CN214476326U - Laser projection host applied to laser display equipment and laser display equipment - Google Patents

Abstract

The embodiment that this application provided belongs to the display technology, provides a laser projection host computer and laser display device who is applied to laser display device, and this laser projection host computer includes: the device comprises a microprocessing unit (MCU), a foreign body detection circuit and a laser, wherein the MCU is respectively connected with the foreign body detection circuit and the laser; the foreign matter detection circuit is used for responding to the fact that foreign matters exist in a projection light outlet of the laser projection host machine and sending an interrupt signal to the MCU; and the MCU is used for turning off the laser based on the interrupt signal. In this application, MCU is direct to be connected with foreign matter detection circuitry, and MCU receives the interrupt signal back that comes from foreign matter detection circuitry, can directly close the laser instrument, avoids the foreign matter burning.

Description

Laser projection host applied to laser display equipment and laser display equipment

Technical Field

The embodiment of the application relates to a display technology. And more particularly, to a laser projection host and a laser display apparatus applied to the laser display apparatus.

Background

The laser television comprises a laser projection host and a projection screen, wherein a laser is arranged in the laser projection host. When the laser television normally works, laser emitted by the laser can be projected onto the projection screen through the projection light outlet of the laser projection host. If the projection light outlet is covered with foreign matters, such as curtains and paper, due to the shielding of the foreign matters, the laser is gathered in the laser projection host machine and cannot be emitted, and the foreign matters are burnt due to the gathering of the laser energy.

If the projection light outlet of the laser projection host machine is covered with foreign matters, the foreign matters such as curtains and paper can shield the projection light outlet, so that laser is gathered at the projection light outlet, and the gathering of laser energy can cause the burning of the foreign matters.

Disclosure of Invention

The exemplary embodiment of the application provides a laser projection host computer and laser display equipment for laser display equipment, can close the laser instrument in quick response to detecting the foreign matter, avoids the foreign matter burning.

In a first aspect of the present application, a laser projection host applied to a laser display device is provided, where the laser projection host may include: the device comprises a microprocessing unit (MCU), a foreign matter detection circuit and a laser, wherein the MCU is respectively connected with the foreign matter detection circuit and the laser; the foreign matter detection circuit is used for responding to the fact that foreign matters exist at a projection light outlet of the laser projection host machine and sending an interrupt signal to the MCU; and the MCU is used for closing the laser based on the interrupt signal.

In the embodiment of the application, because MCU is direct to be connected with foreign matter detection circuitry, MCU receives behind the interrupt signal who comes from foreign matter detection circuitry, can directly close the laser instrument, need not to wait to close the laser instrument based on the close command that comes from the mainboard, and response speed is fast.

In some embodiments of the present application, the MCU includes a first interrupt pin, the foreign object detection circuit includes a foreign object detection sensor, the foreign object detection sensor includes a second interrupt pin, and the first interrupt pin is connected to the second interrupt pin; the foreign object detection sensor is specifically configured to control the second interrupt pin to output a first falling edge in response to detecting the foreign object, where the first falling edge is used to characterize the interrupt signal; the MCU is specifically configured to turn off the laser in response to detecting the first falling edge.

In the embodiment of the application, the MCU can determine that foreign matters exist on the laser projection host machine in a mode of detecting the second interruption pin output falling edge of the foreign matter detection sensor, and then quickly close the laser.

In some embodiments of the present application, the MCU further comprises a first data SDA pin, and the foreign object detection sensor further comprises a second SDA pin, the first SDA pin being connected to the second SDA pin via an integrated circuit bus IIC.

In some embodiments of the present application, the foreign object detection circuit further includes: the foreign matter detection sensor is connected with the photoelectric detection diode; the MCU is further used for setting a first threshold value for the foreign matter detection sensor through the IIC; the infrared photodiode is used for emitting pulse infrared rays; the photoelectric detection diode is used for detecting infrared light reflected by the foreign matters; the foreign matter detection sensor is configured to control the second interrupt pin to output the first falling edge when the number of times of detecting the reflected infrared light detected by the photodetection diode is greater than the first threshold value.

In the embodiment of the application, MCU can set up first threshold value for foreign matter detection sensor in advance, and when the number of times of the infrared light of the reflection that foreign matter detection sensor detected exceeded this first threshold value, foreign matter detection sensor output first fell along, can avoid MCU spurious triggering to close the problem of laser instrument.

In some embodiments of the present application, the MCU is further configured to set a second threshold for the foreign object detection sensor through the IIC, where the second threshold is smaller than the first threshold; the foreign matter detection sensor is further configured to control the second interrupt pin to output a second falling edge when the number of times of detection is smaller than the second threshold value; the MCU is further used for turning on the laser if the second falling edge is detected after the laser is turned off.

In this application embodiment, MCU can set up the second threshold value for foreign matter detection sensor in advance, and when the number of times of the infrared light of reflection that foreign matter detection sensor detected was less than this second threshold value, can export the second falling edge to make laser projection host computer normally work.

In some embodiments of the present application, the laser projection host further comprises: the main board is respectively connected with the power panel and the MCU; the power panel is used for supplying power to the mainboard; the main board is used for controlling the MCU to be opened or closed.

In some embodiments of the present application, the laser projection host further comprises: the laser driving circuit is connected with the MCU, the laser driving circuit is connected with the laser, and the power panel is connected with the laser driving circuit; the power panel is used for supplying power to the laser driving circuit; and the MCU is specifically used for controlling the laser driving circuit to stop supplying power to the laser so as to close the laser.

In some embodiments of the present application, the laser projection host further comprises: the digital light processor DLP and the digital micromirror device DMD are respectively connected with the mainboard and the DMD; the main board is further used for sending content to be displayed to the DLP; and the DLP is used for driving the DMD to display the content to be displayed.

In some embodiments of the present application, the laser projection host further comprises: the MCU is respectively connected with the fan and the temperature sensor; the temperature sensor is used for detecting the temperature of the DMD; and the MCU is used for controlling the fan to rotate at a preset rotating speed.

In a second aspect of the present application, there is provided a laser display device, comprising a projection screen and the laser projection host as described above in the first aspect.

The embodiment of the application provides a laser projection host computer and laser display device for laser display device, this laser projection host computer can include: the device comprises a microprocessing unit (MCU), a foreign body detection circuit and a laser, wherein the MCU is respectively connected with the foreign body detection circuit and the laser; the foreign matter detection circuit is used for responding to the fact that foreign matters exist in a projection light outlet of the laser projection host machine and sending an interrupt signal to the MCU; and the MCU is used for turning off the laser based on the interrupt signal. In this application, MCU is direct to be connected with foreign matter detection circuitry, and MCU receives behind the interrupt signal who comes from foreign matter detection circuitry, can directly close the laser instrument, need not to wait to close the laser instrument based on the command of closing that comes from the mainboard, and response speed is fast.

