CN115767048A - Laser projection device - Google Patents

Abstract

The application discloses laser projection equipment includes: a light source comprising a red laser; display panel, power panel, TV panel; and the signal shaping circuit is connected with the display panel, is arranged in a path for transmitting either or both of an initial image enable signal and an initial current control signal output by a display control processing part in the display panel to the red laser and is used for outputting a shaped signal, the frequency of the shaped signal is more than or equal to 100Mhz, the red laser emits light or extinguishes light under the drive of a target drive signal, and the target drive signal is a high-frequency periodic drive signal. When the laser projection equipment performs projection display, the speckle phenomenon can be weakened or suppressed.

Description

Laser projection device

The invention is based on the Chinese invention application 202010495287.5 (2020-6-3), the invention name: a laser projection device and a divisional application of a laser driving control method are provided.

Technical Field

The present disclosure relates to projection display, and particularly to a laser projection apparatus and a laser driving control method.

Background

Currently, a projection device may include a light source, and after laser light emitted from the light source is projected onto a projection screen, an image may be projected onto the projection screen.

However, due to the high coherence of the laser, the laser emitted from the projection device forms light and dark spots, also called speckles, on the projection screen when the laser irradiates the projection screen, thereby seriously affecting the display effect of the image.

Disclosure of Invention

The embodiment of the application provides a laser projection device which can weaken or inhibit the speckle phenomenon in a laser projection display image. The technical scheme is as follows:

a laser projection device, comprising: a display control processing unit, a signal shaping circuit, a laser drive circuit, a laser, and an optical modulator; the display control processing part is used for outputting an image display driving signal to the light modulation device and outputting an initial image enabling signal and an initial current control signal to the laser driving circuit so as to drive the laser to emit light or extinguish; the signal shaping circuit is arranged in a path for transmitting the initial image enabling signal and the initial current control signal or any one of the two signals to the laser and is used for outputting a shaping signal which is superposed on the two signals or any one of the two signals to form a target driving signal; and the laser is used for emitting light or extinguishing light under the drive of a target drive signal, and the target drive signal is a high-frequency periodic drive signal.

In the above technical solution, a signal shaping circuit is added in a path of the projection display control processing part outputting a driving signal to the laser, and the driving signal to be received by the laser is shaped, so that a variation period of a driving current finally acting on the laser is shortened, a frequency is increased, and in one period, a high value level of the driving signal can light the laser, a low value level is not greater than a threshold current of the laser, so that the driving signal capable of frequently controlling the laser to be on and off is formed, a normal steady-state light emitting process of the laser is affected, and coherence of a laser beam is reduced, and a speckle phenomenon can be eliminated or suppressed when projection display is performed.

And, also provided is a laser drive control method, applied in a laser projection apparatus, the method comprising: the display control processing part outputs an initial driving signal; shaping the initial driving signal to obtain a target driving signal; the target drive signal is transmitted to the corresponding laser.

In the drive control method of the laser, similarly, the drive signal to be received by the laser is shaped, so that the change period of the drive current finally acting on the laser is shortened, the frequency is increased, in one period, the high value level of the drive signal can enable the laser to be lightened, the low value level is not more than the threshold current of the laser, the drive signal capable of frequently controlling the on and off of the laser is formed, the coherence of the laser beam is reduced, and the speckle phenomenon can be eliminated or inhibited when projection display is carried out.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1-1 is a schematic structural diagram of a laser projection apparatus provided in an embodiment of the present application;

1-2 are block diagrams of circuitry of a laser projection device according to an embodiment of the present disclosure;

FIG. 2-1 is a block diagram of a three-color laser projection apparatus according to an embodiment of the present disclosure;

2-2 is a schematic diagram of a partial circuit structure of another laser projection apparatus provided in an embodiment of the present application;

2-3 are schematic diagrams of partial circuit structures of another laser projection device provided by the embodiments of the present application;

FIG. 3-1 is a schematic diagram of a shaped signal provided by an embodiment of the present application;

FIG. 3-2 is a schematic diagram of another shaped signal provided by embodiments of the present application;

3-3 are schematic diagrams of still another shaped signal provided by embodiments of the present application;

FIG. 4-1 is a schematic timing diagram of a signal mapping provided in an embodiment of the present application;

4-2 is a timing diagram of primary light in a laser projection apparatus provided by an embodiment of the present application;

fig. 5 is a schematic diagram of a partial circuit structure of a laser projection apparatus according to an embodiment of the present disclosure;

FIG. 6 is a schematic diagram of a circuit structure of a portion of another laser projection apparatus provided in an embodiment of the present application;

FIG. 7 is a schematic diagram of a circuit configuration of a portion of another laser projection apparatus according to an embodiment of the present disclosure;

FIG. 8 is a schematic diagram of another method for shaping an initial image enable signal to obtain a target enable signal according to an embodiment of the present disclosure;

FIG. 9 is a schematic diagram of another exemplary embodiment of the present disclosure for shaping an initial current control signal to obtain a target current control signal;

FIG. 10 is a schematic diagram of a circuit structure of a portion of another laser projection apparatus provided in an embodiment of the present application;

FIG. 11 is a schematic diagram of another method for shaping an initial image enable signal to obtain a target enable signal according to an embodiment of the present disclosure;

FIG. 12 is a schematic diagram of a circuit structure of a portion of another laser projection apparatus provided in an embodiment of the present application;

fig. 13 is a waveform diagram of an enable signal of a laser and a driving current of the laser according to an embodiment of the present disclosure;

fig. 14 is a schematic structural view of a related art laser light emitting chip;

fig. 15 is a flowchart of a laser driving control method according to an embodiment of the present application.

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

Fig. 1-1 is a schematic view of a laser projection apparatus provided in an embodiment of the present application. As shown in fig. 1-1, after the upper housing is disassembled, the internal structure of the laser projection apparatus is divided according to the optical function, and may include a light source 100, an optical engine 200, and a lens 300, where the light source 100 is used to provide a light source illumination beam to be transmitted to the rear end light modulation device and the projection lens. The light source 100 may include at least one color laser, such as a blue laser, a dual color laser, such as a blue laser and a red laser, or a three color laser light source, including three red, green, and blue lasers, for providing three color laser illumination beams.

The laser beam provided by the light source 100 is incident to the illumination light path portion in the optical engine 200 after being combined and shaped, and in the DLP projection architecture, the DMD chip is a core light modulation device. The DMD chip receives a driving control signal corresponding to an image signal, inverts a positive angle or a negative angle of the driving signal corresponding to thousands of tiny mirrors on the surface thereof, and reflects a light beam irradiated on the surface thereof into the lens 300.

The lens 300 may be an ultra-short-focus projection lens, and the ultra-short-focus projection lens 300 is configured to project the image beam onto a projection screen, so as to implement projection image display. The laser projection apparatus of the above example may be an ultra-short-focus laser projection apparatus.

