CN113156636A - Method and device for quickly starting microscopic camera shooting and intelligent equipment - Google Patents

Abstract

The invention provides a method and a device for quickly starting microscopic camera shooting and intelligent equipment, wherein the method comprises the following steps: the method is used for intelligent equipment, and the intelligent equipment comprises a camera module and a microscopic amplification module which are arranged separately, and is provided with a microscopic camera application program. And when the camera module is detected to be tightly attached to the upper surface of the microscopic amplification module, automatically starting the microscopic camera application program. The method and the device can avoid the situation that the user manually starts the corresponding application program when the user carries out the micro-photography, simplify the operation and improve the user experience.

Description

Method and device for quickly starting microscopic camera shooting and intelligent equipment

Technical Field

The invention relates to the technical field of computers, in particular to a method and a device for quickly starting microscopic camera shooting and intelligent equipment.

Background

Recently, smart devices such as smart phones and smart watches which are widely used are generally provided with cameras for shooting. However, a general camera is difficult to photograph a tiny object and does not have the functions of microscopic observation and microscopic photography.

At present, smart devices such as smart phones and smart watches have a function of taking micrographs by adding an external micro lens for an amplification function.

In order to distinguish from traditional shooting and obtain better microscopic shooting effect and interactive experience simultaneously, two application software are respectively designed on intelligent equipment: traditional photography APP (Application) and photomicrography APP. If the user needs to carry out micro-shooting, the user needs to manually open the micro-shooting APP first to enter the micro-shooting.

Disclosure of Invention

The invention aims to provide a method and a device for quickly starting microscopic shooting and intelligent equipment, which are used for solving the problem that the microscopic shooting can be started only by manually starting a microscopic shooting APP in the prior art.

The technical scheme provided by the invention is as follows:

a method of rapidly turning on a photomicrograph, comprising: and when the camera module which is arranged separately is detected to be closely attached to the upper surface of the microscopic amplification module, starting the microscopic camera application program.

Further, when it is detected that the camera module arranged separately is closely attached to the upper surface of the microscopic magnification module, the microscopic camera application program is started, including:

when the camera module which is arranged separately is detected to be closely attached to the upper surface of the microscopic amplification module, an illumination component of the microscopic amplification module is started to illuminate a shot sample;

detecting the brightness and/or color temperature of light rays input into the camera module;

and when the light brightness and/or the light color temperature reach respective preset values, starting a micro-camera application program.

Further, when it is detected that the separately arranged camera module is closely attached to the upper surface of the microscopic amplification module, the lighting part of the microscopic amplification module is turned on, and the method includes:

detecting the surface pressure of the microscopic amplification module;

and when the surface pressure reaches a preset pressure threshold, starting an illuminating part of the micro-amplification module.

Further, comprising: and when the camera module is detected to leave the microscopic magnification module, the illumination part of the microscopic magnification module is turned off.

Further, detecting the brightness of the light input into the camera module includes:

and acquiring the average pixel brightness of the initial image, and taking the average pixel brightness as the light brightness input into the camera module.

Further, detecting the color temperature of the light input into the camera module comprises:

and acquiring the color temperature of the light rays input into the camera module through an automatic white balance algorithm.

The invention also provides a device for rapidly starting the microscopic camera, which comprises: the device comprises a camera module, a microscopic amplification module, a detection module and a starting module;

the detection module is used for detecting whether the separately arranged camera module is tightly attached to the upper surface of the microscopic amplification module;

and the starting module is used for starting the micro-camera application program when the separately arranged camera module is detected to be tightly attached to the upper surface of the micro-amplification module.

Further, the micro-magnification module comprises a microscope lens and an illumination component, wherein the illumination component is arranged around the microscope lens;

the detection module is also used for turning on the illumination component when the separately arranged camera module is detected to be tightly attached to the upper surface of the microscopic amplification module;

the illumination component is used for emitting light rays to illuminate the shot sample;

the camera module is used for detecting the brightness and/or color temperature of light rays input into the camera module;

the starting module is further used for starting a micro-camera application program when the light brightness and/or the light color temperature reach respective preset values.