Drawings

In order to more clearly illustrate the embodiments of the present application or the implementation manner in the related art, a brief description will be given below of the drawings required for the description of the embodiments or the related art, and it is obvious that the drawings in the following description are some embodiments of the present application, and other drawings can be obtained by those skilled in the art according to the drawings.

FIG. 1 is a schematic diagram illustrating an operational scenario between a display device and a control device according to some embodiments;

a schematic structural diagram of a display device according to some embodiments is illustrated in fig. 2;

a timing diagram of a laser display device according to some embodiments is illustrated in fig. 3;

fig. 4 illustrates an arrangement position of the foreign matter detection plate of some embodiments;

fig. 5A illustrates a schematic structural view of a foreign object detection plate according to some embodiments;

a schematic diagram of a laser display device according to some embodiments is illustrated in fig. 5B;

a schematic diagram of a laser projection host according to some embodiments is illustrated in fig. 6;

an interactive schematic diagram of elements in a laser projection host according to some embodiments is illustrated in fig. 7;

fig. 8 illustrates a schematic connection diagram of a main board and a foreign object detection sensor according to some embodiments;

a timing diagram of a laser display device according to some embodiments is illustrated in fig. 9;

FIG. 10 illustrates a schematic diagram of infrared light emitted by an infrared emitter, in accordance with some embodiments;

a schematic diagram illustrating the interaction of various elements in a laser projection host, according to some embodiments, is illustrated in fig. 11;

a schematic triggering diagram of a foreign object detection sensor according to some embodiments is illustrated in fig. 12;

an operational schematic of a motherboard according to some embodiments is illustrated in fig. 13A;

FIG. 13B illustrates a timing diagram of the operation of a laser projection host, according to some embodiments;

FIG. 14 is a schematic diagram illustrating the structure of a laser projection host, according to some embodiments;

a timing diagram of a laser display device according to some embodiments is illustrated in fig. 15;

FIG. 16 is a schematic diagram illustrating the structure of a laser projection host, according to some embodiments;

a flow diagram of an MCU according to some embodiments is illustrated in fig. 17.

Description of reference numerals:

control device-100;

display device-200;

a projection screen-201;

laser projection host-202;

foreign matter detection plate-2021;

PCB-20211;

a foreign matter detection sensor-20212;

rubber pad-20213;

infrared emitter-20214;

infrared receiver-20215;

emission window-20216;

receive window-20217;

partition-20218;

a projection light outlet-2022;

a power panel-2023;

a main board-2024;

a power amplifier-20241;

SOC-20242；

optical machine display panel-2025;

MCU-20251；

DLP-20252；

laser driver circuit-2026;

laser-2027;

DMD-2028；

socket-2029;

a fan-2030;

temperature sensor-2031;

speaker-2032;

foreign object detection circuit-2033;

a mobile terminal-300;

a server-400.

Detailed Description

To make the objects, embodiments and advantages of the present application clearer, the following description of exemplary embodiments of the present application will clearly and completely describe the exemplary embodiments of the present application with reference to the accompanying drawings in the exemplary embodiments of the present application, and it is to be understood that the described exemplary embodiments are only a part of the embodiments of the present application, and not all of the embodiments.

All other embodiments, which can be derived by a person skilled in the art from the exemplary embodiments described herein without inventive step, are intended to be within the scope of the claims appended hereto. In addition, while the disclosure herein has been presented in terms of one or more exemplary examples, it should be appreciated that aspects of the disclosure may be implemented solely as a complete embodiment.

It should be noted that the brief descriptions of the terms in the present application are only for the convenience of understanding the embodiments described below, and are not intended to limit the embodiments of the present application. These terms should be understood in their ordinary and customary meaning unless otherwise indicated.

The terms "first," "second," "third," and the like in the description and claims of this application and in the above-described drawings are used for distinguishing between similar or analogous objects or entities and are not necessarily intended to limit the order or sequence of any particular one, Unless otherwise indicated. It is to be understood that the terms so used are interchangeable under appropriate circumstances such that the embodiments described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein.

Furthermore, the terms "comprises" and "comprising," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a product or device that comprises a list of elements is not necessarily limited to those elements explicitly listed, but may include other elements not expressly listed or inherent to such product or device.

The term "module," as used herein, refers to any known or later developed hardware, software, firmware, artificial intelligence, fuzzy logic, or combination of hardware and/or software code that is capable of performing the functionality associated with that element.

The term "remote control" as used in this application refers to a component of an electronic device (such as the display device disclosed in this application) that is typically wirelessly controllable over a relatively short range of distances. Typically using infrared and/or Radio Frequency (RF) signals and/or bluetooth to connect with the electronic device, and may also include WiFi, wireless USB, bluetooth, motion sensor, etc. For example: the hand-held touch remote controller replaces most of the physical built-in hard keys in the common remote control device with the user interface in the touch screen.

The term "gesture" as used in this application refers to a user's behavior through a change in hand shape or an action such as hand motion to convey a desired idea, action, purpose, or result.

A schematic diagram of an operational scenario between a display device and a control device according to some embodiments is illustrated in fig. 1. As shown in fig. 1, a user may operate the display device 200 through the mobile terminal 300 and the control device 100.

In some embodiments, the control device 100 may be a remote controller, and the communication between the remote controller and the display device includes an infrared protocol communication or a bluetooth protocol communication, and other short-distance communication methods, etc., and the display device 200 is controlled by wireless or other wired methods. The user may input a user command through a key on a remote controller, voice input, control panel input, etc. to control the display apparatus 200. Such as: the user can input a corresponding control command through a volume up/down key, a channel control key, up/down/left/right moving keys, a voice input key, a menu key, a power on/off key, etc. on the remote controller, to implement the function of controlling the display device 200.

In some embodiments, mobile terminals, tablets, computers, laptops, and other smart devices may also be used to control the display device 200. For example, the display device 200 is controlled using an application program running on the smart device. The application, through configuration, may provide the user with various controls in an intuitive User Interface (UI) on a screen associated with the smart device.

In some embodiments, the mobile terminal 300 may install a software application with the display device 200 to implement connection communication through a network communication protocol for the purpose of one-to-one control operation and data communication. Such as: the mobile terminal 300 and the display device 200 can establish a control instruction protocol, synchronize a remote control keyboard to the mobile terminal 300, and control the display device 200 by controlling a user interface on the mobile terminal 300. The audio and video content displayed on the mobile terminal 300 can also be transmitted to the display device 200, so as to realize the synchronous display function.

