Patent Publication Number: US-7895968-B2

Title: Liquid droplet ejection apparatus, method for forming structure, and method for manufacturing electro-optic device

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2005-099941, filed on Mar. 30, 2005, the entire contents of which are incorporated herein by reference. 
     BACKGROUND 
     The present invention relates to a liquid droplet ejection apparatus, a method for forming a structure, and a method for manufacturing an electro-optic device. 
     Typically, a color filter substrate of a liquid crystal display is provided with a dot pattern consisting of a plurality of color films each having a dot like shape. The color films are provided through a liquid phase process. In the liquid phase process, liquid containing color film forming material is ejected onto color film forming sections, each of which is encompassed by a wall. The liquid is then dried in the color film forming sections so as to form the color films. 
     As described in Japanese Laid-Open Patent Publication No. 2004-341114, an inkjet method may be used as the liquid phase process. Specifically, according to the inkjet method, liquid is ejected onto each of color film forming sections as a microdroplet. The microdroplet is then dried to provide a color film. 
     The inkjet method reduces consumption of the liquid compared to other liquid phase processes including a spin coat method and a dispenser method. Further, the position of each color film is adjusted with improved accuracy. However, in the inkjet method, the distribution of concentrations of the color film forming material in the microdroplets varies depending on the viscosity of the microdroplets, the angle of contact with the color film forming section, and the concentration of the color film forming material in the process of drying the microdroplets. Therefore, the thickness of the dried color film cannot be controlled to have a desired thickness distribution. 
     SUMMARY 
     An advantage of some aspect of the invention is to provide a liquid droplet ejection apparatus and a structure forming method that form a structure having a desired structure profile and to provide a method for manufacturing an electro-optic device that has a color film or a light emission element having a desired structure profile. 
     To achieve the foregoing and other objectives and in accordance with the purpose of the present invention, according to a first aspect of the invention, a liquid droplet ejection apparatus is provided. The apparatus includes: a liquid droplet ejection portion that ejects a liquid droplet containing a structure forming material onto a substrate; and drying means that dries the droplet on the substrate, thereby forming a structure made of the structure forming material. The drying means includes: an energy outputting section that outputs energy onto the droplet on the substrate, thereby causing the structure forming material in the droplet to flow; and an energy profile controlling section controlling an energy profile of the energy output by the energy outputting section to be an energy profile that permits the structure forming material to flow such that the structure forming material is distributed in accordance with a structure profile of the structure to be formed. 
     According to a second aspect of the invention, a method for forming a structure on a substrate is provided. The method includes: ejecting a droplet containing a structure forming material onto the substrate; drying the droplet on the substrate, thereby forming a structure made of the structure forming material; and radiating energy onto the droplet on the substrate before or when drying the droplet, thereby permitting the structure forming material to flow such that the structure forming material is distributed in accordance with a structure profile of the structure to be formed. The radiated energy has an energy profile based on structure profile information related to the structure profile of the structure to be formed. 
     According to a third aspect of the invention, a method for manufacturing an electro-optic device is provided. The electro-optic device includes a substrate on which a color film is formed. The method includes forming the color film on the substrate by the above method for forming a structure on a substrate. 
     According to a fourth aspect of the invention, another method for manufacturing an electro-optic device is provided. The electro-optic device includes a substrate on which a light emission element is formed. The method includes forming the light emission element on the substrate by the above method for forming a structure on a substrate. 
     Other aspects and advantages of the invention will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which: 
         FIG. 1  is a perspective view showing a liquid crystal display according to one embodiment of the present invention; 
         FIG. 2  is a perspective view showing a color filter substrate of the liquid crystal display of  FIG. 1 ; 
         FIG. 3  is a cross-sectional view taken along the line  3 - 3  of  FIG. 2 ; 
         FIG. 4  is a perspective view schematically showing a liquid droplet ejection apparatus according to the embodiment; 
         FIG. 5  is a perspective view schematically showing a liquid droplet ejection head of the liquid droplet ejection apparatus of  FIG. 4 ; 
         FIG. 6  is a cross-sectional view for explaining the liquid droplet ejection head of  FIG. 5 ; 
         FIG. 7  is another cross-sectional view for explaining the liquid droplet ejection head of  FIG. 5 ; 
         FIGS. 8A ,  8 B, and  8 C are diagrams for explaining a beam profile for a color film forming area according to the embodiment; 
         FIG. 9  is a block circuit diagram showing the electric configuration of the liquid droplet ejection apparatus of  FIG. 4 ; 
         FIG. 10  is a timing chart for explaining operational timing of a piezoelectric element and a semiconductor laser; and 
         FIGS. 11A ,  11 B, and  11 C are diagram for explaining a beam profile for a color film forming area according to a modified embodiment. 
     
    
    
     DESCRIPTION OF EXEMPLARY EMBODIMENTS 
     One embodiment of the present invention will be described below according to  FIGS. 1 to 10 . 
     First, a liquid crystal display  1  as an electro-optic device according to this embodiment will be described.  FIG. 1  is a perspective view showing the liquid crystal display  1 ,  FIG. 2  is a perspective view showing a color filter substrate  10  provided in the liquid crystal display  1 , and  FIG. 3  is a cross-sectional view taken along the line  3 - 3  of  FIG. 2 . 
     As shown in  FIG. 1 , the liquid crystal display  1  comprises a liquid crystal panel  2 , and an illumination device  3  illuminating the liquid crystal panel  2  with an area light L 1 . 
     The illumination device  3  has light sources  4 , which are, for example, LEDs, and a light guide  5 . The light guide  5  produces the area light L 1 , which is illuminated onto the liquid crystal panel  2 , from the light emitted by the light sources  4 . The liquid crystal panel  2  has a color filter substrate  10  and an element substrate  11  that are bonded together. Non-illustrated liquid crystal molecules are sealed between the color filter substrate  10  and the element substrate  11 . The position of the liquid crystal panel  2  is determined relative to the position of the illumination device  3  in such a manner that the color filter substrate  10  is located closer to the illumination device  3  than the element substrate  11 . 
     The element substrate  11  is formed by a rectangular non-alkaline glass and includes an element forming surface  11   a , which is a surface of the element substrate  11  facing the illumination device  3  (the color filter substrate  10 ). A plurality of scanning lines  12  are provided and equally spaced on the element forming surface  11   a , extending in direction X. The scanning lines  12  are electrically connected to a scanning line driver circuit  13  arranged at an end of the element substrate  11 . In correspondence with a scanning control signal of a control circuit (not shown), the scanning line driver circuit  13  generates a scanning signal for driving selected ones of the scanning lines  12  at predetermined timings. 
     A plurality of data lines  14  are formed and equally spaced on the element forming surface  11   a , extending in direction Y perpendicular to each scanning line  12 . The data lines  14  are electrically connected to a data line driver circuit  15 , which is formed at the end of the element substrate  11 . In correspondence with display data sent from a non-illustrated external device, the data line driver circuit  15  produces a data signal and outputs the data signal to a corresponding one of the data lines  14  at a predetermined timing. 