Based on the structure of the laser projection device illustrated in fig. 1-1, fig. 1-2 show a schematic circuit architecture of the laser projection device according to an embodiment.

As shown in fig. 1-2, a laser projection apparatus includes: display panel 001, power panel 002, TV panel 003. The power panel 02 is connected with the display panel 001 and the TV panel 003 respectively, and can be used for supplying power to each device or part of modules on the display panel 001 and the TV panel 003, and also can supply power to other functional modules in the laser projection device, such as a human eye protection module, a fan, a WIFI module, and the like, so as to ensure that each part of the laser projection device supplies power normally. In some implementations, a laser driving circuit may also be disposed on the power board 002. Alternatively, the laser driving circuit may be provided independently of the power supply board 002.

The TV board 003 is mainly used for external audio-video signals and decoding.

The TV board 003 is provided with a System on Chip (SoC) capable of decoding data of different data formats into a normalized format and transmitting the data of the normalized format to the display panel 001 through, for example, a connector (connector).

Among them, the video image signal output from the TV board 003 is transmitted to the display panel 001.

The display panel 001 may be provided with a Field Programmable Gate Array (FPGA), and an algorithm processing module FPGA, which is used to process an input video image signal, such as performing MEMC frequency doubling processing or image correction to implement an image enhancement function. The projection display control processing part 010 is connected with the algorithm processing module FPGA, and is configured to receive the processed video image processing signal data as image data to be displayed. The FPGA is usually provided as an enhanced function module, and in some low-cost embodiments, the projection display control processing unit 010 may receive the video image display signal output from the TV board 003 without providing this module.

The projection display control Processing unit 010 mainly includes a Digital Light Processing (DLP) chip, and may further include a driving chip.

In the DLP control architecture, the light source portion needs to match the working timings of the DLP chip and the DMD chip. Specifically, the DLP chip outputs an image enable signal, which may also be referred to as a primary light enable signal, generally denoted as X _ EN, X being an abbreviation for a different primary light, and also outputs a brightness adjustment signal, abbreviated as PWM signal, at the same time. Along with the modulation process of the DMD chip on different primary color image components in a time sequence manner, the light source part needs to synchronously output primary color light beams with corresponding colors. That is, the DLP chip outputs a primary light enable signal to notify the laser light source of enabling the lighting of the laser of a certain color, and outputs a PWM signal to notify the certain laser of the laser light source of at what brightness to light.

Corresponding to fig. 1-2, the projection display control processing unit 010 is configured to generate, according to an image signal to be displayed, a modulation driving signal for driving the light modulation device 011 on one hand, and on the other hand, a light source beam and the light modulation device need to be synchronously matched due to displaying of a projected image, and the projection display control processing unit 010 further generates a driving signal for driving the light source to emit light, where the driving signal may be referred to as an initial driving signal and includes two specific driving signals, namely an image enable signal EN and a current PWM signal, where the image enable signal EN is a timing control signal for coordinating timings of light outputs of different colors, and the current PWM signal is a square wave signal for providing a current signal for lighting the laser.

And, in the schematic circuit architecture diagram of the laser projection apparatus shown in fig. 1-2, a laser driving circuit 030 is further included, which is configured to receive the image enable signal EN and the current PWM signal output by the projection display control processing unit 010, and to specifically control the lighting of the laser 040.

In the drawing, the lasers 040 may be lasers of one color or lasers of a plurality of colors, and usually, corresponding laser drive circuits 030 are provided for the respective lasers of the respective colors.

And, in the schematic diagram of the hardware circuit framework of the laser projection device in this example, the signal shaping circuit 020 is further included, which can be used to generate a periodic sub-signal, shape the image enable signal EN or the current PWM signal, and affect the waveform and period of the signal finally output to the laser 040.

In the figure, the signal shaping circuit 020 is connected to the display panel 001 only for showing that the signal shaping circuit 020 has an influence on an output signal of the display panel 001. In practical applications, the signal shaping circuit 020 may be disposed on the display panel 001, and may be specifically connected to the projection display control processing unit 010, and may act on one or both of the image enable signal EN and the current PWM signal output from the projection display control processing unit 010. The signal shaping circuit 020 may be further provided in the projection display control processing unit 010, and in this case, the signal shaping circuit 020 may be a sub-circuit module of the projection display control processing unit 010.

Alternatively, the signal shaping circuit 020 may be provided on the laser driver circuit 030, that is, the signal shaping circuit 020 may be a sub-circuit block of the laser driver circuit 030, or, when the laser driver circuit is provided on the power board 002, the signal shaping circuit 020 may be provided on the power board 002. Thus, when the image enable signal EN and the current PWM signal are output to the laser drive circuit 030, the signal shaping circuit 020 shapes either or both of the signals, at least the original signal waveform period is changed, and the drive signal to be finally transmitted to the laser 040 is affected.

Alternatively, the signal shaping circuit 020 may be provided as an independent module between the laser driver circuit 030 and the display panel 001. The signal shaping circuit 020 can receive both or either of the image enable signal EN and the current PWM signal, reshape the waveform period, output the signal to the laser drive circuit 030, and finally output the signal to the laser 040 through some conversion amplification processing of the laser drive circuit 030, thereby controlling the laser device to be lit.

The signal shaping circuit 020 may include a high frequency signal generator.

In one example, the laser projection device may be a three-color laser projection device including three colors of red, green, and blue lasers. Fig. 2-1 shows a schematic circuit diagram of a three-color laser projection apparatus. As shown in fig. 2-1, corresponding to the projection display control processing unit 010 in fig. 1-2, in fig. 2-1, it is illustrated that the DLP master control processing unit 010a and the DLP slave control processing unit 010b may be, for example, two DLP control chips, which may be determined according to the requirement of specific circuit function division and are not limited specifically. The DLP master control processing part 010a and the DLP slave control processing part 010b receive data output of the algorithm processing module FPGA and are connected with the DMD optical modulation device 011.

And, in the example of fig. 2-1, the DLP main control processing portion 010a outputs the image enable signal EN and the current PWM signal for driving the laser, and, in the present example, the signal shaping circuit 020 is provided in a signal path between the laser driving circuit 030 and the DLP main control processing portion 010a, and specifically, for shaping the image enable signal EN and outputting the shaped image enable signal EN to the laser driving circuit 030.

And, in the example of fig. 2-1, lasers 040 include blue laser 401, red laser 402, and green laser 403. The signal shaping circuit 020 can be used for shaping the image enable signal EN of only one color laser, and can also be used for the image enable signal EN of two or three color lasers.

And, the power board 002 may provide a driving current for the red laser of 2.9 amperes (a), a driving current for the green laser of 2A, and a driving current for the blue laser of 3A.

As shown in the schematic circuit diagram of the laser projection apparatus of fig. 2-2, the laser 040 may include: three sets of different colored lasers, a blue laser 401 for emitting blue laser light, a red laser 402 for emitting red laser light, and a green laser 403 for emitting green laser light, respectively. Each of the above lasers may be a Multi-chip Laser (MCL).

