CN203206190U - Digital micro mirror device driving waveform generator - Google Patents

Abstract

The utility model discloses a digital micro mirror device driving waveform generator. The digital micro mirror device driving waveform generator comprises a PC, a digital micro mirror driver and a voltage converter, wherein communication between the PC and the digital micro mirror driver is realized through a USB to carry out edition and input of parameters, a touch screen is taken as a man-machine interaction interface and is convenient and simple to control and operate, an ARM transmits waveform parameter information to a FPGA through 32 bit parallel communication to generate original driving waveforms, a high level of a driving a voltage can increase to 15V to 200V through voltage boost of the voltage converter, adjustment is convenient and simple, and load current is fed back to the ARM to realize automatic adjustment. The digital micro mirror device driving waveform generator solves a problem of circuit singleness of a digital micro mirror device driving waveform generator in the prior art, can adjust a power source to obtain digital micro mirror driving waveforms having properties of waveform changeability, voltage adjustability and automatic adjustment through parameter change while a driving circuit is not changed.

Description

A kind of Digital Micromirror Device drive waveforms generator

Technical field

The utility model relates to the Digital Micromirror Device that shows image and drives development field, especially a kind of arbitrarily adjustable digital micro-mirror drive waveforms generator.

Background technology

In the up-to-date shadow casting technique, process based on the DLP(digital light at present) the optical projection system competitiveness the strongest, mainly be because its volume is little, compact conformation, lightweight, the image color that shows simultaneously is abundant, brightness is high, contrast is high, definition is good.

Digital Micromirror Device is begun one's study in 1977 by Larry doctor Hornbeck of American TI Company, and always by development and improvement.Digital Micromirror Device is mainly used in the optical projection system, but TI company was devoted to excavate and enlarge its application in recent years, such as stereo display, offset printing, little demonstration and wide spectrum of use etc.

Digital Micromirror Device adopts the method for light modulation to produce image in the DLP optical projection system, and the DLP of an one chip is comprised of three parts: a mainboard with Digital Micromirror Device (for the treatment of video information and driving Digital Micromirror Device); Light source controller and high-pressure mercury lamp (light source that forms optical projection system); Light path system (being used for guiding light).Wherein, Digital Micromirror Device have thousands of structures consistent can be reflective micro mirror, each micro mirror only has " opening " and " pass " two states, can control by drive waveforms the on off state of each micro mirror.

When the DLP system starts working, high-pressure mercury lamp sends high-intensity white light, be radiated on the light source controller of high speed rotating, because the particularity of light source controller (is carried out segmentation with circumference, each section only allows the light of a kind of color in the three primary colors to pass through), the light that sees through light source controller can change according to the order rule of look section.The guiding that sees through the light process light path system of light source controller shines on the digital micro-mirror, those micro mirrors that are in "open" state can be gone out light reflection and be incident upon on the screen, the micro mirror that is in "off" state shows black at screen, image has so just been arranged, because the High Rotation Speed of light source controller, human eye is difficult to identification, the just composograph of three primary colors of seeing.

In the process that shows, the grey scale change that mainly embodies image by control micro mirror " pass " time of " opening "." opening " " pass " of micro mirror can be controlled by binary digit pulse, determined the size of gray value the switching time of micro mirror, opening time is long, the gray-scale pixels of short generation of shut-in time is just shallow, otherwise the short shut-in time of opening time is long, the gray-scale pixels that produces is just dark, therefore can produce gray level image by changing control impuls.

In whole system, can " opening " "Off" state of control micro mirror has very important effect, accurately control " opening " "Off" state and " opening " " pass " time of micro mirror, can be to the correctness of image, gray scale presents and has a significant impact, and certainly will affect the visual effect of human eye.In working control, the reversal rate of micro mirror can reach khz, " opening " "Off" state of each micro mirror is different, on the other hand, micro mirror is because self material structure and physical characteristic, can special requirement be proposed to control signal, such as the reaction time of opening, optimal drive voltage and optimal drive waveform etc., these objective factors have proposed strict requirement all for the drive waveforms of digital micro-mirror, just need different drive waveforms for different products, and do not have pervasive drive waveforms generator now, if therefore revise drive circuit, it certainly will be a thing that expend energy on sinks money again.