     A plurality of pixel areas  16  are formed on the element forming surface  11   a . The pixel areas  16  are aligned in a matrix-like shape of “i” rows by “j” columns. Each of the pixel areas  16  is encompassed by an adjacent pair of the scanning lines  12  and an adjacent pair of the data lines  14  and is connected to the corresponding scanning line  12  and the associated data line  14 . A non-illustrated control element formed by, for example, a TFT and a pixel electrode are formed in each pixel area  16 . The pixel electrode is formed by a transparent conductive film formed of, for example, ITO. In other words, the liquid crystal display  1  is an active-matrix-type liquid crystal display that includes the control element such as a TFT. 
     An non-illustrated alignment film is provided under the scanning lines  12 , the data lines  14 , and the pixel areas  16  (on a side facing the color filter substrate  10 ) to cover the element forming surface  11   a  entirely. The alignment film is subjected to alignment treatment such as rubbing treatment. The alignment film thus orientates the liquid crystal molecules in the vicinity of the alignment film in a certain direction. 
     As shown in  FIG. 2 , the color filter substrate  10  includes the rectangular transparent glass substrate  21  formed of non-alkaline glass. 
     As shown in  FIG. 3 , the color filter substrate  10  includes a color film forming surface  21   a , which is a surface of the color filter substrate  10  that faces the element substrate  11 . A light shielding layer  22   a  is provided on the color film forming surface  21   a . The light shielding layer  22   a  is formed of resin containing light shielding material such as chrome and carbon black. The light shielding layer  22   a  has a grid-like shape corresponding to the scanning lines  12  and the data lines  14 . A liquid repelling layer  22   b  is defined on the light shielding layer  22   a . The liquid repelling layer  22   b  is a resin layer formed of fluorinated resin that repels liquid droplets FD (see  FIG. 6 ), which will be later described. The liquid repelling layer  22   b  prevents the droplets FD from protruding from corresponding color film forming areas  23 , which also will be explained later. 
     Referring to  FIG. 2 , a grid-like wall  22  is formed on a substantially entire portion of the color film forming surface  21   a  by the light shielding layer  22   a  and the liquid repelling layer  22   b . The color film forming areas  23 , which are portions of the color film forming surface  21   a  that are encompassed by the corresponding portions of the wall  22 , are aligned in a matrix-like shape of “i” rows by “j” columns. Each of the color film forming areas  23  is opposed to the corresponding one of the pixel areas  16 . In this embodiment, each of the color film forming areas  23  has a substantially square in which the length in a direction Y consists of a pixel width WP. 
     In this embodiment, the columns of the color film forming areas  23  are sequentially numbered in a direction opposite to direction Y as a first column to an “i”th column. 
     As shown in  FIG. 3 , a color film  24  having a dot like shape is formed in each of the color film forming areas  23 . The color films  24  allow light L 1  from the illumination device  3  to pass therethrough to be converted into colored light. The color films  24  are arranged to form a predetermined dot pattern. The color films  24  include red films  24 R, green films  24 G, and blue films  24 B, which are provided in a manner alternating in this order along direction X of  FIG. 2 . 
     The color films  24  are made of a color film forming material (e.g. organic pigments) as a structure forming material. The color films  24  are provided using a liquid droplet ejection apparatus  30  (see  FIG. 4 ), which will be described later. Specifically, microdroplets Fb (see  FIG. 6 ) containing the color film forming material are ejected onto the corresponding color film forming areas  23  through ejection nozzle holes N (see  FIG. 5 ). The microdroplets Fb on the color film forming surface  21   a  are agitated and dried by application of a laser beam B as energy, which will be described later. The color films  24  are thus provided. 
     The thickness distribution as a structure profile of the color films  24  are made uniform within the corresponding color film forming areas  23  and uniform between the color film forming areas  23  by a planarization sequence, which will be described later. 
     Referring to  FIG. 3 , an opposing electrode  25  is formed on the color films  24 . The opposing electrode  25  opposes the pixel electrodes of the element substrate  11 . A predetermined common potential is provided to the opposing electrode  25 . An alignment film  26  is defined on the opposing electrode  25  and orientates the liquid crystal molecules in the vicinity of the opposing electrode  25  in a certain direction. 
     In accordance with line-sequential scanning, the scanning line driver circuit  13  sequentially drives the scanning lines  12  one by one. This sequentially activates the control elements of the pixel areas  16 . Activation of each control element is maintained only for the time corresponding to the time in which the associated scanning line  12  is activated. In correspondence with the activated control element, the data signal generated by the data line driver circuit  15  is sent to the associated pixel electrode through the corresponding data line  14  and the control element. The orientation of the liquid crystal molecules is thus held in a state in which the light L 1  from the illumination device  3  is modulated in correspondence with the difference between the potential of the pixel electrode of the element substrate  11  and the potential of the opposing electrode  25  of the color filter substrate  10 . Accordingly, by selectively passing the modulated light L 1  through a non-illustrated deflection plate, the liquid crystal panel  2  displays a desired full-color image through the color filter substrate  10 . 
     The liquid droplet ejection apparatus  30  used for forming the color films  24  will hereafter be described.  FIG. 4  is a perspective view showing the liquid droplet ejection apparatus  30 . 
     As shown in  FIG. 4 , the liquid droplet ejection apparatus  30  includes a parallelepiped base  31 . The base  31  is provided in such a manner that the longitudinal direction of the base  31  extends in direction Y with the color filter substrate  10  mounted on a substrate stage  33 , which will be described later. A pair of guide grooves  32  are defined in the upper surface of the base  31  and extend throughout the base  31  in direction Y. The substrate stage  33  having a non-illustrated linear movement mechanism corresponding to the guide grooves  32  is secured to the upper surface of the base  31 . The linear movement mechanism of the substrate stage  33  is a threaded type linear movement mechanism having, for example, a threaded shaft (a drive shaft) extending along the guide grooves  32  in direction Y and a ball nut that is engaged with the threaded shaft. The drive shaft of the linear movement mechanism is connected to a y-axis motor MY (see  FIG. 9 ), which is a stepping motor. The y-axis motor MY rotates in a forward or reverse direction in response to a drive signal corresponding to a predetermined number of steps. This advances or retreats (moves) the substrate stage  33  at a predetermined transport speed Vy along direction Y by an amount corresponding to the number of steps. 
     In this embodiment, as shown in  FIG. 4 , when the base  31  is located at a foremost position in direction Y (as indicated by the solid lines in  FIG. 4 ), it is defined that the base  31  is arranged at a proceed position. When the base  31  is located at a rearmost position in direction Y (as indicated by the double-dotted broken lines in  FIG. 4 ), it is defined that the base  31  is arranged at a return position. 
     A suction type chuck mechanism (not shown) is provided on a mounting surface  34 , which is the upper surface of the substrate stage  33 . When the color filter substrate  10  is mounted on the mounting surface  34  with the surface having the color film forming areas  23  facing upward, the color filter substrate  10  is positioned with respect to the mounting surface  34 . The substrate stage  33  is then advanced at the transport speed Vy in direction Y in such a manner that the color film forming areas  23  move at the transport speed Vy in direction Y. 
     A pair of supports  35   a ,  35   b  are provided at opposing sides of the base  31  in direction X. The supports  35   a ,  35   b  support a guide member  36  extending in direction X. The longitudinal dimension of the guide member  36  is greater than the dimension of the substrate stage  33  in direction X. An end of the guide member  36  is projected beyond the support  35   a . A non-illustrated maintenance unit is arranged immediately below the projected end of the guide member  36 . The maintenance unit wipes off a nozzle surface  41   a  (see  FIG. 5 ) of a liquid droplet ejection head FH, which will be explained later, thus cleansing the nozzle surface  41   a.    