Further, the camera module is further configured to obtain an average pixel brightness of an initial image, which is used as the light brightness input to the camera module.

The invention also provides an intelligent device, which comprises a camera module and a microscopic amplification module, and also comprises: a memory for storing a computer program; and the processor is used for realizing the method for quickly starting the microscopic camera shooting when the computer program is run.

The method, the device and the intelligent equipment for quickly starting the microscopic camera provided by the invention can at least bring the following beneficial effects:

1. according to the invention, when the camera module and the microscopic amplification module which are separately arranged are detected to be closely attached, the requirement of the user for microscopic camera shooting is identified, and then the microscopic camera application program is automatically started, so that the user is prevented from manually starting the microscopic camera application program, and the user experience is improved.

2. According to the invention, the lighting part is introduced into the microscopic amplification module, the lighting part not only supplements light for the microscopic photography, but also provides specific light brightness and color temperature for the microscopic photography, and the microscopic photography can be more accurately identified based on the characteristics, so that the accuracy of starting the application program of the microscopic photography is improved.

Drawings

The above features, technical features, advantages and implementations of a method and apparatus for fast start-up photomicrography, a smart device, and a computer program product are further described in the following detailed description of preferred embodiments in a clearly understandable manner with reference to the accompanying drawings.

FIG. 1 is a flow chart of one embodiment of a method of rapidly starting a photomicrograph according to the invention;

FIG. 2 is a flow chart of another embodiment of a method of rapidly starting a photomicrograph according to the invention;

FIG. 3 is a schematic diagram of an embodiment of a device for rapidly turning on photomicrography in accordance with the present invention;

FIG. 4 is a schematic diagram of another embodiment of a fast turn-on photomicrography device of the present invention;

fig. 5 is a schematic structural diagram of an embodiment of an intelligent device of the present invention.

The reference numbers illustrate:

100. the system comprises a camera module, a microscopic amplification module, a detection module, a starting module, a microscope lens, a lighting part, an intelligent device, a storage, a processor, a computer program and a device, wherein the camera module comprises 200, the microscopic amplification module, 300, the detection module, 400, the starting module, 210, the microscope lens, 220, the lighting part, 20, the intelligent device, 21, the storage, 22, the processor, 23, the computer program and 10 are used for quickly starting a microscopic camera.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following description will be made with reference to the accompanying drawings. It is obvious that the drawings in the following description are only some examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be derived from them without inventive effort.

For the sake of simplicity, the drawings only schematically show the parts relevant to the present invention, and they do not represent the actual structure as a product. In addition, in order to make the drawings concise and understandable, components having the same structure or function in some of the drawings are only schematically depicted, or only one of them is labeled. In this document, "one" means not only "only one" but also a case of "more than one".

In one embodiment of the present invention, as shown in fig. 1, a method for rapidly starting a photomicrography is used for an intelligent device, the intelligent device comprises a camera module and a microscope amplification module which are separately arranged, and a photomicrography application program is arranged. The method comprises the following steps:

step S100 is to start the micro-camera application when it is detected that the separately arranged camera module is closely attached to the upper surface of the micro-magnification module.

Specifically, the smart device is a portable mobile terminal such as a smart phone and a smart watch.

The camera module has the function of making a video recording, can be the camera on the smart machine, is used for tradition to shoot usually. The microscopic magnification module has the function of a traditional microscope and comprises a microscope lens, and can magnify and image tiny objects.

The micro-camera application program is application software specially used for micro-camera, and can obtain a better micro-camera effect compared with a common camera application program.