As also shown in fig. 1, the display apparatus 200 also performs data communication with the server 400 through various communication means. The display device 200 may be allowed to be communicatively connected through a Local Area Network (LAN), a Wireless Local Area Network (WLAN), and other networks. The server 400 may provide various contents and interactions to the display apparatus 200. The exemplary display device 200 receives software program updates, or accesses a remotely stored digital media library by sending and receiving information, as well as Electronic Program Guide (EPG) interactions. The server 400 may be a cluster or a plurality of clusters, and may include one or more types of servers. Other web service contents such as video on demand and advertisement services are provided through the server 400.

The display apparatus 200 may additionally provide an intelligent network tv function of a computer support function including, but not limited to, a network tv, an intelligent tv, an Internet Protocol Tv (IPTV), and the like, in addition to the broadcast receiving tv function.

The display device 200 may be a liquid crystal display, an OLED display, a projection display device. The particular display device type, size, resolution, etc. are not limiting, and those skilled in the art will appreciate that the display device 200 may be modified in performance and configuration as desired.

In some embodiments, a schematic structural diagram of a display device according to some embodiments is illustrated in fig. 2. As shown in fig. 2, the display device 200 may be a laser display device. The laser display device includes a projection screen 201 and a laser projection host 202. And the laser projection host 202 is used for emitting laser and projecting the content to be displayed on the projection screen 201. And the projection screen 201 is used for displaying the content to be displayed. The content to be displayed may be, but not limited to, pictures, videos, and the like. It should be understood that the laser display device 200 is illustrated as a laser display device in fig. 2.

The operation of the laser display device is explained below with reference to fig. 3. A timing diagram of a laser display device according to some embodiments is illustrated in fig. 3. In some embodiments, the laser projection host may include: the digital micromirror device comprises a power panel, a mainboard, an optical machine display panel, a laser driving circuit, a laser and a Digital Micromirror Device (DMD). The motherboard may be provided with a System On Chip (SOC), and the optical display panel may be provided with an optical Micro Control Unit (MCU) and a Digital Light Processing (DLP). In the following embodiments, a motherboard is used instead of the SOC, and the motherboard is described as an execution subject for executing the embodiments of the present application, that is, the motherboard in the following embodiments may be replaced with the "SOC".

At time t1, the motherboard is configured to receive a power-on signal or a power-off signal (the power-on signal is taken as an example for the following description). In some embodiments, the motherboard may receive a power-on signal from a remote control. Or, in some embodiments, the main board is configured to detect that a user triggers a power-on key, that is, receives a power-on signal. When the laser display device is in the power-off state, the power panel is in the standby mode. At time t2, the motherboard receives the power-on signal, and the motherboard can send the power-on signal to the power board. At time t3, the power board exits from the standby mode, and the power board exiting from the standby mode can supply power to the motherboard. In some embodiments, the way for the motherboard to send the power board the power-on signal may be: the main board pulls high the STB signal that is output to the power strip.

At time t4, the main board can control the light machine display board to be powered on, and the MCU starts working. At time t5, the MCU may control the fan connected thereto to start operating, and for example, the MCU may control the fan to rotate at a preset speed. At time t6, the MCU may also control the DLP to power up. After the DLP is electrified, the DMD can be driven to be started. At time t7, the MCU may also drive a laser driver circuit to illuminate the laser so that the laser emits laser light. In some embodiments, the MCU may pull up an input level (LASER _ EN) output to the LASER driving circuit, thereby causing the LASER driving circuit to output a high level to power the LASER, thereby lighting the LASER. Laser light emitted from the laser may be irradiated onto the DMD. After the DLP is powered on, the mainboard can send the content to be displayed to the DLP. The DLP may drive the DMD, and display the content to be displayed using laser light irradiated on the DMD.

When the laser projection host is covered with foreign matters, such as curtains, paper and the like, laser emitted by the laser is gathered in the laser projection host, and the burning of the foreign matters is easily caused. In one embodiment, a foreign object detection function may be added to the laser display device to detect whether a foreign object is covered on the laser projection host. Wherein, when laser display device detects that laser projection host computer coats and is stamped the foreign matter, laser display device can close the laser instrument, avoids laser energy gathering, and then avoids the foreign matter burning.

In some embodiments, a foreign object detection function is added to the laser display device, and a foreign object detection plate 2021 may be provided in the laser projection host 202. And a foreign substance detection plate 2021 for detecting whether or not the laser projection host 202 is covered with a foreign substance. The position of the foreign matter detection plate of some embodiments is exemplarily shown in fig. 4. As shown in fig. 4, a foreign substance detection plate 2021 may be disposed on one side of a projection light outlet 2022 of the laser projection host 202, the projection light outlet 2022 for projecting laser light to the projection screen 201.

In some embodiments, a schematic structural view of a foreign object detection plate according to some embodiments is exemplarily shown in fig. 5A. As shown in fig. 5A, the foreign substance detection plate 2021 may include a Printed Circuit Board (PCB) 20211, and the PCB 20211 is provided with a foreign substance detection sensor 20212 and a rubber pad 20213. The rubber pad 20213 is provided with two concave grooves, the first groove is provided with an infrared emitter 20214, and the second groove is provided with an infrared receiver 20215. The infrared transmitter 20214 may be, but is not limited to, an infrared photodiode, and the infrared receiver 20215 may be, but is not limited to, a photodetector diode. A black partition 20218 is provided between the two grooves. An emission window 20216 is disposed above the first groove, and a reception window 20217 is disposed above the second groove. The foreign object detection sensor 20212 may be connected to the infrared receiver 20215 and the main board, respectively. It is to be understood that the connection between the foreign object detection sensor 20212 and the infrared receiver 20215 is not shown in fig. 5A.

A schematic diagram of a laser display device according to some embodiments is illustrated in fig. 5B. It should be understood that fig. 5B is a front view of the laser display apparatus. As shown in fig. 5A and 5B, an infrared emitter 20214 for emitting infrared rays. The infrared emitter 20214 emits infrared rays in the same direction as the laser light projected from the projection light outlet 2022. If there is a foreign object covering on the laser projection host, the laser light will not be projected and will be collected in the laser projection host, because the direction of the infrared ray in the embodiment of the present application is the same as the direction of the laser light, the foreign object will also block the infrared ray, and therefore the infrared ray will be reflected due to the blocking of the foreign object, as shown in fig. 4. In the embodiment of the present application, the infrared receiver 20215 is used to detect infrared light reflected by a foreign object. It should be appreciated that the black partition 20218 between the first and second slots avoids cross talk between the infrared transmitter 20214 and the infrared receiver 20215. Since the infrared rays emitted from the infrared emitter 20214 would most likely be directly detected by the infrared receiver 20215 if there were no black partition 20218, thereby causing false detection. In some embodiments, the emission angle at which the infrared emitter 20214 emits infrared light may be, but is not limited to, 15 °, and the reception angle at which the infrared receiver 20215 detects reflected infrared light may be, but is not limited to, 30 °.