     A tank  37  is located on the guide member  36  and retains color film forming liquids F (see  FIG. 6 ) of the three colors. The color film forming liquid F of each of the colors is prepared by dispersing color film forming material (which is, for example, tetradecane) of the corresponding color in dispersion medium. The tank supplies color film forming liquids F to the ejection head FH, which will be described later. 
     As shown in  FIG. 4 , a carriage  39  is secured to the bottom surface of the guide member  36 . The carriage  39  has a non-illustrated linear movement mechanism provided in correspondence with a pair of upper and lower guide rails  38 , which extend in direction X. The linear movement mechanism of the carriage  39  is formed by a threaded type linear movement mechanism having, for example, a threaded shaft (a drive shaft) extending along the guide rails  38  in direction Y and a ball nut engaged with the threaded shaft. The drive shaft of the linear movement mechanism is connected to an x-axis motor MX (see  FIG. 9 ), which is a stepping motor. The x-axis motor MX rotates in a forward or reverse direction in response to a drive signal corresponding to a predetermined number of steps. This advances or retreats (moves) the carriage  39  along direction X by an amount corresponding to the number of the steps. 
     In this embodiment, referring to  FIG. 4 , when the carriage  39  is located at a position closest to the support  35   a  (as indicated by the solid lines in  FIG. 4 ), or when the carriage  39  is located at a foremost position in direction X, it is defined that the carriage  39  is arranged at a proceed position. When the carriage  39  is located at a position closest to the support  35   b  (as indicated by the double-dotted broken lines in  FIG. 4 ), or when the carriage  39  is located at a rearmost position in direction X, it is defined that the carriage  39  is arranged at a return position. 
     As shown in  FIG. 4 , the liquid droplet ejection head FH is arranged below the carriage  39  and extends in direction X. The ejection head FH forms a liquid droplet ejecting portion of the three colors (red, green, and blue) corresponding to the color films  24 R,  24 G,  24 B.  FIG. 5  is a perspective view showing the ejection head FH with the bottom surface of the ejection head FH (i.e. the surface of the ejection head FH that is opposed to the substrate stage  33 ) facing upward.  FIG. 6  is a cross-sectional view showing the interior of a main portion of the ejection head FH. 
     As shown in  FIG. 5 , a nozzle plate  41  is provided on the bottom surface of the ejection head FH. The bottom surface of the nozzle plate  41  (the nozzle surface  41   a ) includes 180 nozzle holes N that eject the microdroplets Fb, as will be later explained. The nozzle holes N extend through the nozzle plate  41  and are aligned in direction X and equally spaced. The pitch of the nozzle holes N is equal to the pitch of the color film forming areas  23 . The nozzle holes N oppose the corresponding color film forming areas  23  when the color filter substrate  10  is (the color film forming areas  23  are) linearly reciprocated along direction Y. Each of the nozzle holes N extends perpendicular to the nozzle surface  41   a  and perpendicular to the surface of the color filter substrate  10  having the color film forming areas  23 . The microdroplets Fb (see  FIG. 6 ) ejected through the nozzle holes N thus travel along direction Z. 
     As shown in  FIG. 6 , cavities  42 , or pressure chambers, are defined in the ejection head FH above the corresponding nozzle holes N direction Z. Each cavity  42  communicates with the tank  37  through a corresponding communication bore  43  and a supply line  44 , which is provided commonly for the communication bores  43 . The color film forming liquid F of the corresponding color is thus introduced from the tank  37  into each cavity  42 . The cavity  42  then provides the color film forming liquid F to the associated nozzle hole N. 
     An oscillation plate  45  is arranged above the cavities  42 . The oscillation plate  45  is capable of oscillating in a vertical direction. Through such oscillation, oscillation plate  45  selectively increases and decreases the volume of each cavity  42 . One hundred and eighty piezoelectric elements PZ are arranged above the oscillation plates  45  and in correspondence with the nozzle holes N. Each of the piezoelectric elements PZ receives a corresponding drive signal, which is a corresponding piezoelectric element drive signal COM 1  (see  FIG. 9 ). In response to the drive signal, the piezoelectric element PZ contracts and extends in the vertical direction, thus oscillating the associated oscillation plate  45  in the vertical direction. 
     Through such contraction and extension, the piezoelectric element PZ increases and then decreases the volume of the corresponding cavity  42 . The color film forming liquid F is thus ejected from the corresponding nozzle hole N as the microdroplet Fb by an amount corresponding to the decrease of the volume of the cavity  42 . The microdroplet Fb is then received by the color film forming surface  21   a  located immediately below the nozzle hole N. 
     In this embodiment, a position at which the microdroplet Fb is received by the corresponding color film forming area  23  is defined as a target ejecting position Pa. In this embodiment, a plurality of microdroplets Fb are ejected onto each target ejecting position Pa to form a droplet FD of the united microdroplets. Fb in each color film forming area  23 . 
     As shown in  FIG. 4 , a laser head LH, which is drying means (a drier), is provided below the carriage  39  and forward from the ejection head FH in direction Y. With reference to  FIG. 5 , the bottom surface of the laser head LH includes 180 radiation ports  47 , which are provided in correspondence with the nozzle holes N at positions forward from the nozzle holes N in direction Y. 
     As shown in  FIG. 6 , a semiconductor laser array LD having a plurality of semiconductor lasers L is provided in the laser head LH. The semiconductor lasers L are arranged in correspondence with the radiation ports  47 . Each of the semiconductor lasers L receives a drive signal for driving the semiconductor laser L, which is a laser drive signal COM 2  (see  FIG. 9 ). In response to the drive signal, the semiconductor laser L radiates a laser beam B in wavelength region allowing the color film forming liquid F (droplet FD) to be agitated and dried. 
     In the laser head LH, a phase modulating portion  48  forming an energy profile controlling section, a cylindrical lens Lz 1 , and a polygon mirror  49  and a scanning lens Lz 2  forming an energy scanning section are provided near each of the semiconductor lasers L at a position corresponding to the corresponding radiation port  47 . The phase modulating portion  48 , the cylindrical lens Lz 1 , the polygon mirror  49  and the scanning lens Lz 2  are provided in order from the position closest to the corresponding semiconductor laser L. 
     Each phase modulating portion  48  is constituted by a plurality of diffractive elements which are mechanically or electrically driven, or a spatial light modulator such as liquid crystals, and receives a signal for driving the phase modulating portion  48  (phase modulating portion drive signal COM 3 , see  FIG. 9 ) to subject the laser beam B from the semiconductor laser L to preset predetermined phase modulation. Specifically, each phase modulating portion  48  carries out phase modulation corresponding to each piece of beam profile forming information BPI based on a plurality of pieces of beam profile forming information BPI (first agitation profile forming information BPI 1  and second agitation profile forming information BPI 2 ). Each phase modulating portion  48  switches the phase modulation in timing based on a beam profile sequence BPS as energy profile information described later. 