In this embodiment, the camera module and the micro-magnifying module are separately disposed, not integrated, and the camera module and the micro-magnifying module are usually not in contact, and may be separated from each other. People can take a picture daily with the camera module. Only when the camera module is tightly attached to the upper surface of the microscopic amplifying module through manual operation, the optical axis of the camera is superposed with the optical axis of the microscope lens, and the camera module and the microscopic amplifying module form a light path system for microscopic shooting so as to carry out microscopic shooting.

Taking a smart watch as an example, the camera module is fixed on the watch body, and the microscopic amplification module is movably hung on the watch as an accessory. When the micro-camera is carried out, the camera module is tightly attached to the upper surface of the micro-amplification module by manual operation.

Optionally, the intelligent device is provided with a pressure sensor, and the surface pressure of the microscopic amplification module is detected through the pressure sensor. And when the surface pressure of the microscopic amplification module reaches a preset pressure threshold, detecting that the camera module is tightly attached to the upper surface of the microscopic amplification module, and starting the microscopic camera application program.

When the micro-photography is not needed, the camera module is not in contact with the micro-amplification module, and the surface pressure of the micro-amplification module is usually 0. When microscopic shooting is needed and the shooting module is tightly attached to the upper surface of the microscopic amplification module through manual operation, the surface pressure of the microscopic amplification module is obviously changed. It is possible to recognize whether the user has a need for the photomicrograph by detecting a change in the surface pressure of the photomicrograph module. When the user is identified to have the requirement of the micro-photography, the micro-photography application program is automatically started, so that the user is prevented from manually starting the micro-photography application program.

There are other ways to attach the camera module closely to the upper surface of the micro-magnification module. For example, the camera module can rotate, and when the optical axis of the camera module and the optical axis of the microscopic magnification module are arranged at 90 degrees, the camera module can carry out traditional shooting; when the camera module rotates 90 degrees and the optical axis of the camera module and the optical axis of the microscopic amplification module are on the same straight line, an optical path system for microscopic shooting is formed and microscopic shooting can be carried out. In this way, whether the camera module is closely attached to the upper surface of the micro-magnification module can be detected by the angle sensor. The present embodiment does not limit this.

According to the embodiment, whether the camera module is tightly attached to the upper surface of the microscopic amplification module or not is detected, when the camera module is detected to be tightly attached to the upper surface of the microscopic amplification module, the microscopic camera application program is automatically started, the user can be prevented from manually starting the corresponding application program when the microscopic camera is carried out, the operation is simplified, and the user experience is improved.

In another embodiment of the present invention, as shown in fig. 2, a method for rapidly starting a photomicrography is used for an intelligent device, the intelligent device comprises a camera module and a microscope magnification module which are separately arranged, and a photomicrography application program is provided. The microscopic magnification module comprises a microscope lens and an illuminating part, and the illuminating part is arranged around the microscope lens.

The method comprises the following steps:

and step S200, when the camera module is detected to be closely attached to the upper surface of the microscopic amplification module, starting an illuminating part of the microscopic amplification module to illuminate the shot sample.

Specifically, the microscopic magnification module includes an illumination section. The lighting component is used for supplementing light for the microscopic photography, so that the microscopic photography can obtain a better imaging effect.

The lighting component comprises a light emitting element, such as a light emitting diode. The lighting component may comprise a plurality of light emitting elements, such as four light emitting diodes capable of emitting white light, or three light emitting diodes capable of emitting white light and one light emitting diode capable of emitting ultraviolet light, so as to be suitable for application scenes requiring ultraviolet fluorescence observation.

The illumination component may be disposed around the microscope lens. When the number and position of the light-emitting elements in the lighting component are determined, the brightness and color temperature of the light emitted by the lighting component are also determined.

The lighting component is in an off state by default. When detecting that the user is ready to perform the micro-photographing operation, for example, when detecting that the photographing module is closely attached to the upper surface of the micro-magnification module, the illumination component is turned on, so that the energy consumption can be reduced. The illumination component emits light to illuminate the shot sample.