The foreign object detection sensor 20212 may detect the reflected infrared light received by the infrared receiver 20215, thereby determining that the laser projection host is covered with the foreign object. Because the foreign object detection sensor 20212 can be connected to the motherboard, the foreign object detection sensor 20212 can communicate with the motherboard to notify the motherboard of the presence of a foreign object on the laser projection host. In this way, the mainboard can control the laser to close, and then reaches the purpose of avoiding laser energy gathering, avoids the foreign matter burning.

The following describes a principle of turning off a laser in a laser projection host according to an embodiment of the present application, with reference to a structure of the laser projection host. The following embodiments may be combined with each other, and the same concept is not described in detail. A schematic diagram of a laser projection host according to some embodiments is illustrated in fig. 6. As shown in fig. 6, the laser projection host 202 may include: a power supply board 2023, a main board 2024, an optical machine display board 2025, a laser driving circuit 2026, a laser 2027, a DMD2028, and a foreign substance detection board 2021. The foreign substance detection plate 2021 includes a foreign substance detection sensor 20212. The functions of the "power board 2023, main board 2024, optical display board 2025, laser driver circuit 2026, laser 2027, and DMD 2028" may refer to the related descriptions in fig. 2. The structure of the foreign substance detection plate 2021 may be described with reference to fig. 5A described above.

The optical display panel 2025 may include: the MCU20251 and the DLP20252 may refer to the related descriptions in the above embodiments. In this embodiment, the power board 2023 may be connected to the motherboard 2024 and the laser driver circuit 2026, respectively. And the power supply board 2023 is used for supplying power to the main board 2024 and the laser driving circuit 2026. The main board 2024 may be connected to the MCU20251, the DLP20252, and the foreign substance detection sensor 20212, respectively. DLP20252 is connected to DMD2028, and in some embodiments DLP20252 may be connected to DMD2028 through socket 2029. The MCU20251 may be connected with a laser driver circuit 2026. The laser driver circuit may be connected to the laser 2027.

In some embodiments, the laser projection host 202 may further include: fan 2030, and temperature sensor 2031. The MCU20251 may be connected to the fan 2030 and the temperature sensor 2031, respectively. The temperature sensor 2031 is used to detect the temperature of the DMD 2028. In some embodiments, the temperature sensor 2031 may be a Negative Temperature Coefficient (NTC) temperature sensor 2031.

In some embodiments, the motherboard 2024 may further comprise: a power amplifier 20241 (power amplifier for short). The SOC20242 on the motherboard 2024 may be connected to the power amplifier via IIC on the one hand, and on the other hand, the SOC20242 may be connected to the power amplifier 20241 via a clock pin (CLK). The power amplifier 20241 may be connected to at least one speaker 2032, where the speaker 2032 may be a speaker 2032 disposed in the laser projection host 202, or may also be a speaker 2032 disposed in the laser display device, which is not limited herein, and fig. 6 exemplarily shows that the speaker 2032 includes a left speaker 2032L and a right speaker 2032R. In some embodiments, the connections between the components of the laser projection host 202 (including the power board 2023, the motherboard 2024, the optical display board 2025, the laser driving circuit 2026, the laser 2027, the DMD2028, and the foreign object detection board 2021) may be realized through pins in the components.

The following describes a response operation of the laser projection host 202 when the laser projection host 202 is covered with a foreign object, with reference to the structure shown in fig. 6 and the interaction diagram between the elements shown in fig. 7. As shown in fig. 7, the process may include:

and S701, when the foreign matter detection plate detects the foreign matter, sending an interrupt signal to the main board.

In some embodiments, the foreign substance detection sensor 20212 is included in the foreign substance detection plate 2021. According to the description of the above embodiments, when the foreign object detection sensor 20212 determines that the infrared receiver detects the reflected infrared light, the foreign object detection sensor 20212 may transmit an interrupt signal to the main board 2024. The interrupt signal is used to indicate that the laser projection host 202 is covered with foreign objects.

S702, the main board sends a closing command to the MCU based on the interrupt signal, and the closing command is used for indicating the MCU to close the laser.

The motherboard 2024, receiving the interrupt signal, may send a shutdown command to the MCU 20251. In some embodiments, an indication bit for instructing the MCU20251 to turn off the laser 2027 may be included in the turn-off command.

And S703, the MCU closes the laser based on the closing command.

The MCU20251, receiving the turn-off command, may turn off the laser 2027. In some embodiments, the MCU20251 can control the laser driver circuit 2026 to power down the laser 2027 to turn off the laser 2027. In some embodiments, the MCU20251 may pull down the level of a pin (LASER _ EN) connected to the LASER driver circuit 2026 to control the LASER driver circuit 2026 to power down the LASER 2027, thereby turning off the LASER 2027.

In this embodiment, the foreign object detection board 2021 may detect whether the laser projection host 202 is covered with a foreign object, and when the foreign object is covered, the main board 2024 may control the MCU20251 to turn off the laser 2027, so as to interrupt the emission of laser light, thereby avoiding the hidden danger of burning of the foreign object caused by the accumulation of laser energy.

In some embodiments, if the user's hand is quickly flashing on the laser projection host 202, the foreign object detection sensor 20212 may also detect a foreign object, and the motherboard 2024 may turn off the laser 2027, but the user does not intend to turn off the laser 2027. To avoid the problem of the main board 2024 triggering the laser 2027 to be turned off by mistake, the main board 2024 may set a threshold value for the foreign substance detection sensor 20212 in advance, and when the number of times of reflected infrared light detected by the foreign substance detection sensor 20212 exceeds the threshold value, the main board 2024 may turn off the laser 2027 in response to an interrupt signal. As shown in fig. 6, in some embodiments, the motherboard 2024 may be connected to the MCU20251 through an inter-integrated circuit (IIC) bus. The mainboard 2024 can be connected with the DLP20252 through a signal transmission interface V-by-One. DLP20252 may be connected to DMD2028 through HSSI0 interface and/or HSSI1 interface, and socket 2029. The MCU20251 may be connected to the DLP20252 through the IIC. The motherboard 2024 may be connected to the foreign object detection sensor 20212 through the IIC, and the motherboard 2024 may be further connected to a second interrupt pin (INT pin) on the foreign object sensor through a first interrupt pin (INT pin) on the motherboard 2024.