     The cylindrical lens Lz 1  has curvature only in direction Z. The cylindrical lens Lz 1  performs “optical face tangle error correction” for the polygon mirror  49 . The cylindrical lens Lz 1  guides the laser beam B to the polygon mirror  49 . The polygon mirror  49  has thirty-six reflective surfaces M, which define a regular triacontakaihexagon (a regular thirty-six-sided polygon) as a whole. The reflective surfaces M are rotated by a polygon motor MP (see  FIG. 9 ) in a direction indicated by arrow R of  FIG. 6 . Every time the rotational angle θp of the polygon mirror  49  is advanced at 10 degrees in direction R, the reflective surface M that receives the laser beam B is switched from a preceding reflective surface M to a following reflective surface M. The scanning lens Lz 2  is defined by an f-theta lens that keeps constant the scanning speed on the color film forming surface  21   a  of the laser beam B reflected and deflected by the polygon mirror  49 . 
     In  FIG. 6 , the laser beam B from the cylindrical lens Lz 1  is received by the end of the reflective surface M (Ma) of the polygon mirror  49  located forward in direction R. The deflection angle of the laser beam B, which is reflected and deflected by the polygon mirror  49 , is a deflection angle θ 1  (in this embodiment, five degrees). In this embodiment, in the state of  FIG. 6 , it is defined the rotational angle θp of the polygon mirror  49  is zero degrees. 
     When the laser drive signal COM 2  and the phase modulating portion drive signal COM 3  are supplied to the semiconductor laser L and the phase modulating portion  48  when the rotation angle θp of the polygon mirror  49  is zero degrees, the laser beam B from the semiconductor laser L is subjected to phase modulation by the phase modulating portion  48 . When the laser beam B subjected to phase modulation is introduced into the cylindrical lens Lz 1 , the cylindrical lens Lz 1  adjusts the optical axis of the laser beams B in relation to a direction orthogonally crossing the sheet face and guides the laser beam B to the polygon mirror  49 . The polygon mirror  49  into which the laser beam B has been introduced reflects and deflects the laser beam B in the direction of the deflection angle θ 1  in relation to the optical axis LzA by the reflection surface Ma and guides the laser beam B onto the color film forming surface  21   a  via the scanning lens Lz 2 . The laser beam B guided to the color film forming surface  21   a  forms a laser beam cross section (beam spot) having a certain intensity distribution (beam profile as an energy profile) on the color film forming surface  21   a  in response to phase modulation of the phase modulating portion  48 . When the droplet FD deposited at the target ejecting position Pa is transferred in direction Y at a transport speed Vy and enters the beam spot, the droplet FD is irradiated with the laser beam B of a predetermined beam profile deflected and reflected by the reflection surface Ma. 
     In this embodiment, a position at which the beam spot is formed when the rotation angle θp is zero degrees is referred to as a radiation start position Pe 1 . In this embodiment, as shown in  FIG. 6 , a distance between the radiation start position Pe 1  and the target ejecting position Pa is an irradiation standby distance Ly 1 , and time after ejection of the microdroplet Fb is started until the microdroplet Fb (droplet FD) arrives at the radiation start position Pe 1  is referred to as standby time T. 
     Subsequently, the polygon mirror  49  rotates in the direction R, and when its rotation angle θp becomes substantially ten degrees, the polygon mirror  49  deflects and reflects the laser beam B in the direction of a deflection angle θ 2  (−5° in this embodiment) in relation to the optical axis LzA by the rear end of the reflection surface Ma with respect to direction R, and guides the laser beam onto the color film forming surface  21   a  via the scanning lens Lz 2  as shown in  FIG. 7 . The laser beam B guided to the color film forming surface  21   a  forms a beam spot of a predetermined beam profile on the color film forming surface  21   a  in response to phase modulation of the phase modulating portion  48 . 
     In this embodiment, a position at which the beam spot is formed when the rotation angle θp is substantially ten degrees is referred to as an radiation end position Pe 2 , and a region between the radiation end position Pe 2  and the radiation start position Pe 1  is referred to as a scanning zone Ls. The width (scanning width Ly 2 ) of the scanning zone Ls in direction Y is set to a width equal to the formation pitch of the color film forming areas  23  along direction Y. 
     That is, the laser head LH is configured to scan the laser beam B (repeats movement from the radiation start position Pe 1  to the radiation end position Pe 2 ) in a predetermined cycle (scanning cycle=scanning width Ly 2 /transport speed Vy) along direction Y with the color film forming area  23  as a unit by deflection and reflection by the polygon mirror  49 . 
     The rotation speed of the polygon motor MP (see  FIG. 9 ) is set to a speed such that the laser beam B is scanned only once while each color film forming area  23  is conveyed from the radiation start position Pe 1  to the radiation end position Pe 2 . That is, each droplet FD passing through the scanning zone Ls is irradiated with the laser beam B with its relative radiating position made stationary by scanning of the laser beam B. 
     The laser head LH (semiconductor laser L and phase modulating portion  48 ) receives the laser drive signal COM 2  and the phase modulating portion drive signal COM 3  to form a beam profile corresponding to the phase modulating portion drive signal COM 3  with in a cycle synchronous with the scanning cycle of the laser beam B. 
     A beam profile as an energy profile in this embodiment will now be described below.  FIGS. 8A ,  8 B and  8 C and  FIG. 9  are diagrams for explaining the beam profile. In  FIG. 8A , the abscissa represents relative positions along direction Y where the rear end of the beam spot with respect to direction Y is a base point (zero point), and the ordinate represents irradiation intensities of the laser beam.  FIG. 8B  is a diagram for explaining the state of the droplet FD corresponding to the beam profile shown with the solid line of  FIG. 8A .  FIG. 8C  shows a thickness distribution of the color film  24  corresponding to the beam profile of  FIG. 8A . 
     The laser head LH forms a beam profile (first agitation profile BP 1 ) having a sharp peak of radiation intensity only in a rear portion with respect to direction Y of the color film forming area  23  as shown with the solid line in  FIG. 8A , based on the beam profile forming information BPI (first agitation profile forming information BPI 1 ). 
     The first agitation profile BP 1  has the maximum value of its radiation intensity set to an intensity for sufficiently inhibiting evaporation of the color film forming material and the dispersion medium and inducing thermal convection of the color film forming material and the dispersion medium in the corresponding droplet FD. The first agitation profile BP 1  is formed with a substantially same intensity over the entire width of the color film forming area  23  in direction X along a direction vertical to the sheet face of  FIG. 8A , i.e. direction X. 
     When the droplet FD formed on the color film forming area  23  is irradiated with the laser beam B of the first agitation profile BP 1 , thermal convection of the color film forming material and the dispersion medium is induced in the droplet FD in a front portion and in a rear portion with respect to direction Y as shown with arrows of  FIG. 8B . The extent of thermal convection increases on a side on which light energy is supplied, i.e. on a side of the peak position (a rear portion with respect to direction Y) of the first agitation profile BP 1 , and decreases in a front portion with respect to direction Y. Accordingly, in the color film forming area  23  irradiated with the laser beam B, the color film forming material flows so as to shift toward a rear portion with respect to direction Y (agitated). 
     In the meantime, the first agitation profile BP 1  is formed by the laser beam B having an intensity to sufficiently inhibit evaporation of the color film forming material and the dispersion medium, and therefore the droplet FD has the hardening of its color film forming material inhibited and its flowability maintained. 