The three-color laser may be a light emitting unit packaged independently, such as three sets of MCL-type lasers, or may be a multi-color chip packaged in one light emitting unit, such as one MCL-type laser having multiple rows of light emitting chips with different colors, where the different light emitting units may all output three-color laser light.

For example, in fig. 2-2, the display control processing part 010 may output a blue PWM signal B _ PWM corresponding to the blue laser 401 based on a blue primary color component of an image to be displayed, a red PWM signal R _ PWM corresponding to the red laser 402 based on a red primary color component of the image to be displayed, and a green PWM signal G _ PWM corresponding to the green laser 403 based on a green primary color component of the image to be displayed.

The display control processing portion 010 may output the initial image enable signal B _ EN0 corresponding to the blue laser 401 based on a lighting period of the blue laser 401 in the drive cycle, output the initial image enable signal R _ EN0 corresponding to the red laser 402 based on a lighting period of the red laser 402 in the drive cycle, and output the initial image enable signal G _ EN0 corresponding to the green laser 403 based on a lighting period of the green laser 403 in the drive cycle.

The signal shaping circuit 020 is provided between the laser drive circuit 030 corresponding to the red laser and the display control processing unit 010, and shapes the image enable signal EN or the red base color light enable signal R _ EN0 corresponding to the red laser.

In the schematic diagram of fig. 2-2, the display control processing portion 010 may transmit the initial image enable signal B _ EN0 corresponding to the blue laser 401 to the corresponding laser driving circuit 030, transmit the initial image enable signal R _ EN0 corresponding to the red laser 402 to the corresponding signal shaping circuit 020, and output the initial image enable signal G _ EN0 corresponding to the green laser 403 to the corresponding laser driving circuit 030.

And, the display control processing portion 010 may also transmit the blue PWM signal B _ PWM to the laser driving circuit 030 corresponding to the blue laser 401, transmit the red PWM signal R _ PWM to the laser driving circuit 030 corresponding to the red laser 402, and transmit the green PWM signal G _ PWM to the laser driving circuit 030 corresponding to the green laser 403.

In the schematic diagram of fig. 2-2, the display control processing section 010 transmits an initial image enable signal to the corresponding signal shaping circuit 020 and transmits an initial current control signal to the corresponding laser driving circuit 030. Alternatively, as a modification of the schematic diagrams of fig. 2-2, the display control processing section 010 may also transmit two or three kinds of initial image enable signals to the signal shaping circuit 020, and transmit three sets of initial current control signals to the corresponding laser driving circuits 030.

And, exemplarily, the signal shaping circuit 020 may also be disposed in the signal path of the current PWM signal. As shown in fig. 2 to 3, the signal shaping circuit 020 is provided in the PWM signal transmission paths corresponding to the blue laser 401, the red laser 402, and the green laser 403, respectively.

As shown in fig. 2 to 3, the display control processing portion 010 is respectively connected to each signal shaping circuit 020 and each laser driving circuit 030, and is configured to output at least one initial image enable signal corresponding to one of the three primary colors of each frame of image in the multi-frame display image, specifically, as shown in the figure, a blue primary light enable signal B _ EN, a red primary light enable signal R _ EN, and a green primary light enable signal G _ EN. And also for outputting three sets of initial current control signals corresponding to the three primary colors of each frame image one to one, for example, the initial current control signals may be Pulse Width Modulation (PWM) signals, and specifically, may be a blue PWM signal B _ PWM0, a red PWM signal R _ PWM0, and a green PWM signal G _ PWM0 as shown in the figure. And the display control processing portion 010 is further configured to transmit the three initial current control signals to the corresponding signal shaping circuits 020, and transmit the three sets of initial image enable signals to the corresponding laser driving circuits 030, respectively.

The display control processing portion 010 may also output an initial image enable signal B _ EN corresponding to the blue laser 401 based on a lighting period of the blue laser 401 in the drive period, output an initial image enable signal R _ EN corresponding to the red laser 402 based on a lighting period of the red laser 402 in the drive period, and output an initial image enable signal G _ EN corresponding to the green laser 403 based on a lighting period of the green laser 403 in the drive period.

The display control processing portion 010 may transmit the initial image enable signal B _ EN to the laser driving circuit 030 corresponding to the blue laser 401. The initial image enable signal R _ EN is transmitted to the laser driving circuit 030 corresponding to the red laser 402, and the initial image enable signal G _ EN is output to the laser driving circuit 030 corresponding to the green laser 403. The display control processing unit 010 may transmit the blue PWM signal B _ PWM0 corresponding to the blue laser 401 to the corresponding signal shaping circuit 020, transmit the red PWM signal R _ PWM0 corresponding to the red laser 402 to the corresponding signal shaping circuit 020, and transmit the green PWM signal G _ PWM0 corresponding to the green laser 403 to the corresponding signal shaping circuit 020.

Each signal shaping circuit 020 is configured to shape the received initial signal to obtain a target signal, and transmit the target signal to the corresponding laser driving circuit 030.

The frequency of the target signal is greater than that of the initial image enable signal, and the total duration of the target signal at the effective level is less than the duration of the initial signal at the effective level in one period of the initial image enable signal.

If the initial signal received by the signal shaping circuit 020 is the initial image enable signal, it can be achieved that the laser driving circuit 030 is continuously controlled to be turned on or off in one period of the initial image enable signal, so that the driving current provided by the laser driving circuit 030 to the laser is switched between the active level and the inactive level at a high frequency. Wherein the active level may be a high level.

If the initial signal received by the signal shaping circuit 020 is the initial current control signal, it is possible to change the variation period of the driving current supplied to the laser by the laser driving circuit 030 within one period of the initial image enable signal.

Each laser driver circuit 030 is arranged to deliver a drive current to the corresponding laser in response to a target signal and another initial signal. Each laser is used for emitting light under the drive of the drive current.

Specifically, the signal shaping circuit 020 superimposes a high-frequency, periodic waveform on the original signal to form a target signal.

Fig. 3-1, 3-2, and 3-3 show examples of different shaped signals S _ f, respectively.

As shown in fig. 3-1, the signal S _ f may be a square wave pulse waveform. In the schematic diagram of fig. 3-2, the signal S _ f may be a triangular pulse waveform. And, in the schematic diagrams of fig. 3-3, the signal S _ f may be a sawtooth pulse waveform.

Fig. 4-1 shows a lighting operation timing chart of the red laser, in conjunction with the hardware circuit configuration diagram of fig. 2-2.

First, for better understanding of the multi-primary period timing variation, reference may be made to the timing diagram of the tricolor light in the laser projection apparatus shown in fig. 4-2. As shown in fig. 4-2, the enable signals R _ EN0, G _ EN0, and B _ EN0 corresponding to the three primary colors are in one driving period T0, and only one of the three enable signals is in the high-level valid period at one time, and the other two enable signals are in the low-level invalid period.

