CN116734670A - Multi-element selected RCLED optical aiming chip - Google Patents

Abstract

The application discloses a multi-element selected RCLED optical aiming chip, which comprises: the device comprises a power supply module, a control circuit module, a signal storage module, a feedback circuit module, a photoelectric generator module and a lens module; the power supply module provides power for the infrared sighting telescope, and the control circuit module is connected with the feedback circuit module and the photoelectric generator module; the photoelectric generator module is connected with the lens module, and the signal storage module is connected with the photoelectric generator module.

Description

Multi-element selected RCLED optical aiming chip

Technical Field

The application relates to the technical field of sighting telescope, in particular to a multi-element selected RCLED optical sighting chip.

Background

An infrared sighting telescope is a common shooting auxiliary device, and enables a shooter to clearly see a target in a dark environment by emitting infrared rays. However, the existing infrared sighting telescope has problems, such as single lighting mode, unadjustable brightness and the like, which limit the use range and effect of the infrared sighting telescope.

Disclosure of Invention

Compared with the prior art, the multi-element selected RCLED optical aiming chip in the file can switch different modes so as to be convenient for a user to use.

The file is realized by the following technical scheme: the application discloses a multiplex selective RCLED optical aiming chip, which is characterized by comprising the following components: the device comprises a power supply module, a control circuit module, a signal storage module, a feedback circuit module, a photoelectric generator module and a lens module;

the power supply module provides power for the infrared sighting telescope, and the control circuit module is connected with the feedback circuit module and the photoelectric generator module; the photoelectric generator module is connected with the lens module, and the signal storage module is connected with the photoelectric generator module.

For the application, a power module provides stable power for the whole system, is connected with other modules, provides required voltage and current for the modules, and a control circuit module is connected with a signal storage module, a feedback circuit module and a photoelectric generator module. The device controls the luminous mode and the brightness of the photoelectric generator module according to the data in the signal storage module and the feedback information of the feedback circuit module, the photoelectric generator module is connected with the lens module, the luminous pattern is projected onto the lens module, and the pattern is focused and projected onto the sight of a user by the lens module.

Preferably, the pattern formed by the photo-generator includes an outer frame and dots located at a central region of the outer frame.

Preferably, the outer frame includes a cross member and a circular member, the cross member dividing the circular member into four.

Preferably, the photo generator module comprises an infrared light emitting diode for emitting infrared light.

Preferably, the control circuit module comprises a first control point and a second control point; when only the first control point is electrified, the outer frame is lightened; when only the second control point is energized, the origin is lighted, and when the first control point and the second control point are energized simultaneously, the outer frame and the origin are lighted.

The application discloses a multi-element selected RCLED optical aiming chip, which is compared with the prior art:

the multi-element selected RCLED optical aiming chip provided by the application has a plurality of luminous modes, different luminous modes can be selected according to actual needs, and the shooting accuracy and convenience are improved.

Drawings

FIG. 1 is a schematic block diagram of red dot sighting electronics of the present application;

FIG. 2 is a schematic view of an embodiment of an optical generator module according to the present application;

fig. 3 is a schematic diagram of the internal structure of the chip according to the present application.

Detailed Description

The following describes in detail examples of the present application, which are implemented on the premise of the technical solution of the present application, and detailed implementation and specific operation procedures are given, but the scope of protection of the present application is not limited to the following examples.

As shown in fig. 1 and fig. 2, the present application is implemented by the following technical solutions: the application discloses a multiplex selective RCLED optical aiming chip, which comprises: the device comprises a power supply module, a control circuit module, a signal storage module, a feedback circuit module, a photoelectric generator module and a lens module;

the power supply module provides power for the infrared sighting telescope, and the control circuit module is connected with the feedback circuit module and the photoelectric generator module; the photoelectric generator module is connected with the lens module, and the signal storage module is connected with the photoelectric generator module.

For the application, the power module provides stable power for the whole system, provides needed voltage and current for the whole system, the control circuit module is connected with the signal storage module, the feedback circuit module and the photoelectric generator module, the control circuit module controls the luminous mode and the brightness of the photoelectric generator module according to the data in the signal storage module and the feedback information of the feedback circuit module, the photoelectric generator module is connected with the lens module, the luminous pattern is projected onto the lens module, and the lens module focuses the pattern and projects the pattern onto the sight of a user.