     The laser beam B of the first agitation profile BP 1  is applied, a beam profile (drying profile) to uniformly evaporate the dispersion medium is then formed, and the laser beam B of the drying profile is applied to the droplet FD. Then, a color film (first color film  24   a ) having a structure profile (thickness distribution) in which the thickness is substantially uniform on a side on which the color film material shifts, i.e. in a rear portion with respect to direction Y of the color film forming area  23 , and the thickness gradually decreases from the central position of the color film forming area  23  toward a front edge with respect to direction Y as shown with the solid line of  FIG. 8C  is formed. 
     The laser head LH forms a beam profile (second agitation profile BP 2 ) having a sharp peak of radiation intensity only in a front portion with respect to direction Y of the color film forming area  23  as shown with the dashed line in  FIG. 8A , based on the beam profile forming information BPI (second agitation profile forming information BPI 2 ). That is, the laser head LH forms a beam profile with the first agitation profile BP 1  mirror-inversed at the central position of the color film forming area  23 , based on the second agitation profile forming information BPI 2 . 
     The second agitation profile BP 2  has the maximum value of its radiation intensity set to an intensity for sufficiently inhibiting evaporation of the color film forming material and the dispersion medium and inducing thermal convection of the color film forming material and the dispersion medium in the corresponding droplet FD. The second agitation profile BP 2  is formed with a substantially same intensity over the entire width of the color film forming area  23  in direction X along a direction vertical to the sheet face of  FIG. 8A , i.e. direction X. 
     The laser beam B of the second agitation profile BP 2  is applied, a beam profile (drying profile) to uniformly evaporate the dispersion medium is then formed, and the laser beam B of the drying profile is applied to the droplet FD. Then, a color film (second color film  24   b ) having a thickness distribution in which the thickness is substantially uniform in a front portion with respect to direction Y of the color film forming area  23  and the thickness gradually decreases from the central position of the color film forming area  23  toward rear edge with respect to direction Y as shown with the dashed line of  FIG. 5C  is formed. 
     In this embodiment, the planarization sequence is formed based on the aforementioned three types of beam profiles (first agitation profile BP 1 , second agitation profile BP 2 , and drying profile). That is, the planarization sequence forms the first agitation profile BP 1  for a predetermined time (first agitation time), subsequently forms the second agitation profile BP 2  for a predetermined time (second agitation time), and finally forms the drying profile for a predetermined time (drying time). The total time of the first agitation time, second agitation time and drying time is set to a time shorter than the scanning cycle of the laser beam B (the scanning time=scanning width Ly 2 /transport speed Vy). 
     When the droplet FD formed on the color film forming area  23  is irradiated with the laser beam B based on the planarization sequence, the color film forming material is substantially uniformly dispersed from the rearmost end in direction Y to the foremost end in direction Y in the droplet. The color film  24  having a uniform thickness distribution is formed on the color film forming area  23 . 
     The electric configuration of the liquid droplet ejection apparatus  30  configured as described above will now be described according to  FIG. 9 . 
     In  FIG. 9 , a controller  50  comprises a control section  51  consisting of a CPU or the like, a RAM  52  consisting of a DRAM and an SRAM, and a ROM  53  storing various kinds of control programs and various kinds of data. The controller  50  comprises a drive signal generating circuit  54  generating piezoelectric element drive signal COM 1  and the phase modulating portion drive signal COM 3 , a power supply circuit  55  generating the laser drive signal COM 2 , and an oscillating circuit  56  or the like generating a clock signal CLK for synchronizing various kinds of signals. The control section  51 , the RAM  52 , the ROM  53 , the drive signal generating circuit  54 , the power supply circuit  55  and the oscillating circuit  56  are connected to the controller  50  via a bus (not shown). 
     Specifically, the ROM  53  stores a plurality of pieces of beam profile forming information BPI (e.g. first and second agitation profile forming information BPI 1  and BPI 2 ) and a plurality of beam profile sequences BPS (e.g. planarization sequence in this embodiment). 
     Each piece of beam profile forming information BPI is information for driving and controlling the phase modulating portion  48  for forming a corresponding beam profile, and is information for generating the phase modulating portion drive signal COM 3 . 
     Each beam profile sequence BPS is information for continuously forming different beam profiles based on the different beam profile forming information BPI, and is information for generating the phase modulating portion drive signal COM 3 . 
     Each beam profile sequence BPS has data (thickness distribution data Ib) about the thickness distribution of the color film  24  formed by the laser beam of a corresponding sequence. Each beam profile sequence BPS has information (profile identification information) making it possible to identify a plurality of pieces of beam profile forming information BPI that are used in the sequences. In each beam profile sequence BPS, data (forming time data) about the time for forming each beam profile (time for driving and controlling the phase modulating portion  48 ) and data (forming order data) about the order for forming each beam profile are set in correspondence with the profile identification information. 
     For example, the planarization sequence in this embodiment has numerical data in which unevenness in thickness of the color film  24  is equal to or less than a predetermined numerical value as thickness distribution data Ib. The planarization sequence has profile identification information corresponding to the first agitation profile forming information BPI 1 , the second agitation profile forming information BPI 2  and the drying profile. In the planarization sequence, forming time data for the first agitation time, the second agitation time and the drying time is set in correspondence with identification information for the first agitation profile forming information BPI 1 , the second agitation profile forming information BPI 2  and the drying profile. In the planarization sequence, forming order data for forming beam profiles in the order of the first agitation profile BP 1 , the second agitation profile BP 2  and the drying profile is set in correspondence with the first agitation profile forming information BPI 1 , the second agitation profile forming information BPI 2  and the drying profile. 
     An input device  61  is connected to the controller  50 . 
     The input device  61  has operation switches such as a start switch and a stop switch, and outputs operation signals by operations of the switches to the controller  50  (control section  51 ). The input device  61  outputs information for forming a droplet FD corresponding to the color film  24  to a controller  50  as dot formation data Ia. The input device  61  outputs information about a thickness distribution of the color film  24  to the controller  50  as thickness distribution data Ib. 
     The controller  50  moves the substrate stage  33  to perform an operation of conveying the color filter substrate and drives each piezoelectric element PZ of the ejection head FH to perform a liquid droplet ejection operation in accordance with dot formation data Ia and thickness distribution data Ib from the input device  61  and a control program (e.g. color filter production program) stored in the ROM  53  or the like. The controller  50  performs an agitation and drying operation of driving the laser head LH to agitate and dry the droplet FD. 
     Specifically, the control section  51  subjects the dot formation data Ia from the input device  61  to predetermined development processing, generates bitmap data BMD indicating whether the droplet FD is ejected at a position on a two-dimensional dot formation plane (color film forming surface  21   a ), and stores the generated bitmap data BMD in the RAM. The bitmap data BMD specifies ON or OFF of the piezoelectric element PZ (whether the droplet FD is ejected or not) according to the value of each bit (0 or 1). 
     The control section  51  subjects the dot formation data Ia from the input device  61  to development processing different from the development processing for the bitmap data BMD, generates waveform data of the piezoelectric element drive signal COM 1  appropriate to a drawing condition and outputs the generated waveform data to the drive signal generating circuit  54 . The drive signal generating circuit  54  stores the waveform data from the control section  51  in a waveform memory (not shown). The drive signal generating circuit  54  subjects the stored waveform data to digital/analog conversion to amplify a waveform signal of an analog signal, and thereby generates the corresponding piezoelectric element drive signal COM 1 . 