And, generally, in order to increase the picture brightness, it is also possible to set the enable signals for the three colors to be simultaneously active, i.e., the W period shown in the drawing, in one driving period T. The W period may not be set, and timing control may be performed only in such a manner that three colors are alternately effective.

R, G and B sequentially indicate the duration of the red enable signal as the effective potential, the duration of the green enable signal as the effective potential, and the duration of the blue enable signal as the effective potential at the time sequence output stage; w refers to the duration of the output phase of the superposition.

Fig. 4-2 only shows the relationship between the three color enable signals in one period, and in a specific implementation, the period T0 may be 1/240s, that is, the period of the multi-primary enable signal EN may be 240HZ.

See fig. 2-2 and 4-1. As shown in fig. 4-1, in one period R _ EN0-T of the red initial image enable signal R-EN0, R _ EN0 has a high level valid period and a low level invalid period, which will be exemplified by only one period.

As shown in fig. 2-2 and the foregoing description, the display control processing section simultaneously outputs the image enable signal and the current PWM signal. Typically, the current PWM signal is a square wave with a frequency of 18.3KHZ, wherein within one color of enable signal period, multiple periods of the PWM signal may be included. In fig. 4-1, for example only, about 5 cycles of the R _ PWM0 signal are included in one R _ EN0 cycle.

In fig. 2-2, the signal shaping circuit 020 can output the square wave pulse signal S _ f shown in fig. 3-1 as a shaped signal. The frequency of the shaped signal is equal to or greater than 100Mhz, for example, 200Mhz. The shaped signal is plotted in an exemplary fashion for several cycles.

The signal shaping circuit 020 is disposed in a transmission path of the red enable signal R _ EN0, and shapes the red enable signal R _ EN0, so that during a high-level valid period of R _ EN0, after being shaped by the signal shaping circuit 020, a high-frequency pulse signal is superimposed on the red enable signal R _ EN0, so that the red enable signal R _ EN0 forms a pulse signal similar to the shaped signal S _ f during the high-level valid period in one cycle, so that the valid period of R _ EN0 is divided into a plurality of valid periods, and the total valid period is shortened. For the red current R _ PWM0 signal, it is always periodically output, and limited by the red enable signal R _ EN0, the current signal can be output to the laser only in the active level period of R _ EN0.

And the red enabling signal R _ EN0 after signal shaping is changed from an initial continuous high-level effective period to a plurality of short high-level effective periods and ineffective periods and is periodically repeated. Thus, for the laser drive circuit and the laser, the drive current that ultimately reaches the red laser 402 is shown as the RLD _ D signal waveform in fig. 4-1, and the laser drive current is also divided into a plurality of shorter waveforms that alternate high and low.

And as shown in fig. 3-1, the shaped signal has a certain amplitude, the highest value is Imax and the lowest value is Imin. In the graph, io corresponds to the threshold current amplitude at which the laser is lit. Since Imin is smaller than Io, the lowest value of the driving current waveform of the laser is also smaller than the lighting threshold current Io of the laser, so that the laser is switched before frequent lighting and switching off. And the frequency of the switching is close to the frequency of the shaped signal.

In the example of the present application, the laser used in the laser projection apparatus is a semiconductor laser having a PN junction. Fig. 14 is a schematic diagram of a semiconductor-type laser light emitting chip.

Among them, semiconductor laser chips operate by injecting carriers, and if laser light is to be emitted, three basic conditions must be met:

(1) When irradiated by laser, generating enough population inversion distribution, wherein the population number of the high-energy state is enough larger than that of the low-energy state;

(2) A proper resonant cavity can play a feedback role to enable stimulated radiation photons to proliferate so as to generate laser oscillation;

(3) The gain is greater than the loss and a threshold condition is satisfied such that the photon gain is equal to or greater than the photon loss.

As shown in fig. 14, the semiconductor laser light emitting chip includes a P region, an active region, and an N region. When a certain forward bias is applied to the laser, electrons are injected from the N region to the P region, holes are injected from the P region to the N region, sufficient photon energy is radiated, when the excited condition is met, stable excitation is formed, photon radiation strictly propagates in a PN junction plane, light radiation with the same wavelength, phase and intensity is output from an active region area of the front cavity surface, namely a commonly applied monochromatic laser beam, the process is a laser radiation process of semiconductor laser, and a laser light emitting chip can stably emit light only when a process reaches a stable state.

For the PN junction, as long as a forward bias is applied to the PN junction, the N region injects electrons into the P region, the P region injects holes into the N region, and the electrons and holes spontaneously coincide to form electron-hole pairs in the active region (also called active layer, active region), and at the same time, excess energy is released in the form of photons, where the phases and directions of the emitted photons are different, and the radiation is called spontaneous radiation. This spontaneous emission is the emission pattern of the light emitting diode.

In the case of a semiconductor laser, the light emitted from the laser is laser light only when the drive current reaches a current of a threshold current (lighting the laser), but the laser may emit light at that time if the laser is energized but does not reach its own threshold current, only fluorescence (referred to as spontaneous emission) is emitted at that time.

Therefore, when the laser is electrified to be above the threshold current, the laser light-emitting chip can perform stable stimulated light radiation to emit laser beams, and if the laser is not reached to the threshold current, the laser radiation is not steady stimulated oscillation and is in a random photon radiation state to emit fluorescence, which is a basic working mode of a PN junction.

According to the above working principle, by providing a driving current for turning the laser on and off frequently and periodically, and the current period reaches at least 100Mhz or more, for example, it is easy for the laser light emitting chip to be in an unstable state or not yet in a stable state, and in this state, the laser is operated in a multi-longitudinal mode oscillation mode, so that a plurality of wavelengths are selected at the time of wavelength selection, rather than a single wavelength emitted in a stable state, which widens the spectrum of the light emitted by the laser, and the coherence of the laser beam itself is reduced compared with that of the single wavelength.

In one embodiment, the signal shaping circuit may output a high frequency signal waveform such as that shown in fig. 3-1, 3-2, 3-3, the low value of which is lower than the value corresponding to the laser lighting threshold current, specifically, may be smaller than the threshold and larger than 0, or may be 0. And, the shaping signal frequency is greater than or equal to 100Mhz, for example, 200Mhz, and by providing a driving signal for frequently controlling the on and off of the laser, the laser light emitting chip shown in fig. 14 is in a state of being in a process of switching to a steady state with a high probability under frequent on and off of current, so that the wavelength of radiation selected by the front cavity surface active region may include other wavelengths near the main wavelength in addition to the main wavelength, and these other wavelengths are not as wide as the range of the fluorescence spectrum, but also migrate from the main wavelength, and the proportion of the energy distribution is also high, so that the spectrum of the laser beam is broadened, and the coherence from the source itself is reduced.