The utility model content

The purpose of this utility model is a kind of Digital Micromirror Device drive waveforms generator that provides for the deficiencies in the prior art, can produce by this generator that waveform is any, level is adjustable, self-adjusting drive waveforms, universality is strong, can realize arranging and control through touch-screen and PC, so that the generation of drive waveforms becomes is various, convenient and flexibly, greatly improved operating efficiency and work quality.

The concrete technical scheme that realizes the utility model purpose is:

A kind of Digital Micromirror Device drive waveforms generator, characteristics are that this generator comprises: PC, digital micro-mirror driver and electric pressure converter, and the digital micro-mirror driver connects respectively PC and electric pressure converter, wherein:

PC: be connected with the digital micro-mirror driver by USB, be used for editor and input that Digital Micromirror Device drives parameter;

The digital micro-mirror driver: formed by microprocessor ARM, dynamic random access memory SDRAM, FLASH, programmable logic device FPGA, two dynamic random access memory DDR2, touch-screen TFT and light source controller, wherein:

A) microprocessor ARM be used for PC and FPGA between communicate by letter, process current feedback information, control light source controller and touch-screen;

B) dynamic random access memory SDRAM is used for microprocessor ARM when work, interim store data;

C) FLASH is used for depositing main program;

D) touch-screen TFT is used for demonstration and the control operation of menu;

E) programmable logic device FPGA is for generation of the target drives waveform of digital micro-mirror;

F) two dynamic random access memory DDR2 are used for depositing complicated drive waveforms information temporarily;

Electric pressure converter: be used for voltage transitions and current feedback, the amplitude that programmable logic device FPGA is produced is that the original driving signal of 3.3V converts the driving signal that adjustable range is 30-60V to, simultaneously with load current feedback to the microprocessor ARM on the digital micro-mirror driver.

Compared with prior art, the beneficial effects of the utility model are:

⑴, simple and convenient, easy to operate, can edit and input the driving parameter by PC, as human-computer interaction interface, simple and clear, easy to operate with touch-screen;

⑵, employing FPGA are as waveform generator, and precision is high, and changeability is strong, and synchronism is good.The external voltage transducer, the driving voltage adjustable range is wide, and driving force is strong, avoided revising driver for the different digital micro mirror, be the strong drive waveforms generator of a universality;

⑶, load current is carried out Real Time Monitoring, and then automatically adjust drive waveforms, obtain optimal drive voltage, avoid electric current excessive.

Description of drawings

Fig. 1 is the utility model structured flowchart;

Fig. 2 is the structured flowchart of the utility model digital micro-mirror driver;

Fig. 3 is the digital micro-mirror working state schematic representation of the utility model digital micro-mirror driver drives;

Fig. 4 is the utility model microprocessor ARM control flow chart;

Fig. 5 is the utility model FPGA workflow diagram;

Fig. 6 is a kind of drive waveforms figure that the utility model produces.

Embodiment

Consult Fig. 1, the utility model is by PC, the digital micro-mirror driver, and electric pressure converter three parts consist of.PC is realized communicating by letter with the digital micro-mirror driver by USB, can realize the editor of waveform, setting and the modification of parameter at PC; The original driving signal that the digital micro-mirror driver produces is delivered to electric pressure converter, simultaneously electric pressure converter with load current feedback to the digital micro-mirror driver; The voltage of electric pressure converter is directly supplied with by external power source, and size can be passed through power adjustment, and adjustable range is 30V-60V.

Consult Fig. 2, digital micro-mirror driver of the present utility model comprises the ARM(microprocessor, model S3C2440), the FPGA(programmable logic device, model EP3C16F484C6N), TFT touch-screen, SDRAM(dynamic random access memory), FLASH, DDR2(dynamic random access memory) and light source controller.

ARM realizes following functions:

A) communicate by USB with PC, realize the transmission of relevant parameter;

B) detect also driving light source controller;

C) control touch-screen, as human-computer interaction interface, the display operation menu is also realized control;

D) communicate with FPGA, the relevant information of the drive waveforms that will receive from PC passes to FPGA, adopts the mode of parallel communications, greatly improves the efficient of communication;

E) the current feedback information of receiver voltage transducer, and analyze, and then the realization waveform is adjusted automatically.