     The control section  51  synchronizes the bitmap data BMD with a clock signal CLK generated by the oscillating circuit  56 , and sequentially serially transfers data for each scan (one forward movement or backward movement of the substrate stage  33 ) as ejection control data SI to an ejection head drive circuit  67  (shift register  67   a ) described later. The control section  51  outputs a latch signal LAT for latching the serially transferred ejection control data SI for one scan. 
     The control section  51  synchronizes the piezoelectric element drive signal COM 1  with the clock signal CLK generated by the oscillating circuit  56  and outputs the piezoelectric element drive signal COM 1  to the ejection head drive circuit  67  (switch circuit  67   d ) described later. The control section  51  is configured to output to the ejection head drive circuit  67  (switch circuit  67   d ) a selection signal SEL for selecting the piezoelectric element drive signal COM 1  and apply to each piezoelectric element PZ the piezoelectric element drive signal COM 1  corresponding to the selection signal SEL. 
     The control section  51  searches thickness distribution data Ib of the beam profile sequence BPS stored in the ROM  53  referring to thickness distribution data Ib from the input device  61 , and determines the beams profile sequence BPS of the thickness distribution data Ib corresponding to the thickness distribution data Ib from the input device  61 . The control section  51  extracts beam profile forming information BPI corresponding to each piece of profile identification information from the ROM  53  based on profile identification information of the determined beam profile sequence BPS. The control section  51  generates the corresponding phase modulating portion drive signal COM 3  based on each piece of beam profile forming information BPI extracted, and forming time data and forming order data of the determined beam profile sequence BPS. 
     The control section  51  synchronizes the generated phase modulating portion drive signal COM 3  with the clock signal CLK generated by the oscillating circuit  56  and outputs the phase modulating portion drive signal COM 3  to a laser head drive circuit  68  (switch circuit  68   b ) described later. 
     The control section  51  outputs the laser drive signal COM 2  to the laser head drive circuit  68  (switch circuit  68   b ). 
     As shown in  FIG. 9 , an x-axis motor drive circuit  62  is connected to the controller  50 , and an x-axis motor drive and control signal is output to the x-axis motor drive circuit  62 . The x-axis motor drive circuit  62  rotates an x-axis motor MX in a forward or reverse direction, thereby causing the carriage  39  to move forward and backward, in response to the x-axis motor drive and control signal from controller  50 . For example, when the x-axis motor MX is rotated in the forward direction, the carriage  39  moves in direction X, and when the x-axis motor MX is rotated in the reverse direction, the carriage  39  moves in a direction opposite to direction X. 
     A y-axis motor drive circuit  63  is connected to the controller  50 , and a y-axis motor drive and control signal is output to the y-axis motor drive circuit  63 . The y-axis motor drive circuit  63  rotates a y-axis motor MY in a forward or reverse direction, thereby causing the substrate stage  33  to move forward and backward, in response to the y-axis motor drive and control signal from the controller  50 . For example, when the y-axis motor MY is rotated in the forward direction, the substrate stage  33  moves in direction Y, and when the y-axis motor is reversely moved, the substrate stage  33  moves in a direction opposite to direction Y. 
     A substrate detector  64  is connected to the controller  50 . The substrate detector  64  detects an end edge of the color filter substrate  10 , and the detection result is used when calculating a position of the color filter  10  (color film forming area  23 ) passing immediately below the ejection head FH (nozzle hole N) by the controller  50 . 
     An x-axis motor rotation detector  65  is connected to the controller  50 , and a detection signal from the x-axis motor rotation detector  65  is input to the controller  50 . The controller  50  detects the direction and amount of rotation of the x-axis motor MX based on the detection signal from the x-axis motor rotation detector  65 , and calculates the amount and direction of movement of the carriage  39  in direction X. 
     A y-axis motor rotation detector  66  is connected to the controller  50 , and a detection signal from the y-axis motor rotation detector  66  is input to the controller  50 . The controller  50  detects the direction and amount of rotation of the y-axis motor MY based on the detection signal from the y-axis motor rotation detector  66 , and calculates the direction and amount of movement of the substrate stage  33  (color film forming area  23 ) in direction Y. 
     An ejection head drive circuit  67  and a laser head drive circuit  68  are connected to the controller  50 . 
     The ejection head drive circuit  67  comprises a shift register  67   a , a latch circuit  67   b , a level shifter  67   c  and a switch circuit  67   d . The shift register  67   a  subjects ejection control data SI from the controller  50  synchronized with the clock signal CLK to serial/parallel conversion associated with each piezoelectric element PZ. The latch circuit  67   b  latches the ejection control data SI subjected to parallel conversion by the shift register  67   a  in synchronization with the latch signal LAT from the controller  50 , and sequentially outputs the latched ejection control data SI to the level shifter  67   c  and a delay circuit  68   a  of the laser head drive circuit  68  described later in a predetermined cycle synchronized with the clock signal CLK. The level shifter  67   c  boosts the ejection control data SI latched by the latch circuit  67   b  to a voltage to drive the switch circuit  67   d  to generate a first switching signal GS 1  corresponding to each piezoelectric element PZ. 
     The switch circuit  67   d  comprises switch elements (not shown) corresponding to the piezoelectric elements PZ. The piezoelectric element drive signal COM 1  corresponding to the selection signal SEL is input to the input side of each switch element, and the corresponding piezoelectric element PZ is connected to the output side. The corresponding first switching signal GS 1  from the level shifter  67   c  is input to each switch element of the switch circuit  67   d , and whether the piezoelectric drive signal COM 1  is supplied to the corresponding piezoelectric element PZ is determined according to each first switching signal. 
     That is, the liquid droplet ejection apparatus  30  of this embodiment applies the piezoelectric element drive signal COM 1  generated by the drive signal generating circuit  54  to each corresponding piezoelectric element PZ and controls the application of the piezoelectric element drive signal COM 1  by the ejection control data SI (first switching signal GS 1 ) from the controller  50 . When the piezoelectric element drive signal COM 1  is applied to the piezoelectric element PZ corresponding to the closed switch element based on the ejection control data SI, microdroplets Fb (droplets FD) are ejected from the nozzle hole N corresponding to the piezoelectric element PZ. 
       FIG. 10  is a timing chart showing pulse waveforms of the aforementioned latch signal and first switching signal GS 1  and a second switching signal GS 2  described later, and rotation angles θp of the polygon motor MP. 
     As shown in  FIG. 10 , in response to a falling edge of the latch signal LAT input to the ejection head drive circuit  67 , the first switching signal GS 1  is generated based on the latched ejection control data SI, and in response to a rising edge of the first switching signal GS 1 , the piezoelectric element drive signal COM 1  is supplied to the corresponding piezoelectric element PZ. By expansion and contraction motion of the piezoelectric element PZ based on the piezoelectric element drive signal COM 1 , microdroplets Fb (droplets FD) are ejected from the corresponding nozzle hole N. In response to a falling edge of the first switching signal GS 1 , the operation of ejecting droplets FD by drive of the piezoelectric element PZ is ended. 
     The laser head drive circuit  68  comprises a delay circuit  68   a , a switch circuit  68   b  and a polygon motor drive circuit  68   c.    