In fig. 2-2, when the display control processing portion 010 transmits the initial image enable signal to the corresponding signal shaping circuit 020 and transmits the initial current control signal to the corresponding laser driving circuit 030, the initial signal output by the display control processing portion 010 is the initial image enable signal, and the target signal obtained by shaping the initial image enable signal by the signal shaping circuit 020 may also be referred to as a target enable signal.

Alternatively, for a scenario where the display control processing section 010 transmits the initial image enable signal to the corresponding signal shaping circuit 020, each laser drive circuit 030 is configured to transmit a drive current that can turn on the laser to the corresponding laser in response to the current control signal and keep the drive current constant when the level of the target enable signal jumps from the inactive level to the active level. Then, when the level of the target enable signal jumps from an active level to an inactive level, the driving current transmitted to the corresponding laser is reduced to a fixed driving current in response to the current control signal, and the fixed driving current cannot light the laser.

By periodically changing the drive current supplied to the lasers, thereby causing the emission luminance of the lasers to periodically vary and the spectral width of the emitted light to widen, each of the lasers generates a plurality of laser lights of different wavelengths driven by the periodically varying drive current, and the coherence between the laser light beams of different wavelengths is reduced compared with that of a single wavelength light beam.

Referring to fig. 2-2, the signal shaping circuit 020 can shape the initial image enable signal R _ EN0 corresponding to the red laser 402 transmitted from the display control processing unit 010 to obtain the target enable signal R _ EN1 after receiving the initial image enable signal R _ EN0. The laser driving circuit 030 for the red laser 402 may respond to the red PWM signal R _ PWM transmitted from the display control processing portion 010 and the target enable signal R _ EN1 transmitted from the signal shaping circuit 020, and the R _ PWM signal may be modulated again by the target enable signal R _ EN1 so that the period of variation of the driving current supplied to the red laser 402 is greater than the period of the R _ PWM signal and close to or equal to the period of variation of the target enable signal R _ EN1. In this way, the red laser 402 is used to emit red laser light of at least two different wavelengths under the driving of the periodically varying driving current.

In fig. 2-2, the red enable signal R _ EN0 is merely used as an example, and it can be understood that the signal shaping circuit 020 may be disposed in the transmission path for the blue enable signal B _ EN0 and the green enable signal G _ EN0, so that the laser driving circuits corresponding to the blue laser and the green laser may supply the PWM signals of the new change period modulated by the target enable signal to the blue laser 401 and the green laser 403 respectively in response to the blue PWM signal B _ PWM and the green PWM signal G _ PWM transmitted by the display control processing unit 010 and the target enable signals B _ EN1 and G _ EN1 transmitted by the signal shaping circuit 020, respectively, and the new change period is much lower than the change period of the original PWM signal, so that the laser is in the change state of frequent on-off during the active period of one period of the original image enable signal.

In another embodiment, as shown in fig. 2 to 3, when the display control processing unit transmits the initial current control signal to the corresponding signal shaping circuit and transmits the initial image enable signal to the corresponding laser driving circuit, the initial signal output by the display control processing unit is the initial current control signal, and the target signal shaped by the signal shaping circuit on the initial current control signal may also be referred to as a target current control signal.

Alternatively, for the scenario where the display control processing unit 010 transmits the initial current control signal to the corresponding signal shaping circuit 020, when the level of the initial image enable signal jumps from the inactive level to the active level, each laser drive circuit 030 transmits the drive current shaped by the signal shaping circuit 020 to the corresponding laser in response to the target current control signal. Thereafter, when the level of the initial image enable signal jumps from the active level to the inactive level, the inactive level of the initial image enable signal may be anded with the driving current signal, so that the driving current signal is inactive and thus no driving current is transmitted to the laser.

Referring to fig. 2 to 3, after receiving the initial current control signal B _ PWM0 transmitted by the display control processing unit 010, the signal shaping circuit 020 may shape the initial current control signal B _ PWM0 to obtain a target current control signal B _ PWM1, and transmit the target current control signal B _ PWM1 to the laser driving circuit 030 corresponding to the blue laser 401. The laser driving circuit 030 for the blue laser 401 can logically and-operate in response to the initial image enable signal B _ EN transmitted from the display control processing portion 010 and the target current control signal B _ PWM1 transmitted from the signal shaping circuit 020, and then supply the corresponding driving current to the blue laser 401. The blue laser 401 is used to emit laser light driven by the driving current.

Similarly, the signal shaping circuit 020 can shape the initial current control signal R _ PWM0 to obtain the target current control signal R _ PWM1 after receiving the initial current control signal R _ PWM0 transmitted by the display control processing unit 010. The laser driving circuit 030 corresponding to the red laser 402 can supply a corresponding driving current to the red laser 402 in response to the initial image enable signal R _ EN transmitted by the display control processing section 010 and the target current control signal R _ PWM1 transmitted by the signal shaping circuit 020. The red laser 402 is used to emit laser light driven by the driving current.

And, the signal shaping circuit 020 can shape the initial current control signal G _ PWM0 to obtain the target current control signal G _ PWM1 after receiving the initial current control signal G _ PWM0 transmitted from the display control processing unit 010. The laser driving circuit 030 corresponding to the green laser 403 can supply a corresponding driving current to the green laser 403 in response to the initial image enable signal G _ EN transmitted by the display control processing portion 010 and the target current control signal G _ PWM1 transmitted by the signal shaping circuit 020. The green laser 403 is used for emitting laser light driven by the driving current.

Various embodiments of the present application will be further described below in conjunction with specific circuit configurations.

Fig. 5 is a schematic diagram of a partial hardware circuit of a laser projection apparatus according to an embodiment of the present disclosure, and as shown in fig. 5, a signal shaping circuit 020 in the laser projection apparatus may include a signal generating sub-circuit 021 and a shaping sub-circuit 022. The signal generating sub-circuit 021 is connected to the shaping sub-circuit 022, and is configured to transmit the high-frequency signal S _ f to the shaping sub-circuit 022.

The shaping sub-circuit 022 is also connected to the display control processing unit 010 and the corresponding laser drive circuit 030, and shapes the received initial signal based on the high-frequency signal S _ f to output a target signal. As shown in fig. 5, the received initial signal is an initial image enable signal EN0, and the target signal is a target enable signal EN1.

The frequency of the high-frequency signal S _ f is greater than that of the received initial signal, and in one period of the received initial signal, the total duration of the high-frequency signal S _ f at the effective level is less than the duration of the initial signal at the effective level.

When the initial signal is at an inactive level, the level of the target signal output from the shaping sub-circuit 022 is at an inactive level. When the initial signal is at the active level, the level of the target signal output from the shaping sub-circuit 022 is determined by the level of the high-frequency signal S _ f. Therefore, the frequency of the target signal output by the shaping sub-circuit 022 is equal to the frequency of the high-frequency signal S _ f, and the duty cycle of the target signal is equal to the duty cycle of the high-frequency signal S _ f.