The surface pressure of the microscopic amplification module can be detected through the pressure sensor; and when the surface pressure of the microscopic amplification module reaches a preset pressure threshold, the camera module is considered to be tightly attached to the upper surface of the microscopic amplification module.

Step S300 detects the brightness and/or color temperature of the light input to the camera module.

Optionally, the average pixel brightness of the initial image is obtained as the light brightness of the input camera module.

Smart devices typically have an automatic exposure function.

Generally, an average brightness method is adopted, and the automatic exposure is realized by the following processes:

1. the average pixel brightness (i.e., the average of all pixel brightness) of the current image is obtained.

2. New exposure parameters (exposure time, aperture, sensitivity ISO value, etc.) are determined from the current image brightness and the target brightness.

3. The new exposure parameters are applied to the camera.

4. Repeating steps 1 to 3 until the target brightness is reached.

The first step is to obtain the average pixel brightness of the initial image, which is the required brightness of the light input into the camera module in this embodiment.

Optionally, the color temperature of the light input into the camera module is obtained through an automatic white balance algorithm.

Color temperature is a measure of the color of light, with warm shades being low and cold shades being high.

Since a light source is often accompanied by a spectrum of a certain color, when a white object is present under such a light source, it is no longer white. If a White Balance algorithm (i.e., an AWB algorithm) is not adopted during photographing, a picture photographed in yellow light will be yellow, a picture photographed in sunlight will be blue, and the like. In order to make the photographed object appear true color, the color of the light source itself needs to be eliminated, and this operation is called white balance.

The AWB algorithm needs to acquire the color temperature of the light source. We take the color temperature of the light source obtained by the algorithm as the color temperature of the light rays input into the camera module.

In step S400, when the light brightness and/or the light color temperature reach respective preset values, the micro-camera application program is started.

Specifically, during microscopic imaging, light emitted from the illumination unit enters the imaging module by scattering, reflection, or the like. When the camera is used for daily shooting, natural environment light enters the camera module.

Since the illumination component is close to the camera of the camera module during the microscopic image capturing, the brightness of the light (i.e. BV Value) detected during the microscopic image capturing is higher than that measured during the ordinary daily image capturing. For example, the light brightness of daily shooting is generally below BV6000, and the brightness detected by microscopic shooting with fill light can reach BV 12000.

The color temperature range of daily camera shooting is generally 4000K-7000K, a small part is 2800K-4000K, and the indoor scene is generally below 5500K. The color temperature of the incandescent lamp is about 2800K, and that of the ultraviolet lamp is about 9000K; and outdoor standard sunlight is about 5200-5500K.

If the illuminating part is an ultraviolet lamp, the light color temperature (9000K) during microscopic shooting can be basically distinguished from daily shooting. If the lighting part adopts a white light lamp, the microscopic image pickup and the daily image pickup are simply distinguished according to the color temperature of light, so that errors exist; in this case, the light brightness is combined to improve the distinguishing accuracy.

When the number and the position of the light-emitting elements in the lighting part are determined, the brightness and the color temperature of the light emitted by the lighting part are also determined; therefore, when the camera module is tightly attached to the upper surface of the micro-amplification module, the detected light brightness and light color temperature data are basically unique. By utilizing the characteristic, the light brightness value and the light color temperature value input into the camera module during micro-photography can be obtained in advance, corresponding preset values are set according to the obtained light brightness value and the obtained light color temperature value respectively, and the micro-photography and the daily photography are distinguished according to the light brightness value and the light color temperature value.

Optionally, when the brightness and the color temperature of the light input into the camera module do not reach respective preset values, the micro-camera application program is not started.

And when the camera module is detected to leave the microscopic magnification module, the lighting part of the microscopic magnification module is turned off.