In some embodiments, the connection structure of the foreign object detection sensor 20212 and the main board 2024 may be as shown in fig. 8. Referring to fig. 8, the foreign object detection sensor may be connected to the pins on the main board 2024 through 3 pins. The pins on the motherboard 2024 are a first clock SCL pin, a first data SDA pin, and a general-purpose input/output (GPIO) pin, respectively, the GPIO pin on the motherboard 2024 may be referred to as an INT pin, and the INT pin may be a first interrupt pin. The pins on the foreign object transmission detection sensor can be a second SCL pin, a second SDA pin, and a second interrupt pin, respectively. The first SDA pin and the second SDA pin are connected through the IIC. The first SDA pin is connected with the second SDA pin through the IIC, the first SCL pin is connected with the second SCL pin, and the first interrupt pin is connected with the second interrupt pin. The first interrupt pin may also be referred to as a first INT pin and the second interrupt pin may also be referred to as a second INT pin. It should be understood that "the first SDA pin is connected with the second SDA pin through IIC" is characterized by IIC in fig. 6, "the first interrupt pin is connected with the second interrupt pin" is characterized by INT, and the connection of the first SCL pin with the second SCL pin is not shown in fig. 6.

The motherboard 2024 may send a clock signal to the foreign object detection sensor 20212 through the first SCL pin and the second SCL pin. For example, the clock signal may be a signal for indicating that the foreign object detection sensor 20212 is turned on or off. The main board 2024 may send a data signal to the foreign object detection sensor 20212 through the first SDA pin and the second SDA pin. For example, the data signal may be a threshold value set by the main board 2024 for the foreign object detection sensor 20212 (specifically, refer to the description in the following embodiments). The main board 2024 may determine whether the foreign object detection sensor 20212 detects a foreign object through the first interrupt pin and the second interrupt pin, that is, the main board 2024 may detect an interrupt signal through the first interrupt pin and the second interrupt pin.

A timing diagram for the laser projection host 202 according to some embodiments is illustrated in fig. 9. The working principle of the laser projection host 202 provided by the embodiment of the present application is further described below with reference to fig. 6 and 9. Fig. 9 is different from fig. 3 in that when the power board 2023 supplies power to the motherboard 2024, the motherboard 2024 may initialize the foreign object detection sensor 20212 through the IIC (i.e., the first SDA pin and the second SDA pin) to set a threshold for the foreign object detection sensor 20212. In some embodiments, the threshold may include: a threshold of the number of times the reflected infrared light is detected by the infrared receiver. The threshold may include a first threshold and a second threshold, the second threshold being less than the first threshold. The first threshold may be referred to as an upper threshold value PS _ THDH _ H and the second threshold may be referred to as a lower threshold value PS _ THDH _ L. It is to be understood that the first threshold value is a threshold value of "the number of times the reflected infrared light is detected by the infrared receiver" that triggers the output of the interrupt signal by the foreign object detection sensor 20212.

In some embodiments, the infrared emitted by infrared emitter 20214 is periodically pulsed infrared. In practical applications, since the infrared rays emitted from the infrared emitter 20214 are reflected by the projection screen 201, there is a problem of false triggering caused by being detected by the infrared receiver 20215, and since the emission distance of the infrared emitter 20214 is inversely proportional to the current of the foreign object detection sensor 20212, in order to avoid the influence of the infrared rays reflected by the projection screen 201, the current of the foreign object detection sensor 20212 needs to be adjusted to adjust the emission distance of the pulsed infrared rays. In some embodiments, the current of the foreign object detection sensor 20212 may be in the range of 50mA to 200 mA. In some embodiments, the main board 2024 may set the current IRED _ I of the foreign object detection sensor 20212 in the register PS _ CONF of the foreign object detection sensor 20212 by IIC.

In some embodiments, the main board 2024 may set the integration time t, i.e., the pulse length PS _ IT, the number of pulses PS _ MPS, and the duty ratio of infrared rays emitted by the infrared receiver 20215, for the foreign object detection sensor 20212 through the IIC, in consideration of the actual detection distance of the infrared receiver 20215, and the power consumption of the foreign object detection sensor 20212. Wherein the pulse length is used to characterize the time from the time signal when the pulse generation starts to the time when the pulse ends. The number of pulses is used to characterize the number of pulses per unit time (e.g., 1 second). The duty cycle is used to characterize the proportion of the energization time relative to the total time within a pulse cycle. In some embodiments, the main board 2024 sets the duty ratio for the foreign object detection sensor 20212 to be in the range of 1/160 to 1/1280. It is understood that the higher the number of pulses, the higher the sensitivity of the foreign object detection sensor 20212. A schematic diagram of infrared light emitted by an infrared emitter according to some embodiments is illustrated in fig. 10. As shown in FIG. 10, the infrared emitter 20214 emits infrared light with a period T₀The pulse length may be t, and the infrared receiver 20215 emits infrared rays including infrared ray 1, infrared ray 2, infrared ray 3 … … and infrared ray n.

A schematic diagram illustrating the interaction of various elements in a laser projection host, according to some embodiments, is illustrated in fig. 11. As shown in fig. 11, the process may include:

and S1101, when the foreign matter detection sensor detects the foreign matter, controlling the second interrupt pin to output a first falling edge.

A process of detecting foreign substances by the foreign substance detection sensor 20212 will be described below with reference to fig. 12. It should be understood that, during normal operation of the laser projection host 202, the level of the second interrupt pin on the foreign object detection sensor 20212 may be a high level, which may be greater than a third preset level, for example. At the time a, the infrared receiver 20215 may detect the infrared light reflected once, and if the laser projection host 202 is covered with the foreign object, the infrared receiver 20215 may detect the reflected infrared light multiple times continuously. The number of times of reflected infrared light detected by the infrared receiver 20215 at time b is greater than or equal to the first threshold value. When the foreign object detection sensor 20212 determines that the number of times the reflected infrared light is detected by the infrared receiver 20215 is greater than or equal to the first threshold, an interrupt signal may be issued at time c, e.g., the foreign object detection sensor 20212 may begin to pull down the level of the second interrupt pin on the foreign object detection sensor 20212.

S1102, the motherboard detects that the second interrupt pin outputs the first falling edge.

The first interrupt pin on the motherboard 2024 detects the level of the second interrupt pin. At the time d, the first interrupt pin on the motherboard 2024 detects that the level of the second interrupt pin decreases from the high level to the low level, and the low level may be less than the fourth preset level. That is, the first interrupt pin detects that the second interrupt pin outputs the first falling edge. When the main board 2024 detects that the second interrupt pin outputs the first falling edge, the main board 2024 may determine that the laser projection host 202 is covered by the foreign object. In other words, if the first interrupt pin on the motherboard 2024 detects that the second interrupt pin outputs the first falling edge, that is, the motherboard 2024 receives the interrupt signal from the foreign object detection sensor 20212, the motherboard 2024 can determine that the laser projection host 202 is covered with the foreign object.