Optionally, when the level of the initial signal is an active level, if the level of the high-frequency signal S _ f is an active level, the level of the target signal output by the shaping sub-circuit is an active level. If the level of the high frequency signal S _ f is at an inactive level, the level of the target signal output by the shaping sub-circuit is at an inactive level.

In an alternative implementation manner of the embodiment of the present application, fig. 6 is a schematic diagram of a hardware circuit structure of a part of another laser projection apparatus provided in the embodiment of the present application. As shown in fig. 6, a shaping sub-circuit 022 in the laser projection device may include a tri-state buffer U2. The input terminal of the tri-state buffer U2 is connected to the display control processing section 010, and receives an initial signal. The control terminal of the tri-state buffer U2 is connected to the signal generating sub-circuit 021 for receiving the high frequency signal S _ f. The output terminal of the tri-state buffer U2 is connected to the laser drive circuit 030 for outputting a target signal. The tri-state buffer U2 is also connected to a power supply terminal VCC. The initial signal is an initial image enable signal EN0, and the target signal is a target enable signal EN1. As shown in fig. 7, the received initial signal is an initial current control signal PWM0, and the target signal is a target current control signal PWM1.

Alternatively, the tri-state buffer U2 may be turned on when the level of the high frequency signal S _ f received at its control terminal is an inactive level. Or the tri-state buffer U2 may be turned on when the level of the high frequency signal S _ f received at its control terminal is an active level. When the tri-state buffer U2 is turned on, it can output the signal received by its input terminal to its output terminal.

Referring to fig. 6 and 7, the shaping sub-circuit 022 may further include an inverter U1. The inverter U1 is connected in series between the signal generation sub-circuit 021 and the control terminal of the tri-state buffer U2, and is used for inverting the high frequency signal S _ f output by the signal generation sub-circuit 021 to obtain an inverted high frequency signal S _ f1. The tri-state buffer U2 may be turned on when the inverted high frequency signal S _ f1 received at its control terminal is at an active level. Or may be turned on when the inverted high-frequency signal S _ f1 is at an inactive level.

Assume that the tri-state buffer U2 is turned on when the inverted high frequency signal S _ f1 received at its control terminal is at an inactive level. Fig. 8 is a schematic diagram of another shaping of an initial image enable signal to obtain a target enable signal according to an embodiment of the present application. Taking the signal shaping circuit 020 in the laser projection apparatus shown in fig. 6 as an example, a process of obtaining the target enable signal from the initial image enable signal will be described.

Referring to fig. 6 and 8, when the initial image enable signal EN0 is at a high level, the level of the high frequency signal S _ f is at a high level in a period from t1 to t2, and the inverted high frequency signal S _ f1 is at a low level after the high frequency signal S _ f passes through the inverter U1. At this time, the tri-state buffer U2 is turned on after receiving the high frequency signal S _ f1 with the low level at its control end, and the initial image enable signal EN0 received at the input end of the tri-state buffer U2 is output from the output end of the tri-state buffer U2, that is, the tri-state buffer U2 outputs the target enable signal EN1 with the high level.

In the period from t2 to t3, the level of the high-frequency signal S _ f is low, and after the high-frequency signal S _ f passes through the inverter U1, the level of the inverted high-frequency signal S _ f1 is high. At this time, the tri-state buffer U2 is turned off, and the output level of the output terminal of the tri-state buffer U2 is a low level, that is, the tri-state buffer U2 outputs the target enable signal EN1 at a low level. Thereafter, the process at the period t1 to t2 may be repeated during the period t3 to t4 and during the period t5 to t6, and the process at the period t2 to t3 may be repeated during the period t4 to t 5.

It is assumed that the tri-state buffer U2 is turned on when the inverted high frequency signal S _ f1 received at its control terminal is at an inactive level. Fig. 9 is a schematic diagram of another exemplary embodiment of the present disclosure for shaping an initial current control signal to obtain a target current control signal. Taking the signal shaping circuit 020 in the laser projection apparatus shown in fig. 7 as an example, a process of obtaining the target current control signal from the initial current control signal will be described.

Referring to fig. 7 and 9, when the initial current control signal PWM0 is at a high level, the level of the high frequency signal S _ f is at a high level in a period from t1 to t2, and after the high frequency signal S _ f passes through the inverter U1, the level of the inverted high frequency signal S _ f1 is at a low level. At this time, the tri-state buffer U2 is turned on after receiving the high frequency signal S _ f1 with the low level at its control end, and the initial current control signal PWM0 received at the input end of the tri-state buffer U2 is output from the output end of the tri-state buffer U2, that is, the tri-state buffer U2 outputs the target current control signal PWM1 with the high level.

In the period from t2 to t3, the level of the high-frequency signal S _ f is low, and after the high-frequency signal S _ f passes through the inverter U1, the level of the inverted high-frequency signal S _ f1 is high. At this time, the tri-state buffer U2 is turned off, and the output level of the output terminal of the tri-state buffer U2 is a low level, that is, the tri-state buffer U2 outputs the target current control signal PWM1 at a low level. Thereafter, the process during the period t1 to t2 may be repeated during the period t3 to t 4.

In another alternative implementation manner of the embodiment of the present application, fig. 10 is a schematic diagram of a partial hardware circuit structure of another laser projection apparatus provided in the embodiment of the present application.

Referring to fig. 10, a shaping sub-circuit 022 in the laser projection device may include a tri-state buffer U3. The input of the tri-state buffer U3 is connected to the signal generating sub-circuit 021 for receiving the high frequency signal S _ f. The control terminal of the tri-state buffer U3 is connected to the display control processing unit 010, and receives an initial signal. The output terminal of the tri-state buffer U3 is connected to the laser drive circuit 030 for outputting a target signal. I.e. the tri-state buffer U3 is controlled to be turned on and off by the initial signal.

Optionally, the tri-state buffer U3 is turned on when the control terminal of the tri-state buffer is at the active level when the level of the received initial signal is at the active level. When the tri-state buffer U3 is turned on, it can output the signal received by its input terminal to its output terminal. The initial signal is an initial image enable signal EN0, and the target signal is a target enable signal EN1.

It is assumed that the tri-state buffer U3 is turned on when the level of the initial signal received at its control terminal is an active level, and the initial signal is the initial image enable signal EN0. Fig. 11 is a timing diagram of shaping an initial image enable signal to obtain a target enable signal according to another embodiment of the present application. Taking the signal shaping circuit 020 in the laser projection apparatus shown in fig. 10 as an example, a process of obtaining the target enable signal from the initial image enable signal will be described.

Referring to fig. 10 and 11, in the period from t1 to t2, the level of the initial image enable signal EN0 is high level, the tri-state buffer U3 is turned on after receiving the initial image enable signal EN0 with the high level at its control end, the input end of the tri-state buffer U3 receives the high frequency signal S _ f and is output by the output end of the tri-state buffer U3, that is, the tri-state buffer U3 outputs the target enable signal EN1 with the high level.