In the embodiment, the lighting part is introduced into the micro-amplification module, the lighting part provides specific light brightness and color temperature for distinguishing daily shooting for the micro-shooting besides the light supplement for the micro-shooting, and has stability and uniqueness.

This embodiment need not newly increase the hardware, adopts the software mode accurately to discern the micro-demand of making a video recording, has reduced the cost and the space requirement of equipment, especially to some small intelligent equipment, for example wearable equipment such as intelligent wrist-watch.

In one embodiment of the present invention, as shown in fig. 3, an apparatus for rapidly turning on a photomicrograph includes:

the device comprises a camera module 100, a microscopic amplification module 200, a detection module 300 and a starting module 400.

And the detection module 300 is used for detecting whether the separately arranged camera module is tightly attached to the upper surface of the microscopic amplification module.

And the starting module 400 is used for starting the micro-camera application program when the separately arranged camera module is detected to be tightly attached to the upper surface of the micro-amplification module.

Specifically, the camera module 100 has a camera function, and may be a camera on a smart device such as a smart phone or a smart watch, and is generally used for traditional photographing. The micro-magnification module 200 has a conventional microscope function, and includes a micro-lens, which can magnify and image a tiny object.

In this embodiment, the image capturing module 100 and the micro-magnifying module 200 are separately disposed, not integrated, and they are usually not in contact, and may be separated from each other. People can take daily pictures with the camera module 100. Only when the camera module 100 is tightly attached to the upper surface of the micro-magnification module 200 through manual operation, the optical axis of the camera coincides with the optical axis of the micro-lens, and the camera module 100 and the micro-magnification module 200 form a micro-photographing optical path system, so that micro-photographing can be performed.

Taking a smart watch as an example, the camera module is fixed on the watch body, and the microscopic amplification module is movably hung on the watch as an accessory. When the micro-camera is carried out, the camera module is tightly attached to the upper surface of the micro-amplification module by manual operation.

Optionally, a pressure sensor is further included, and the detection module 300 detects the surface pressure of the microscopic amplification module through the pressure sensor; and when the surface pressure of the microscopic amplification module reaches a preset pressure threshold, detecting that the camera module is tightly attached to the upper surface of the microscopic amplification module. The detection module 300 then notifies the startup module 400 to start the photomicrography application.

When the micro-photography is not needed, the surface pressure of the micro-amplification module is 0. When microscopic shooting is needed and the shooting module is tightly attached to the upper surface of the microscopic amplification module through manual operation, the surface pressure of the microscopic amplification module is obviously changed. It is possible to recognize whether the user has a need for the photomicrograph by detecting a change in the surface pressure of the photomicrograph module.

When the user is identified to have the requirement of the micro-photography, the micro-photography application program is automatically started, so that the user is prevented from manually starting the micro-photography application program, and the operation is simplified.

According to the embodiment, whether the camera module is tightly attached to the upper surface of the microscopic amplification module or not is detected, when the camera module is detected to be tightly attached to the upper surface of the microscopic amplification module, the microscopic camera application program is automatically started, the user can be prevented from manually starting the corresponding application program when the microscopic camera is carried out, the operation is simplified, and the user experience is improved.

In another embodiment of the present invention, as shown in fig. 4, an apparatus for rapidly turning on a photomicrograph includes:

the device comprises a camera module 100, a microscopic amplification module 200, a detection module 300 and a starting module 400.

The micro-magnification module 200 includes a microscope lens 210 and an illumination section 220, the illumination section 220 being disposed around the microscope lens 210.

The detection module 300 is used for detecting whether the separately arranged camera module is tightly attached to the upper surface of the microscopic amplification module; when it is detected that the separately disposed camera module is closely attached to the upper surface of the micro-magnification module, the illumination part 220 is turned on.

And the illuminating component 220 is used for emitting light to illuminate the shot sample.

Specifically, the illumination component is used for supplementing light for the microscopic photography, so that the microscopic photography can obtain a better imaging effect.