At time d, the motherboard 2024 may modify the flag bit in the register of the second interrupt pin from 1 to 0 in response to the first falling edge. Wherein, the change of the flag bit (flag) of the second interrupt pin may be as shown in fig. 12. Correspondingly, the second interrupt pin may be released when the second interrupt pin detects a change in a flag bit in a register of the second interrupt pin, and the level of the second interrupt pin may be automatically raised to a high level, for example, greater than a third preset level. Wherein the level of the second interrupt pin may vary as shown in fig. 12.

S1103, the main board sends a close command to the MCU.

The main board 2024 may send a turn-off command to the MCU20251 through the IIC in response to the first falling edge to control the MCU20251 to turn off the laser 2027.

And S1104, the MCU responds to the closing command and controls the laser driving circuit to close the laser.

It should be understood that the implementation in S1104 may refer to the description related to the above embodiment S703.

In some embodiments, the main board 2024 may also be provided with a second threshold value for the foreign object detection sensor 20212. At the time e, when the foreign object detection sensor 20212 determines that the number of times of the reflected infrared light detected by the infrared receiver 20215 is less than the second threshold value, the foreign object detection sensor 20212 may determine that the foreign object has moved away, and the foreign object detection sensor 20212 may further issue an interrupt signal, such as the foreign object detection sensor 20212 starting to pull down the level of the second interrupt pin. When the first interrupt pin on the motherboard 2024 detects that the second interrupt pin outputs the second falling edge, the motherboard 2024 may determine that the foreign object covered on the laser projection host 202 has been removed. In such an embodiment, the motherboard 2024 may send an open command to the MCU20251 through the IIC to achieve the purpose of the MCU20251 to turn on the laser 2027. In some embodiments, the MCU20251 can control the laser drive circuit 2026 to power the laser 2027 to turn on the laser 2027.

In summary, the operation of the motherboard 2024 can be as shown in fig. 13A. Referring to fig. 13A, after the laser display device is powered on, the main board 2024 may execute a main program, such as the main board 2024 controlling the optical machine display panel 2025 to be powered on, and transmit the content to be displayed to the DLP 20252. When the main board 2024 receives an interrupt signal (which may also be referred to as an interrupt request) from the foreign object detection sensor 20212, an interrupt program may be executed, such as the main board 2024 sending a turn-off command to the MCU20251 to turn off the laser 2027. In some embodiments, after the main board 2024 executes the interrupt routine, an interrupt response may be returned to the foreign object detection sensor 20212 to notify the foreign object detection sensor 20212 that the laser 2027 is turned off, indicating that the foreign object detection sensor 20212 continues to monitor whether the foreign object is removed.

It should be understood that the timing diagram of the operation of the laser projection host 202 can be as shown in fig. 13B. Referring to fig. 13B, at time T1, the foreign object detection sensor 20212 detects a foreign object, and controls the second interrupt pin to output the first falling edge. At time T2, the motherboard 2024 detects that the second interrupt pin outputs the first falling edge. At time T3, the motherboard 2024 sends a shutdown command to the MCU 20251. At time T4, the MCU20251 controls the laser drive circuit 2026 to turn off the laser 2027 in response to the turn-off command.

In this embodiment, the motherboard 2024 may determine whether the laser projection host 202 is covered with the foreign object by detecting the level change of the second interrupt pin of the foreign object detection sensor 20212, and then when the laser projection host 202 is covered with the foreign object, the motherboard 2024 may control the laser 2027 to close by sending a close command to the MCU20251, thereby avoiding the burning of the foreign object.

As in the above embodiment, the foreign substance detection sensor 20212 is connected to the main board 2024, and the main board 2024 can quickly respond to and execute the interrupt processing program based on the falling edge output by the foreign substance detection sensor 20212, but the MCU20251 is an IIC slave device of the main board 2024, and the MCU20251 executes the IIC command serially, and the internal program thereof is also executed serially, so that the MCU20251 has low efficiency in executing the shutdown command. Illustratively, the motherboard 2024 executes an interrupt routine and sends a shutdown command to the MCU 20251. However, if the MCU20251 is executing other commands (programs), the MCU20251 needs to serially execute the other commands to respond to the shutdown command. Therefore, the MCU20251 in the above-described embodiment cannot respond to the shutdown command quickly, and there is still a risk of foreign object combustion.

The embodiment of the application provides a laser projection host 202, MCU20251 can be directly connected with the device (such as foreign matter detection circuit) that detects the foreign matter, and then when MCU20251 determines that there is the foreign matter on laser projection host 202, can directly close laser 2027, compare in the prior art by the mode that mainboard 2024 sent the close command to MCU20251, need not to wait for the response close command, response speed is fast, can avoid the foreign matter burning.

A schematic diagram of the structure of a laser projection host according to some embodiments is illustrated in fig. 14. As shown in fig. 14, the laser projection host 202 may include: a microprocessing unit MCU20251, a foreign substance detection circuit 2033 and a laser 2027, wherein the MCU20251 is connected to the foreign substance detection circuit 2033 and the laser 2027 respectively.

In this embodiment, when the laser projection host 202 is powered on, the MCU20251 may drive the laser 2027 to start working. A laser 2027 for emitting laser light. The MCU20251 drives the laser 2027 to operate as described above with reference to the above embodiments.

In some embodiments, the foreign object detection circuit 2033 may be the foreign object detection plate 2021 in the above embodiments, and the foreign object detection circuit 2033 is used to detect whether a foreign object exists in the projection light outlet 2022 of the laser projection host 202. In some embodiments, the foreign object detection circuit 2033 may include a camera for capturing an image of the projection light outlet 2022 and identifying whether a foreign object is included in the image. The camera can be used for inputting the collected images into the recognition model so as to obtain a result of recognizing the foreign matters by the recognition model. In some embodiments, the recognition model is obtained by taking a large number of images of the foreign object as sample data and performing deep learning training. The sample data may include images of various types of foreign objects, such as curtains, paper, a user's hand, and the like.

In some embodiments, the foreign object detection circuit 2033 detects foreign objects in a manner as described above with reference to the above embodiments.

In this embodiment, since the foreign object detection circuit 2033 is directly connected to the MCU20251, when the foreign object detection circuit 2033 detects a foreign object, an interrupt signal can be sent to the MCU20251, where the interrupt signal is used to indicate that a foreign object exists on the laser projection host 202. The MCU20251 may be configured to receive the interrupt signal from the foreign object detection circuit 2033 and to turn off the laser 2027 based on the interrupt signal.