     The delay circuit  68   a  generates a pulse signal (second switching signal GS 2 ) of a predetermined time range in which the ejection control data SI latched by the latch circuit  67   b  is delayed by predetermined time (the standby time T), and outputs the generated second switching signal GS 2  to the switch circuit  68   b  (laser switch circuit and modulating portion switch circuit). 
     The switch circuit  68   b  comprises a laser switch circuit and a modulating portion switch circuit. The laser switch circuit comprises switch elements (not shown) corresponding to the semiconductor lasers L. The laser drive signal COM 2  generated by the power supply circuit  55  is input to the input side of each switch element, and each corresponding semiconductor laser L is connected to the output side. When the second switching signal GS 2  from the delay circuit  68   a  is input to each switch element of the laser switch circuit, each switch element supplies the laser drive signal COM 2  to the corresponding semiconductor laser L. 
     That is, the liquid droplet ejection apparatus  30  of this embodiment applies the laser drive signal COM 2  generated by the power supply circuit  55  equally to each corresponding semiconductor laser L, and controls the application of the laser drive signal COM 2  by the ejection control data SI (second switching signal GS 2 ) from the controller  50  (ejection head drive circuit  67 ). When the laser drive signal COM 2  is supplied to the semiconductor laser L corresponding to the closed switch element based on the ejection control data SI, the laser beam B is emitted from the corresponding semiconductor laser L. 
     The modulating portion switch circuit comprises switch elements (not shown) corresponding to the phase modulating portions  48 . The phase modulating portion drive signal COM 3  generated by the control section  51  is input to the input side of each switch element, and each corresponding phase modulating portion  48  is connected to the output side. When the second switching signal GS 2  from the delay circuit  68   a  is input to each switch element of the modulating portion switch circuit, each switch element supplies the phase modulating portion drive signal COM 3  to the corresponding phase modulating portion  48 . 
     That is, the liquid droplet ejection apparatus  30  of this embodiment applies the phase modulating portion drive signal COM 3  generated by the controller  50  (drive signal generating circuit  54 ) equally to each corresponding phase modulating portion  48 , and controls the application of the phase modulating portion drive signal COM 3  by the ejection control data SI (second switching signal GS 2 ) from the controller  50  (ejection head drive circuit  67 ). When the phase modulating portion drive signal COM 3  is supplied to the phase modulating portion  48  corresponding to the closed switch element based on the ejection control data SI, the corresponding phase modulating portion  48  subjects the laser beam B to phase modulation based on the beam profile sequence BPS. 
     The polygon motor drive circuit  68   c  receives a polygon motor drive start signal SSP from the controller  50  to generate a polygon motor drive control signal SPM, and outputs the generated signal SPM to the polygon motor MP to rotate the polygon motor MP. The controller  50  outputs the polygon motor drive start signal SSP to start the rotation of the polygon motor MP, based on a detection signal from the substrate detector  64 . Specifically, when the front end of the first-line color film forming area  23  with respect to direction Y is situated at the radiation start position Pe 1 , the controller  50  outputs the polygon motor drive start signal SSP in predetermined timing in which the rotation angle θp of the polygon mirror  49  is zero degrees, to the laser head drive circuit  68 . 
     As shown in  FIG. 10 , when the standby time T elapses after a rising edge of the first switching signal GS 1  (ejection operation is started), the second switching signal GS 2  is generated by the delay circuit  68   a , and the second switching signal GS 2  is supplied to the switch circuit  68   b  (laser switch circuit and modulating portion switch circuit). In response to a rise of the second switching signal GS 2 , the laser drive signal COM 2  is supplied to the corresponding semiconductor laser L, and the laser beam B is emitted from the corresponding semiconductor laser L. At the same time, in response to a rising edge of the second switching signal GS 2 , the phase modulating portion drive signal COM 3  is supplied to the corresponding phase modulating portion  48 , and the corresponding phase modulating portion  48  starts subjecting the laser beam B to phase modulation based on the beam profile sequence BPS determined by the control section  51 . That is, the first agitation profile BP 1 , the second agitation profile BP 2  and the drying profile are sequentially formed within the scanning time. 
     As shown in  FIG. 10 , in response to a rising edge of the second switching signal GS 2 , the rotation angle θp of the rotating polygon mirror  49  is zero degrees. Therefore, the laser beam B of the first agitation profile BP 1  is applied to the droplet FD situated at the radiation start position Pe 1 . When the droplet FD is continuously transferred into a scanning zone Ls, the laser beams B of the first agitation profile BP 1  and the second agitation profile BP 2  and the drying profile with the radiating position made stationary relative to the droplet FD on the corresponding color film forming area  23  by the scanning of the laser beams B are sequentially applied to the droplet FD within the scanning time (=scanning width Ly 2 /transport speed Vy). 
     In response to a falling edge of the second switching signal GS 2 , emission of the laser beam B from the semiconductor laser L is stopped to end the operation of processing the first-line droplet FD. 
     Subsequently, when the standby time T elapses after the ejection operation in the second line is started, the first-line color film forming area  23  leaves the scanning zone Ls and the front end of the following second-line color film forming area  23  in direction Y enters the scanning zone Ls. The second switching signal GS 2  is generated again in the laser head drive circuit  68  (delay circuit  68   a ), and in response to a rising edge of the second switching signal GS 2 , the laser beams B of the first agitation profile BP 1  are started to be applied at a time from the corresponding radiation ports  47 . 
     At this time, the rotation angle θp of the rotating polygon mirror  49  is ten degrees as shown in  FIG. 10 . Thus, the laser beam B of the first agitation profile BP 1  reflected and deflected at the reflection surface M is applied to the second-line droplet FD situated at the radiation start position Pe 1 . 
     Subsequently, similarly, each time the following color film forming area  23  passes through the scanning zone Ls with the droplet FD deposited thereon, the laser beams B of the first agitation profile BP 1 , the second agitation profile BP 2  and the drying profile with the radiating position made stationary relative to the droplet FD are sequentially applied to the corresponding droplets FD. 
     A method for manufacturing the color filter substrate  10  (color film  24 ) using the liquid droplet ejection apparatus  30  will now be described. 
     First, the color filter substrate  10  is fixedly placed on the substrate stage  33  situated at a proceed position as shown in  FIG. 4 . At this time, the front edge of the color filter substrate  10  with respect to direction Y is situated rearward of the guide member  36  with respect to direction Y. The carriage  39  (ejection head FH) is set at a position where the corresponding color film forming area  23  passes immediately below each nozzle hole N when the color filter substrate  10  moves in direction Y. 
     In this state, the controller  50  drives and controls the y axis motor MY to convey the color filter substrate  10  in direction Y at a transport speed Vy via the substrate stage  33 . When the substrate detector  64  detects the front edge of the color filter substrate  10  with respect to direction Y, the controller  50  generated the polygon motor drive start signal SSP in the aforementioned predetermined timing. In response to a rising edge of the polygon motor drive start signal SSP, the polygon motor drive and control signal SPM is generated by the polygon motor drive circuit  68   c  and the polygon mirror  49  is rotated in the direction R. 
     Consequently, the rotation angle θp of the polygon mirror  49  is zero degrees when the front edge of the first-line color film forming area  23  with respect to direction Y is situated at the radiation start position Pe 1 . 
     The controller  50  determines whether the target ejecting position Pa of the first-line color film forming area  23  has reached a position immediately below the corresponding nozzle hole N based on the detection signal from the y-axis motor rotation detector  66 . 
