset number of target subimages with the minimum redundancy as a plurality of output subimages;

the brightness identification device is connected with the sub-image extraction device and used for receiving the output sub-images, determining the overall brightness of each output sub-image and outputting the average value of the overall brightness of the output sub-images as reference brightness;

and the signal analysis equipment is respectively connected with the brightness identification equipment and the electronic control switch and is used for sending out a closing control signal when the reference brightness exceeds a limited quantity and sending out an opening control signal when the reference brightness does not exceed the limited quantity.

2. The lamp electronic switch control mechanism of claim 1, wherein:

identifying whether a target pixel point is performed on each pixel point in the distortion correction image based on a preset target gray threshold range comprises the following steps: and when the gray value of the pixel point is within the preset target gray threshold range, determining the pixel point as a target pixel point.

3. The lamp electronic switch control mechanism of claim 2, wherein:

identifying whether a target pixel point is performed on each pixel point in the distortion correction image based on a preset target gray threshold range comprises the following steps: and when the gray value of the pixel point is out of the preset target gray threshold range, determining the pixel point as a non-target pixel point.

4. The lamp electronic switch control mechanism of claim 3, wherein:

in the TF storage device, the image signal-to-noise ratio is inversely proportional to the preset number.

5. The lamp electronic switch control mechanism of claim 4, wherein:

the subimage extraction device further comprises a signal-to-noise ratio measurement unit for measuring a real-time signal-to-noise ratio of the distortion correction image to determine a preset number required by the subimage extraction device based on the real-time signal-to-noise ratio and the mapping relation.

6. The lamp electronic switch control mechanism of claim 5, wherein:

the equipment is shot in combination includes that first shooting subassembly, second shoot subassembly and third shoot the subassembly, and first shooting subassembly and second shoot the subassembly and be 90 degrees connections, and the third shoots the subassembly and is 90 degrees connections with the second shooting subassembly.