FPGA is for generation of drive waveforms, and the waveform accuracy of generation is high, and synchronism is good, and changeability is strong.And, utilize DDR2 can conveniently produce complicated drive waveforms.

Consult Fig. 3, the digital micro-mirror of the utility model digital micro-mirror driver drives has three electrodes, and control needs three signals:

,

,

Wherein

Bias voltage,

With

It is driving voltage.By changing this three kinds of signals, can change " opening " "Off" state and " opening " " pass " time of digital micro-mirror.Wherein the control figure micro mirror is in the level of "open" state and is

The level that the control figure micro mirror is in "off" state is

Pressure reduction is higher, and the deflection angle of digital micro-mirror is larger.When digital micro-mirror is in "open" state,

Be high level, the adhesive of the digital micro-mirror left side, the light of light source just in time enters lens, and then is throwed through mirror-reflection, presents bright at screen; When being in "off" state,

Be high level, micro mirror the right adhesive, light is not throwed, and presents black at screen.Different digital micro-mirrors, the ability of bearing voltage is different, and optimum operating voltage is different, and is different to the requirement of driving voltage.

Consult Fig. 4, Fig. 4 is the control flow chart of the utility model ARM.After powering on, the ARM microprocessor is at first carried out initialize routine, comprises the initialization of man-machine interface and the initialization of digital micro-mirror; Then start light source controller, and it is detected, if working properly then enter steady-working state, otherwise would close light source; The system stability duration of work, experience following process:

Whether have input, have and then carry out associative operation if a) detecting man-machine interface;

B) whether normally detect load current, if undesired then adjust waveform parameter;

C) whether detection light source work is normal, if undesired then close light source.

Consult Fig. 5, Fig. 5 is the workflow diagram of the utility model FPGA.After powering on, at first carry out initialization, putting digital micro-mirror is "off" state, then enters operating state, and operating state mainly comprises following two processes:

Whether have instruction or parameter transmission, have then instruction to be judged and carried out if a) detecting ARM;

B) parameter is loaded, and for the parameter of complexity, carries out storage and the processing of parameter in conjunction with DDR2.

Consult Fig. 6, Fig. 6 is a kind of drive waveforms that the utility model is realized.The output amplitude of FPGA is the driving signal of 3.3V, ,

,

Obtain by three IO mouths respectively, wherein t ₁And t ₂Can change by programming t ₁Size can reach nanosecond.Power supply changeover device boosts to driving signal, because

,

,

The power supply of three electrodes is independently, and different voltage can be provided, and the amplitude among Fig. 6 is respectively 30V, 15V, 30V.According to the principle of digital micro-mirror work,

, , can obtain the waveform of final driving signal.

So far, in whole the setting, need not to carry out the change of circuit, only need carry out the setting of parameter and the adjusting of power supply, can obtain waveform changeable, voltage is adjustable, self-adjusting digital micro-mirror drive waveforms.

Claims (1)

1. Digital Micromirror Device drive waveforms generator is characterized in that this generator comprises: PC, digital micro-mirror driver and electric pressure converter, and the digital micro-mirror driver connects respectively PC and electric pressure converter, wherein:

PC: be connected with the digital micro-mirror driver by USB, be used for editor and input that Digital Micromirror Device drives parameter;

The digital micro-mirror driver: formed by microprocessor ARM, dynamic random access memory SDRAM, FLASH, programmable logic device FPGA, two dynamic random access memory DDR2, touch-screen TFT and light source controller, wherein:

A) microprocessor ARM be used for PC and FPGA between communicate by letter, process current feedback information, control light source controller and touch-screen;

B) dynamic random access memory SDRAM is used for microprocessor ARM when work, interim store data;

C) FLASH is used for depositing main program;

D) touch-screen TFT is used for demonstration and the control operation of menu;

E) programmable logic device FPGA is for generation of the target drives waveform of digital micro-mirror;

F) two dynamic random access memory DDR2 are used for depositing complicated drive waveforms information temporarily;

Electric pressure converter: be used for voltage transitions and current feedback, the amplitude that programmable logic device FPGA is produced is that the original driving signal of 3.3V converts the driving signal that adjustable range is 30-60V to, simultaneously with load current feedback to the microprocessor ARM on the digital micro-mirror driver.

Images