In the period from t2 to t3, the level of the initial image enable signal EN0 is high level, and the tri-state buffer U3 is turned on after receiving the initial image enable signal EN0 with the high level at its control end, so that the input end of the tri-state buffer U3 receives the high frequency signal S _ f and is output by the output end of the tri-state buffer U3, that is, the tri-state buffer U3 outputs the target enable signal EN1 with the low level. Thereafter, the process at the period t1 to t2 may be repeated during the period t3 to t4 and during the period t5 to t6, and the process at the period t2 to t3 may be repeated during the period t4 to t 5.

In another alternative of the present applicationIn an implementation manner, fig. 12 provides a schematic diagram of a partial hardware circuit structure of another laser projection apparatus. Referring to fig. 12, the shaping subcircuit 022 may include a logic and device U4. The first input of the logical product device U4 is connected to the display control processing section 010 for receiving the initial signal. A second input of the and logic device U4 is connected to the signal generation sub-circuit 021 for receiving the high frequency signal S _ f. The output end of the logical product device U4 is connected to the laser drive circuit 030 for outputting a target signal. The target signal = the initial signal

A square wave signal. The supply voltage of the logical and device U4 is the same as the voltage of the laser drive circuit. The initial signal is an initial image enable signal EN0, and the target signal is a target enable signal EN1.

Referring to fig. 11 and 12, in the period from t1 to t2, the level of the initial image enable signal EN0 output from the display control processing part 010 is at a high level, and the level of the high frequency signal S _ f output from the signal generation sub-circuit 021 is at a high level, so that after the initial image enable signal EN0 and the high frequency signal S _ f pass through the and device U4, the and device U4 outputs the target enable signal EN1 at a high level. In the period from t2 to t3, the level of the initial image enable signal EN0 output from the display control processing portion 010 is at a high level, and the level of the high frequency signal S _ f output from the signal generation sub-circuit 021 is at a low level, and then the initial image enable signal EN0 and the high frequency signal S _ f pass through the and logic device U4, and then the and logic device U4 outputs the target enable signal EN1 at a low level. Thereafter, the process at the period t1 to t2 may be repeated during the period t3 to t4 and during the period t5 to t6, and the process at the period t2 to t3 may be repeated during the period t4 to t 5.

When the level of the initial image enable signal EN0 output from the display control processing unit 010 is low, if the level of the high-frequency signal S _ f output from the signal generation sub-circuit 021 is low, the initial image enable signal EN0 and the high-frequency signal S _ f pass through the and logic device U4, and then the and logic device U4 outputs the target enable signal EN1 at low level. When the level of the initial image enable signal EN0 output from the display control processing unit 010 is low, if the level of the high frequency signal S _ f output from the signal generation sub-circuit 021 is high, the initial image enable signal EN0 and the high frequency signal S _ f pass through the and logic device U4, and then the and logic device U4 outputs the target enable signal EN1 at low level.

Optionally, referring to fig. 5, 6, 7, 10 and 12, the signal shaping circuit 020 may further include a resistor R. One end of the resistor R is connected to the shaping sub-circuit 022 and the laser drive circuit 030, respectively, and the other end of the resistor R is connected to the reference power source terminal vr. The reference power supply terminal vr may be a ground terminal (GND).

In the embodiment of the present application, the frequency f of the high frequency signal S _ f is greater than or equal to 10 megahertz (MHz), i.e., f

100MHz. The frequency of the target signal is equal to or close to the frequency of the high frequency signal S _ f. Therefore, when the frequency of the target signal is lower than 200 kilohertz (KHz), the noise audible by human ears generated by the inductance and the capacitance around the laser driving circuit can be effectively avoided.

During the process of projecting an image, the drive current supplied to the laser by the laser drive circuit fluctuates due to the voltage ripple of the display control processing section, and a current ripple C shown in fig. 13 is generated, and the current maximum value of the current ripple C needs to be within a fluctuation range m, where m is [ -10% × I0, and 10% × I0]. And the frequency of the current ripple C needs to be more than 250KHz, so that the resetting consistency of the DMD group can be ensured, and the display effect of the displayed projection image is further ensured.

The hardware system of the laser projection equipment has clear specification requirements on the current waveform of the driving current of the laser, and the current waveform meets the following requirements: 0

A

19us，0

B

And under the condition that the current maximum value of 19us and the current ripple C is within the fluctuation range m, the laser projection device can normally operate.

Therefore, to achieve speckle reduction, 0 is ensured

A

19us，0

B

19us and the current maximum of the current ripple C lies within the fluctuation range m. It is necessary to ensure that the loss of brightness of the laser is small and that there is a reduced variation in the drive current of the laser.

In the embodiment of the present application, referring to fig. 5, 6, 10, or 12, the laser projection apparatus may further include a signal conversion circuit 050, where the signal conversion circuit 050 is connected to the display control processing part 010 and the laser driving circuit 030, respectively, and the signal conversion circuit 050 is configured to convert the PWM signal transmitted by the display control processing part 010 into an analog signal and send the analog signal to the laser driving circuit 030.

Due to the high coherence of laser, the laser emitted from the laser projection device irradiates the projection screen to form light and dark spots, which are also called speckles. The light source of the laser projection apparatus is mainly a laser, which may be a semiconductor laser, which is a kind of compound semiconductor. According to the light emitting principle of the laser, when the high frequency changes the drive current of the laser, the formation of the light emitting stable state of the laser can be influenced when the laser generates high-frequency on-off change, so that the laser beams with a plurality of adjacent wavelengths are selected with a high probability, the spectrum width of the laser is expanded, the coherence of the laser beams can be greatly reduced, and the speckle phenomenon appearing in a projection picture is weakened or inhibited from the source.

The application provides a laser projection equipment, drive signal through to the laser instrument carries out the plastic for finally act on the change cycle of the drive current of laser instrument and shorten, the frequency increases, and in a cycle, drive signal's high value level can make the laser instrument light, the low value level is not more than the threshold current of laser instrument, the drive signal that can frequently control the laser instrument and switch on, disconnected has been formed, the luminescence process of normal laser steady state has been influenced, speckle phenomenon has been alleviateed greatly.

Compared with the spot dissipation principle and mode that the spot dissipation components such as the diffusion sheet are arranged in the laser projection equipment and the spatial phase of the laser is increased in the related art, the laser projection equipment provided by the application can achieve the spot dissipation from the source.

If the laser projection device can be a three-color laser projection device, the formation of speckles is diffraction, and the longer the wavelength, the more obvious the diffraction effect. The red laser therefore has more severe speckle, the green laser second, and the blue laser has less speckle. Through the drive current of high frequency, periodic change laser instrument, can expand laser beam's spectral width, change the coherence of laser self from the source, and then weaken the influence of speckle phenomenon to the projection picture, promote three-colour laser projection equipment's picture quality display effect.