In one embodiment, the power module provides a stable power supply for the whole system, and the power module adopts a very low power consumption design, and can work for 5 ten thousand hours in standby when the power supply is at 210 milliampere hours. The power supply module can also automatically adjust output voltage and current according to the working state of the system so as to meet the energy consumption requirements in different working modes; in one embodiment, the control circuit module includes sensors such as jitter, gravity, and ambient temperature, and the entire system can be adjusted at any time according to the current environmental state. The control circuit module is also responsible for receiving operation instructions of a user, such as switching an aiming mode, adjusting brightness and the like, and transmitting the instructions to the MCU controller; in one embodiment, the feedback circuit module is responsible for collecting the working state information of each component of the system, such as the luminous state of the photoelectric generator, the output voltage and current of the power supply module, and the like, and feeding back the information to the control circuit module so as to correct various parameters according to actual conditions; in one embodiment, the photoelectric generator module is responsible for generating the aiming marks of the origin 1, the cross member 2, the round member 3, the square member and the like, and can also generate the aiming marks of dots, crosses plus circles or square frames and the like. The photoelectric generator module switches different light-emitting modes according to the instruction transmitted by the control circuit module and projects a light-emitting pattern onto the lens. In one embodiment, the lens module is responsible for focusing and projecting the luminous pattern generated by the photoelectric generator module onto the sight of the user so as to realize the function of assisting aiming; in one embodiment, the signal storage module: some data of the last operation, such as aiming mode, brightness, etc. selected by the user are mainly stored so as to quickly restore to the setting used by the user when the user starts next time.

The working flow of the whole system is as follows:

1. the user sends out instructions through the operation interface, such as switching aiming mode, adjusting brightness and the like;

2. after receiving the instruction, the control circuit module transmits the instruction to the MCU controller;

the MCU controller controls the photoelectric generator module to switch the light-emitting mode according to the instruction, and adjusts the light-emitting brightness;

4. the photoelectric generator module projects a luminous pattern onto the lens;

5. the lens module focuses and projects the luminous pattern onto the sight of a user to realize an auxiliary aiming function;

6. the feedback circuit module collects the working state information of each component of the system and feeds the information back to the control circuit module so as to correct various parameters according to actual conditions;

7. the signal storage module stores operation data of a user so as to quickly restore to the setting of the habit of the user when the signal storage module is started next time.

The examples of the present application are only for illustrating the present application and do not limit the scope of the present application.

In one embodiment, the pattern formed by the photoelectric generator comprises an outer frame and dots 1 positioned in the central area of the outer frame, the outer frame comprises a cross member 2 and a round member 3, the cross member 2 divides the round member 3 into four parts, the photoelectric generator module comprises an infrared light emitting diode and is used for emitting infrared light, and the control circuit module comprises a first control point a and a second control point b; when only the first control point a is electrified, the outer frame is lightened; when only the second control point b is energized, the origin 1 is lighted, and when the first control point a and the second control point b are energized simultaneously, the outer frame and the origin 1 are lighted, specifically, in the control circuit module, two input ports are provided and connected to the first control point a and the second control point b, respectively. Judging the power-on states of the first control point a and the second control point b by detecting the level states of the two ports; programming in the MCU controller, and sending corresponding control signals to the photoelectric generator module according to the detected power-on states of the first control point a and the second control point b. For example, when the first control point a is powered on and the second control point b is not powered on, a control signal for making the outer frame emit light is sent; when the second control point b is detected to be electrified and the first control point a is detected to be not electrified, a control signal for enabling the origin to emit light is sent; when the first control point a and the second control point b are detected to be electrified simultaneously, a control signal for enabling the outer frame and the origin to emit light simultaneously is sent, and the photoelectric generator module switches the corresponding light emitting mode according to the received control signal

In summary, for the present disclosure, the power module provides a stable power for the entire system, is connected to other modules, provides the required voltage and current for them, and the control circuit module is connected to the signal storage module, the feedback circuit module, and the photovoltaic generator module. The device controls the luminous mode and the brightness of the photoelectric generator module according to the data in the signal storage module and the feedback information of the feedback circuit module, the photoelectric generator module is connected with the lens module, the luminous pattern is projected onto the lens module, and the pattern is focused and projected onto the sight of a user by the lens module.

The foregoing is only a preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art should be able to apply to the present application and cover all modifications and equivalents thereof within the scope of the present application.

It should be noted that in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Claims (5)

1. A multiple choice RCLED optical aiming chip comprising: the device comprises a power supply module, a control circuit module, a signal storage module, a feedback circuit module, a photoelectric generator module and a lens module;

the power supply module provides power for the infrared sighting telescope, and the control circuit module is connected with the feedback circuit module and the photoelectric generator module; the photoelectric generator module is connected with the lens module, and the signal storage module is connected with the photoelectric generator module.

2. The multiple choice RCLED optical aiming chip as recited in claim 1, wherein the pattern formed by the photovoltaic generator includes a frame and dots located in a central region of the frame.

3. The multiple choice RCLED optical aiming chip of claim 2, wherein the housing comprises a cross member and a circular member, the cross member dividing the circular member into four parts.

4. A multiple choice RCLED optical aiming chip according to claim 3 wherein the photovoltaic generator module comprises an infrared light emitting diode for emitting infrared light.

5. The multiple choice, RCLED optical aiming chip of claim 4, wherein the control circuit module comprises a first control point and a second control point; when only the first control point is electrified, the outer frame is lightened; when only the second control point is energized, the origin is lighted, and when the first control point and the second control point are energized simultaneously, the outer frame and the origin are lighted.