In some embodiments, the MCU20251 may be connected to a first terminal of a switch, and a second terminal of the switch may be connected to the laser 2027. The MCU20251 can turn on the switch, thereby turning on the laser 2027. The MCU20251 can turn off the switch, which can achieve the purpose of turning off the laser 2027.

In some embodiments, laser projection host 202 further comprises: the laser driver circuit 2026 and the MCU20251 may be connected to the laser driver circuit 2026, and the laser driver circuit 2026 may be connected to the laser 2027. The MCU20251 may control the laser driver circuit 2026 to turn off or turn on the laser 2027. Illustratively, the MCU20251 may pull up the level of the laser drive circuit 2026, causing the laser drive circuit 2026 to turn on the laser 2027, or the MCU20251 may pull down the level of the laser drive circuit 2026, causing the laser drive circuit 2026 to turn off the laser 2027.

The laser projection host 202 provided in the embodiment of the present application may include: a microprocessing unit MCU20251, a foreign substance detection circuit 2033 and a laser 2027, wherein the MCU20251 is connected to the foreign substance detection circuit 2033 and the laser 2027 respectively. A foreign substance detection circuit 2033 for sending an interrupt signal to the MCU20251 in response to detecting the presence of a foreign substance at the projection light-emitting port 2022 of the laser projection host 202; the MCU20251 is used for turning off the laser 2027 based on the interrupt signal. In the embodiment of the present application, the foreign substance detection circuit 2033 is directly connected to the MCU20251, so when the MCU20251 determines that the foreign substance detection circuit 2033 detects that a foreign substance is present at the projection light-emitting port 2022 of the laser projection host 202, the laser 2027 can be turned off, and the response speed is fast without waiting for turning off the laser 2027 in response to a turn-off command from the motherboard 2024.

The following description is made on the operation of the foreign substance detection circuit 2033 to detect foreign substances and the principle of the MCU20251 receiving an interrupt signal.

In some embodiments, the MCU20251 may include: the foreign substance detection circuit 2033 includes a foreign substance detection sensor 20212, and the foreign substance detection sensor 20212 includes a second interrupt pin, to which the first interrupt pin is connected. The foreign object detection sensor 20212 is specifically configured to control the second interrupt pin to output a first falling edge when the foreign object is detected, where the first falling edge is used to represent the interrupt signal. The manner in which the foreign object detection sensor 20212 outputs the first falling edge may refer to the description related to the above-described embodiments.

In some embodiments, the foreign object detection circuit 2033 may further comprise: an infrared photodiode and a photo detection diode, and a foreign object detection sensor 20212 is connected to the photo detection diode. And the infrared photodiode is used for emitting the pulse infrared rays. And a photo detection diode for detecting infrared light reflected by the foreign matter. The foreign object detection sensor 20212 may determine that a foreign object exists on the laser projector 202 when the photodetection diode detects the reflected infrared light, and the foreign object detection sensor 20212 may control the second interrupt pin to output the first falling edge. In this embodiment, the MCU20251 may detect the level of the second interrupt pin through the first interrupt pin. When the MCU20251 detects that the second interrupt pin outputs the first falling edge, it may be determined that a foreign object exists on the laser projection host 202, and the laser 2027 may be turned off.

A timing diagram of a laser display device according to some embodiments is illustrated in fig. 15. Referring to fig. 15, in this embodiment, at time T1, the foreign substance detection circuit 2033 detects a foreign substance, and may transmit an interrupt signal to the MCU20251 (the foreign substance detection sensor 20212 controls the second interrupt pin to output a first falling edge). The foreign object detection circuit 2033 sends an interrupt signal to the MCU20251, which can be referred to the above-mentioned related description. At time T2, the MCU20251 receives the interrupt signal and can turn off the laser 2027. In some embodiments, time T2 may be replaced with time T3, etc., but in any event, time T2 and time T3 are both less than time T4.

Accordingly, in this embodiment of the application, the MCU20251 may detect the first falling edge output by the second interrupt pin through the first interrupt pin to determine that a foreign object exists on the laser projection host 202.

In some embodiments, the MCU20251 further comprises a first data SDA pin, and the foreign object detection sensor 20212 further comprises a second SDA pin, the first SDA pin and the second SDA pin being connected via the integrated circuit bus IIC. The MCU20251, is also configured to set a first threshold value for the foreign object detection sensor 20212 by the IIC. In some embodiments, the MCU20251 may initialize the foreign object detection sensor 20212 when the MCU20251 is powered on, and set a first threshold for the foreign object detection sensor 20212 by the IIC. The MCU20251 initializes the foreign matter detection sensor 20212 and sets the first threshold value can refer to the above-described description of "the main board 2024 initializes the foreign matter detection sensor 20212 and sets the first threshold value".

In this embodiment, in order to avoid the first falling edge being output by the foreign object detection sensor 20212 due to false triggering, the foreign object detection sensor 20212 may be configured to control the second interrupt pin to output the first falling edge when the number of times of detecting the reflected infrared light detected by the photo detection diode is greater than the first threshold. Accordingly, the MCU20251 may detect that the second interrupt pin outputs the first falling edge, and then control the DMD2028 to display the predetermined image.

In some embodiments, the foreign object detection circuit 2033 may also detect the removal of foreign objects from the projection light outlet 2022 of the laser projection host 202, and then sends an interrupt signal to the MCU 20251. After the MCU20251 turns off the laser 2027, if the MCU20251 receives the interrupt signal from the foreign object detection circuit 2033, it can determine that the foreign object on the laser projection host 202 is removed, and the MCU20251 can turn on the laser 2027.

In some embodiments, to improve the detection accuracy of the foreign object detection circuit 2033, the MCU20251 is further configured to set a second threshold value for the foreign object detection sensor 20212 by the IIC, the second threshold value being smaller than the first threshold value. It is understood that when the MCU20251 initializes the foreign object detection sensor 20212 and sets the first threshold, the MCU20251 may set the second threshold for the foreign object detection sensor 20212.

After the foreign object detection sensor 20212 sends the interrupt signal to the MCU20251, if the number of times of detecting the reflected infrared light detected by the photodetection diode is smaller than the second threshold value, it is determined that the reflected infrared light is a false detection, and the foreign object covered on the laser projection host 202 is removed. The foreign object detection sensor 20212 may control the second interrupt pin to output the second falling edge. Accordingly, when the MCU20251 turns off the laser 2027, if the second interrupt pin outputs the second falling edge is detected through the first interrupt pin, the MCU20251 may determine that the foreign object on the laser projection host 202 has been removed, and the MCU20251 may turn on the laser 2027. It should be appreciated that the second falling edge may be one falling edge after the first falling edge of the second interrupt pin output.