And fig. 15 is a flowchart of a laser driving control method according to an embodiment of the present application. The method may be applied in any one of the at least one signal shaping circuit 020 in the laser projection device shown in fig. 1-1, 1-2, 2-1, 2-2 or 2-3, 5, 6, 7, 10 or 12. The laser projection apparatus may further include a display control processing section 010, lasers 040, and at least one laser driving circuit 030, and the lasers 040 include at least one set of lasers in one-to-one correspondence with the at least one laser driving circuit 030. As shown in fig. 15, the method may include:

in step 1501, the display control processing unit outputs an initial drive signal.

Specifically, as described in the foregoing embodiment, the display control processing section outputs the initial driving signal to the light source section while outputting the image driving signal to the light modulation section: an image enable signal or a primary light enable signal EN, and a brightness adjustment signal, also called a current PWM signal. The logical product of these two initial drive signals acts on the laser.

If the three-color laser projection device is applied, the initial driving signal is one of at least one initial image enable signal and at least one initial current control signal, the at least one initial image enable signal is at least one enable signal corresponding to three primary colors of each frame image in the multi-frame display images output by the display control processing part, and the at least one initial current control signal is at least one current control signal corresponding to three primary colors of each frame image in the multi-frame display images output by the display control processing part.

Step 1602, the initial driving signal is shaped to obtain a target driving signal.

Specifically, before the initial driving signal of the display control processing unit reaches the laser, the initial driving signal is output to the laser driving circuit, and is finally transmitted to the laser by the laser driving circuit.

And the signal shaping circuit is used for shaping the initial driving signal to obtain a target driving signal.

The signal shaping may be performed on either or both of the two initial driving signals, where the signal shaping may modulate the initial driving signal with a periodic high-frequency signal having a frequency much higher than that of either of the initial driving signals, or may superimpose the periodic high-frequency signal on the initial driving signal, so as to shape the initial driving signal into a driving signal equal to or close to the high-frequency signal, where a variation period of the driving signal is originally greater than that of either of the initial driving signals.

Step 1503, the target driving signal is transmitted to the corresponding laser.

In the above steps, the shaped initial driving signal is changed into the target driving signal, and finally the target driving signal is transmitted and acted on the laser, so as to change the variation period of the on and off of the laser.

And the frequency of the target driving signal is originally greater than the frequency of the initial image enabling signal and the current PWM signal. And, in one period of the initial image enable signal, a total duration of the target drive signal at the active level is less than a duration of the initial image enable signal at the active level or less than a duration of the active level of the initial PWM current signal. And the value of the low value level of the target driving signal is smaller than the threshold current of the laser and is greater than or equal to 0.

The laser finally receives a target driving signal, and frequent on-off change is carried out under the action of a high-frequency driving signal, so that the light emitting period and wavelength of the laser are influenced, the spectrum width emitted by the laser is widened by influencing the formation of the steady state light emitting state of the laser, the coherence of the laser beam is reduced, the low-coherence laser beam is provided from the source, and the speckle phenomenon is relieved when projection display of a laser projection picture is carried out.

In the laser driving control method provided in the embodiment of the present application, the initial driving signal (which is a driving signal to be received by the laser) output by the display control processing unit may be shaped to obtain the target driving signal, and the target driving signal is transmitted to the corresponding laser driving circuit to drive the corresponding laser to emit light. The variation period of the driving current finally acting on the laser is shortened, the frequency is increased, in the period of a target driving signal, the high-value level of the driving signal can enable the laser to be lightened, the low-value level is not larger than the threshold current of the laser, the driving signal capable of frequently controlling the on and off of the laser is formed, the normal steady-state light emitting process of the laser is influenced, the width of the light emitting spectrum of the laser is widened, the coherence of laser beams is greatly reduced, and when the laser driving signal is applied to projection display of laser projection equipment, the speckle phenomenon can be eliminated or inhibited.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A laser projection device, comprising: a light source comprising a red laser;

display panel, power panel, TV panel; wherein the video image signal output from the TV panel is transmitted to the display panel; the power panel is used for supplying power to each device or partial module on the display panel and the TV panel;

the display panel comprises a display control processing part, wherein the display control processing part is used for generating a modulation driving signal for driving a light modulation device and also generating a driving signal for driving the light source to emit light, and the driving signal comprises an initial image enabling signal and an initial current control signal;

the signal shaping circuit is connected with the display panel, is arranged in a path for transmitting either or both of the initial image enabling signal and the initial current control signal to the red laser and is used for outputting a shaped signal;

the shaped signal is superimposed on either or both of the two signals to form a target drive signal; the frequency of the shaped signal is greater than or equal to 100Mhz;

the red laser is used for emitting light or extinguishing light under the drive of the target drive signal, and the target drive signal is a high-frequency periodic drive signal.

2. A laser projection device as claimed in claim 1, characterized in that the low value level of the shaping signal is equal to 0 or the low value level of the target drive signal is equal to 0.

3. The laser projection device of claim 1, wherein the low level of the shaped signal is less than the turn-on threshold current of the red laser and greater than 0; alternatively, the first and second electrodes may be,

the low level of the target drive signal is less than the turn-on threshold current of the red laser and greater than 0.

4. The laser projection device of claim 1, further comprising a laser drive circuit;

the laser driving circuit is arranged on the power panel or is arranged independently of the power panel.

5. The laser projection device of claim 4, wherein the signal shaping circuit is disposed on the display panel; or, the signal shaping circuit is arranged in a circuit between the laser driving circuit and the display panel; or, the signal shaping circuit is arranged in the laser driving circuit.

6. The laser projection device of claim 1, wherein the shaped signal is a high frequency periodic signal; the waveform is a square wave signal, or a triangular wave signal; or a sawtooth signal.

7. The laser projection device of claim 1, wherein the target driving signal is an image enable signal superimposed by the shaping signal, and the frequency of the target driving signal is much higher than that of the initial image enable signal; alternatively, the first and second electrodes may be,

the target driving signal is a current control signal superposed by the shaping signal, and the frequency of the target driving signal is far higher than that of the initial current control signal.

8. The laser projection device of any of claims 1-7, wherein the light source further comprises a blue laser; alternatively, the light source further comprises a green laser; alternatively, the light source further comprises a blue laser and a green laser;

any of the above lasers is a semiconductor laser.

9. The laser projection device of claim 8, wherein when the light source also includes a blue laser and a green laser, the red laser, the blue laser, and the green laser are individually packaged light emitting units, or are multi-color chips packaged in one light emitting unit.

10. The laser projection device of claim 8, wherein the laser projection device further comprises an optical engine and a lens;

the optical machine comprises an optical modulation device, the light source is used for providing illumination beams which are transmitted to the optical modulation device and the lens, and the lens is an ultra-short-focus projection lens.

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