The lighting component comprises a light emitting element, such as a light emitting diode. The lighting component may comprise a plurality of light emitting elements, such as four light emitting diodes capable of emitting white light, or three light emitting diodes capable of emitting white light and one light emitting diode capable of emitting ultraviolet light, so as to be suitable for application scenes requiring ultraviolet fluorescence observation.

The illumination component may be disposed around the microscope lens. When the number and position of the light-emitting elements in the lighting component are determined, the brightness and color temperature of the light emitted by the lighting component are also determined.

The lighting component is in an off state by default. When detecting that the user is ready to perform the micro-photographing operation, for example, when detecting that the photographing module is closely attached to the upper surface of the micro-magnification module, the illumination component is turned on. The illumination component emits light to illuminate the shot sample.

Optionally, the detection module 300 detects the surface pressure of the micro-amplification module through a pressure sensor; and when the surface pressure of the microscopic amplification module reaches a preset pressure threshold, the camera module is considered to be tightly attached to the upper surface of the microscopic amplification module.

The detection module 300 is further configured to turn off the illumination component of the micro-magnification module when it is detected that the camera module leaves the micro-magnification module.

The camera module 100 is configured to detect the brightness and/or color temperature of light input into the camera module.

Optionally, the camera module 100 is further configured to obtain an average pixel brightness of the initial image, which is used as the brightness of the light input into the camera module.

Smart devices typically have an automatic exposure function.

Generally, an average brightness method is adopted, and the automatic exposure is realized by the following processes:

1. the average pixel brightness (i.e., the average of all pixel brightness) of the current image is obtained.

2. New exposure parameters (exposure time, aperture, sensitivity ISO value) are determined from the current image brightness and the target brightness.

3. The new exposure parameters are applied to the camera.

4. Repeating steps 1 to 3 until the target brightness is reached.

The first step is to obtain the average pixel brightness of the initial image, which is the required brightness of the light input into the camera module in this embodiment.

Optionally, the camera module 100 is further configured to obtain a color temperature of light input to the camera module through an automatic white balance algorithm.

Color temperature is a measure of the color of light, with warm shades being low and cold shades being high.

Since a light source is often accompanied by a spectrum of a certain color, when a white object is present under such a light source, it is no longer white. If a White Balance algorithm (i.e., an AWB algorithm) is not adopted during photographing, a picture photographed in yellow light will be yellow, a picture photographed in sunlight will be blue, and the like. In order to make the photographed object appear true color, the color of the light source itself needs to be eliminated, and this operation is called white balance.

The AWB algorithm needs to acquire the color temperature of the light source. We take the color temperature of the light source obtained by the algorithm as the color temperature of the light rays input into the camera module.

The starting module 400 is configured to start the micro-camera application program when the light brightness and/or the light color temperature reach respective preset values.

Specifically, during microscopic imaging, light emitted from the illumination unit enters the imaging module by scattering, reflection, or the like. When the camera is used for daily shooting, natural environment light enters the camera module.

Since the illumination component is close to the camera of the camera module during the microscopic image capturing, the brightness of the light (i.e. BV Value) detected during the microscopic image capturing is higher than that measured during the ordinary daily image capturing. For example, the light brightness of daily shooting is generally below BV6000, and the brightness detected by microscopic shooting with fill light can reach BV 12000.

The color temperature range of daily camera shooting is generally 4000K-7000K, a small part is 2800K-4000K, and the indoor scene is generally below 5500K. The color temperature of the incandescent lamp is about 2800K, and that of the ultraviolet lamp is about 9000K; and outdoor standard sunlight is about 5200-5500K.

If the illuminating part is an ultraviolet lamp, the light color temperature (9000K) during microscopic shooting can be basically distinguished from daily shooting. If the lighting part adopts a white light lamp, the microscopic image pickup and the daily image pickup are simply distinguished according to the color temperature of light, so that errors exist; in this case, the light brightness is combined to improve the distinguishing accuracy.