In this embodiment, the MCU20251 may set a first threshold and a second threshold for the foreign object detection sensor 20212, and if the number of times that the foreign object sensor detects the reflected infrared light detected by the photo detection diode is greater than the first threshold, the second interrupt pin may be controlled to output the first falling edge, so as to avoid false detection. The MCU20251 may output the first falling edge based on the second interrupt pin, determine that there is a foreign object on the laser projection host 202, and turn off the laser 2027 to reduce the accumulation of laser energy and avoid burning of the foreign object. In addition, when the MCU20251 detects that the second interrupt pin outputs the second falling edge, it may be determined that the foreign object on the laser projection host 202 has been removed and the laser 2027 may be turned on, so that the laser projection host 202 operates normally.

A schematic diagram of the structure of a laser projection host according to some embodiments is illustrated in fig. 16. Referring to fig. 16, in some embodiments, laser projection host 202 may further include: the power panel 2023, the power panel 2023 is connected with the mainboard 2024. And the power panel 2023 is used for supplying power to the mainboard 2024.

In some embodiments, laser projection host 202 further comprises: the laser drive circuit 2026, the MCU20251 and the laser drive circuit 2026 are connected, the laser drive circuit 2026 and the laser 2027 are connected, and the power supply board 2023 and the laser drive circuit 2026 are connected. The MCU20251 is specifically configured to control the laser driving circuit 2026 to turn on or off the laser 2027.

In some embodiments, laser projection host 202 may further include: DLP20252, DMD 2028. The connection between the motherboard 2024 and the DLP20252, the connection between the MCU20251 and the DLP20252, and the connection between the DLP20252 and the DMD2028 may refer to the above description in fig. 6. In some embodiments, the laser projection host 202 may further include a speaker 2032 and a power amplifier 20241, which may specifically refer to the related description in fig. 6.

Based on the structure of the laser projection host 202 shown in fig. 16, a flowchart of an MCU according to some embodiments is exemplarily shown in fig. 17. As shown in fig. 17, when the laser display device is powered on, the MCU20251 can execute a main program. For example, the main program of the MCU20251 may be the MCU20251 to control the DLP20252 to power on, and to control the laser driving circuit 2026 to turn on or off the laser 2027, etc.

When the MCU20251 receives an interrupt signal from the foreign object detection sensor 20212, the MCU20251 may perform an interrupt response, executing an interrupt routine. The MCU20251 may execute an interrupt program by: the MCU20251 turns off the laser 2027. Specifically, the MCU20251 may pull down the level of the laser driving circuit 2026 to turn off the laser 2027. In some embodiments, the interrupt return may be performed after the MCU20251 executes the program, and the interrupt return performed by the MCU20251 may be: the MCU20251 may feed back response information to the foreign object detection sensor 20212, the response information being indicative that the MCU20251 has turned off the laser 2027.

The embodiment of the present application further provides a laser display device, and the laser display device may include: a projection screen 201 and a laser projection host 202 as in the above embodiments. The laser display device in the embodiment of the present application can implement the technical solution of avoiding the foreign object from burning in the above embodiment, and has the same technical effects as the above embodiment, and reference may be made to the related description in the above embodiment.

Finally, it should be noted that: the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present application.

The foregoing description, for purposes of explanation, has been presented in conjunction with specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the embodiments to the precise forms disclosed above. Many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles and the practical application, to thereby enable others skilled in the art to best utilize the embodiments and various embodiments with various modifications as are suited to the particular use contemplated.

Claims (10)

1. A laser projection host computer applied to laser display equipment is characterized by comprising: the device comprises a microprocessing unit (MCU), a foreign matter detection circuit and a laser, wherein the MCU is respectively connected with the foreign matter detection circuit and the laser;

the foreign matter detection circuit is used for responding to the fact that foreign matters exist at a projection light outlet of the laser projection host machine and sending an interrupt signal to the MCU;

and the MCU is used for closing the laser based on the interrupt signal.

2. The laser projection host of claim 1, wherein the MCU comprises a first interrupt pin, the foreign object detection circuit comprises a foreign object detection sensor, the foreign object detection sensor comprises a second interrupt pin, and the first interrupt pin is connected to the second interrupt pin;

the foreign object detection sensor is specifically configured to control the second interrupt pin to output a first falling edge in response to detecting the foreign object, where the first falling edge is used to characterize the interrupt signal;

the MCU is specifically configured to turn off the laser in response to detecting the first falling edge.

3. The laser projection host of claim 2, wherein the MCU further comprises a first data SDA pin, wherein the foreign object detection sensor further comprises a second SDA pin, and wherein the first SDA pin and the second SDA pin are connected via an integrated circuit bus IIC.

4. The laser projection host of claim 3, wherein the foreign object detection circuit further comprises: the foreign matter detection sensor is connected with the photoelectric detection diode;

the MCU is further used for setting a first threshold value for the foreign matter detection sensor through the IIC;

the infrared photodiode is used for emitting pulse infrared rays;

the photoelectric detection diode is used for detecting infrared light reflected by the foreign matters;

the foreign matter detection sensor is configured to control the second interrupt pin to output the first falling edge when the number of times of detecting the reflected infrared light detected by the photodetection diode is greater than the first threshold value.

5. The laser projection host of claim 4,

the MCU is further used for setting a second threshold value for the foreign matter detection sensor through the IIC, and the second threshold value is smaller than the first threshold value;

the foreign matter detection sensor is further configured to control the second interrupt pin to output a second falling edge when the number of times of detection is smaller than the second threshold value;

the MCU is further used for turning on the laser if the second falling edge is detected after the laser is turned off.

6. The laser projection host of any one of claims 1-5, further comprising: the main board is respectively connected with the power panel and the MCU;

the power panel is used for supplying power to the mainboard;

the main board is used for controlling the MCU to be opened or closed.

7. The laser projection host of claim 6, further comprising: the laser driving circuit is connected with the MCU, the laser driving circuit is connected with the laser, and the power panel is connected with the laser driving circuit;

the power panel is used for supplying power to the laser driving circuit;

and the MCU is specifically used for controlling the laser driving circuit to stop supplying power to the laser so as to close the laser.

8. The laser projection host of claim 7, further comprising: the digital light processor DLP and the digital micromirror device DMD are respectively connected with the mainboard and the DMD;

the main board is further used for sending content to be displayed to the DLP;

and the DLP is used for driving the DMD to display the content to be displayed.

9. The laser projection host of claim 8, further comprising: the MCU is respectively connected with the fan and the temperature sensor;

the temperature sensor is used for detecting the temperature of the DMD;

and the MCU is used for controlling the fan to rotate at a preset rotating speed.

10. A laser display device, comprising: a projection screen and a laser projection host as claimed in any one of claims 1-9 above.

Images