When the number and the position of the light-emitting elements in the lighting part are determined, the brightness and the color temperature of the light emitted by the lighting part are also determined; therefore, when the camera module is tightly attached to the upper surface of the micro-amplification module, the detected light brightness and light color temperature data are basically unique. By utilizing the characteristic, the light brightness value and the light color temperature value input into the camera module during micro-photography can be obtained in advance, corresponding preset values are set according to the obtained light brightness value and the obtained light color temperature value respectively, and the micro-photography and the daily photography are distinguished according to the light brightness value and the light color temperature value.

Optionally, when the brightness and the color temperature of the light input into the camera module do not reach respective preset values, the micro-camera application program is not started.

In the embodiment, the lighting part is introduced into the micro-amplification module, the lighting part provides specific light brightness and color temperature for distinguishing daily shooting for the micro-shooting besides the light supplement for the micro-shooting, and the micro-shooting can be more accurately identified based on the characteristics, so that the accuracy of starting the micro-shooting application program is improved.

This embodiment need not newly increase the hardware, adopts the software mode accurately to discern the micro-demand of making a video recording, has reduced the cost and the space requirement of equipment, especially to some small intelligent equipment, for example wearable equipment such as intelligent wrist-watch.

It should be noted that the embodiment of the apparatus for rapidly starting photomicrography provided by the present invention and the embodiment of the method for rapidly starting photomicrography provided by the foregoing embodiments are all based on the same inventive concept, and can obtain the same technical effects. Thus, for further details of the embodiment of the apparatus for fast-start photomicrography, reference may be made to the statements of the content of the embodiment of the method for fast-start photomicrography described above.

In one embodiment of the present invention, as shown in fig. 5, an intelligent device 20 includes a camera module 100 and a micro-magnification module 200, a memory 21, and a processor 22.

The memory 21 is used for storing a computer program 23. The processor 22, when running the computer program 23, implements the method of fast turn-on photomicrography as described above.

As an example, the processor 21 realizes the step S100 according to the foregoing description when executing the computer program. Additionally, the processor 21, when executing the computer program, implements the functions of the modules in the apparatus for fast-start photomicrography as described above. As yet another example, the processor, when executing the computer program, implements the functions of the camera module 100, the microscopic magnification module 200, the detection module 300, and the start module 400.

Alternatively, the computer program may be divided into one or more modules/units according to the particular needs to accomplish the invention. Each module/unit may be a series of computer program instruction segments capable of performing a particular function. The computer program instruction segment is used for describing the execution process of the computer program in the device for quickly starting the microscopic camera shooting.

As an example, the computer program may be divided into modules/units in a virtual device, such as a camera module, a micro-magnification module, a detection module and a start module.

The processor is used for realizing the quick starting of the microscopic camera by executing the computer program. The processor may be a Central Processing Unit (CPU), Graphics Processing Unit (GPU), Digital Signal Processor (DSP), Application Specific Integrated Circuit (ASIC), Field Programmable Gate Array (FPGA), general purpose processor or other logic device, etc., as desired.

The memory may be any internal storage unit and/or external storage device capable of implementing data, program storage. For example, the memory may be a plug-in hard disk, a smart card (SMC), a Secure Digital (SD) card, or a flash card. The memory is used for storing computer programs and data.

The intelligent device 20 may further include an input/output device, a display device, a network access device, a bus, and the like, as required.

The intelligent device 20 may also be a single chip microcomputer or a computing device integrating a Central Processing Unit (CPU) and a Graphics Processing Unit (GPU).

It will be understood by those skilled in the art that the above-mentioned units and modules for implementing the corresponding functions are divided for the purpose of convenient illustration and description, and the above-mentioned units and modules are further divided or combined according to the application requirements, that is, the internal structures of the devices/apparatuses are divided and combined again to implement the above-mentioned functions.

Each unit and module of the above embodiments may be separate physical units, or two or more units and modules may be integrated into one physical unit. The units and modules of the above embodiments may adopt hardware and/or software functional units to implement corresponding functions. Direct coupling, indirect coupling or communication connection among a plurality of units, components and modules of the above embodiments can be realized through a bus or an interface; the coupling, connection, etc. between the multiple units or devices may be electrical, mechanical, or the like. Accordingly, the specific names of the units and modules of the above embodiments are only for convenience of description and distinction, and do not limit the scope of protection of the present application.

It should be noted that the above embodiments can be freely combined as necessary. The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. A method for rapidly starting microscopic camera shooting is used for intelligent equipment, the intelligent equipment comprises a camera shooting module and a microscopic amplification module which are arranged separately, and a microscopic camera shooting application program is arranged, and the method is characterized by comprising the following steps:

and when the camera module which is arranged separately is detected to be closely attached to the upper surface of the microscopic amplification module, starting the microscopic camera application program.

2. The method for rapidly starting photomicrography according to claim 1, wherein the starting the photomicrography application program when the camera module which is arranged separately is detected to be closely attached to the upper surface of the photomicrography module comprises the following steps:

when the camera module which is arranged separately is detected to be closely attached to the upper surface of the microscopic amplification module, an illumination component of the microscopic amplification module is started to illuminate a shot sample;

detecting the brightness and/or color temperature of light rays input into the camera module;

and when the light brightness and/or the light color temperature reach respective preset values, starting a micro-camera application program.

3. The method for rapidly turning on a microscopic camera according to claim 2, wherein turning on an illumination component of a microscopic amplification module when it is detected that a separately arranged camera module is closely attached to an upper surface of the microscopic amplification module comprises:

detecting the surface pressure of the microscopic amplification module;

and when the surface pressure reaches a preset pressure threshold, starting an illuminating part of the micro-amplification module.

4. The method of rapidly turning on photomicrography as set forth in claim 2, comprising:

and when the camera module is detected to leave the microscopic magnification module, the illumination part of the microscopic magnification module is turned off.

5. The method of claim 2, wherein detecting the brightness of light input to the camera module comprises:

and acquiring the average pixel brightness of the initial image, and taking the average pixel brightness as the light brightness input into the camera module.

6. The method of claim 2, wherein detecting the color temperature of light input to the camera module comprises:

and acquiring the color temperature of the light rays input into the camera module through an automatic white balance algorithm.

7. A device for rapidly starting a photomicrograph, comprising:

the device comprises a camera module, a microscopic amplification module, a detection module and a starting module which are arranged separately;

the detection module is used for detecting whether the separately arranged camera module is tightly attached to the upper surface of the microscopic amplification module;

and the starting module is used for starting the micro-camera application program when the separately arranged camera module is detected to be tightly attached to the upper surface of the micro-amplification module.

8. The apparatus for rapidly starting photomicrography as set forth in claim 7, wherein:

the microscopic amplification module comprises a microscope lens and an illumination component, and the illumination component is arranged around the microscope lens;

the detection module is also used for turning on the illumination component when the separately arranged camera module is detected to be tightly attached to the upper surface of the microscopic amplification module;

the illumination component is used for emitting light rays to illuminate the shot sample;

the camera module is used for detecting the brightness and/or color temperature of light rays input into the camera module;

the starting module is further used for starting a micro-camera application program when the light brightness and/or the light color temperature reach respective preset values.

9. The apparatus for rapidly starting photomicrography as set forth in claim 7, wherein:

the camera module is further configured to obtain an average pixel brightness of an initial image, and use the average pixel brightness as the light brightness input to the camera module.

10. An intelligent device, including a camera module and a microscopic magnification module, comprising:

a memory for storing a computer program;

a processor for implementing the method of fast turn-on photomicrography according to any one of claims 1 to 6 when running the computer program.

Images