     In the meantime, the controller  50  searches thickness distribution data Ib of the beam profile sequence BPS stored in the ROM  53  in accordance with a color filter production program. The controller  50  determines beam profile sequences BPS (planarization sequences) of the thickness distribution data Ib (data showing that the uniformity of the thickness of the color film  24  is sufficiently high) from the input device  61  and corresponding thickness distribution data Ib. The controller  50  reads each piece of beam profile forming information BPI (first agitation profile forming information BPI 1 , second agitation profile forming information BPI 2  and the drying profile) corresponding to each piece of profile identification information based on profile identification information of the determined planarization sequence. Subsequently, the controller  50  generates the corresponding phase modulating drive signal COM 3  based on forming time data (first agitation time, second agitation time, and drying time) and forming order data of the planarization sequence. The controller  50  outputs the generated phase modulating portion drive signal COM 3  to the laser head drive circuit  86 . 
     In the meantime, the controller  50  outputs the laser drive signal COM 2  generated in the power supply circuit  55  to the laser head drive circuit  68 . 
     In the meantime, the controller  50  to the ejection head drive circuit  67  the ejection control head SI based on the bitmap data BMD stored in the RAM  52  and the piezoelectric element drive signal COM 1  generated in the drive signal generating circuit  54  in accordance with the color filter production program. 
     The controller  50  waits for timing for outputting the latch signal LAT to the ejection head drive circuit  67 . 
     When the target ejecting position Pa of the first-line color film forming area  23  reaches a position immediately below the corresponding nozzle hole N, the controller  50  outputs the latch signal LAT to the ejection head drive circuit  67 . When receiving the latch signal LAT from the controller  50 , the ejection head drive circuit  67  generates the first switching signal GS 1  based on the ejection control data SI, and outputs the first switching signal GS 1  to the switch circuit  67   d . The piezoelectric element drive signal COM 1  corresponding to the selection signal SEL is supplied to the piezoelectric element PZ corresponding to the closed switch element, and microdroplets Fb corresponding to the piezoelectric element drive signal COM 1  are ejected at a time from corresponding nozzle holes N. The ejected microdroplets Fb are deposited into the corresponding first-line color film forming area  23  at a time to form the droplet FD. 
     When the latch signal LAT is input to the ejection head drive circuit  67 , the laser head drive circuit  68  (delay circuit  68   a ) receives the ejection control data SI from the latch circuit  67   b  to start generation of the second switching signal GS 2 . 
     The laser head drive circuit  68  waits for timing for outputting the second switching signal GS 2  to the switch circuit  68   b  (laser switch circuit and modulating portion switch circuit). 
     When the standby time T elapses after the piezoelectric element PZ starts the ejection operation, i.e. the ejection head drive circuit  67  outputs the first switching signal GS 1 , the droplet FD on first-line color film forming area  23  starts entering the scanning zone Ls, and the laser head drive circuit  68  outputs the second switching signal GS 2  to the laser switch circuit and the modulating portion switch circuit. 
     The laser switch circuit supplies the common laser drive signal COM 2  to the corresponding semiconductor laser L and emits the laser beams B at a time from the corresponding laser L. At the same time, the modulating portion switch circuit outputs the common phase modulating portion drive signal COM 3  to the corresponding phase modulation portion  48 , and drives and controls the phase modulating portion  48  based on the phase modulating portion drive signal COM 3 . 
     Consequently, the laser beams B of the first agitation profile BP 1 , the second agitation profile BP 2  and the drying profile with the radiating position made stationary relative to the droplet FD entering the scanning zone Ls are sequentially and successively applied to the droplet FD. In response to a falling edge of the second switching signal GS 2 , emission of the laser beam B from the semiconductor laser L is stopped, and the agitation and drying operation for the first-line droplet FD is ended. 
     Consequently, the color film  24  having a uniform thickness is formed in the corresponding color film forming area  23 . 
     Subsequently, similarly, each time the following color film forming area  23  in each line passes through the scanning zone Ls with the droplet FD deposited thereon, the laser beams B of the first agitation profile BP 1 , the second agitation profile BP 2  and the drying profile with the radiating position made stationary relative to the corresponding droplet FD are sequentially and successively applied to the droplet FD to form the color film  24  having a uniform thickness. 
     When the color films  24  are formed on all the color film forming areas  23 , the controller  50  controls the y-axis motor MY to place the substrate stage  33  (color filter substrate  10 ) at a proceed position. 
     Advantages of this embodiment configured in a manner described above will now be described below. 
     (1) According to the aforementioned embodiment, the first and second agitation profiles BP 1  and BP 2  are formed with a maximum value of radiation intensity for sufficiently inhibiting evaporation of the color film forming material and the dispersion medium and inducing thermal convection of the color film forming material and the dispersion medium in the corresponding droplet FD. As a result, the color film forming material in the droplet FD can be made to flow to regions corresponding to peak positions of the first and second agitation profiles BP 1  and BP 2 , and the color films  24  can be controlled to have thickness distributions corresponding to the first and second agitation profiles BP 1  and BP 2 . 
     (2) According to the aforementioned embodiment, the first agitation profile BP 1  having a sharp peak only in a rear portion of the color film forming area  23  with respec to direction Y and the second agitation profile BP 2  having a sharp peak only in a front portion of the color film forming area  23  with respect to direction Y are successively formed. The laser beam B of the first agitation profile BP 1  and the laser beam B of the second agitation profile BP 2  are successively applied. As a result, the color film forming material in the droplet FD can be made to flow (agitated) to uniformly disperse the color film forming material in the color film forming area  23 . Thus, the color film  24  having a uniform thickness can be formed in the color film forming area  23 . 
     (3) According to the aforementioned embodiment, the beam profile sequence BPS comprises thickness distribution data, and the controller  50  determines the beam profile sequence BPS (planarization sequence) corresponding to a desired uniform thickness distribution. As a result, a beam profile corresponding to a desired thickness distribution can reliably be formed, and the thickness of the color film  24  can be made uniform more reliably. 
     (4) According to the aforementioned embodiment, the laser beams B of the first agitation profile BP 1  and the second agitation profile BP 2  with the radiating position made stationary relative to the droplet FD are applied to the droplet. As a result, the switch can be made between the first agitation profile BP 1  and the second agitation profile BP 2  in desired timing without being restricted by the transport direction of the droplet FD, and the like. 
     The aforementioned embodiment may be modified as follows. 
     In the embodiment described above, energy is embodied in the form of laser beams B, but the present invention is not limited thereto, and for example, electron beams and ion beams may be used, and any type of energy causing the color film forming material (structure forming material) to flow may be used. 
     In the embodiment described above, the structure profile is embodied in the form of a thickness distribution of the color film  24 , but the present invention is not limited thereto, and for example, the color film  24  may be formed with a plurality of constituent materials, and the structure profile may be embodied in the form of a concentration distribution of each constituent material. Alternatively, the structure profile may be embodied in the form of a shape distribution of the color film  24   
     In the embodiment described above, the energy profile is embodied in the form of a distribution of the radiation intensity. The present invention is not limited thereto, and the energy profile may be a distribution of the shape of beam spots or a distribution of the wavelength. 
     In the embodiment described above, the distribution of the color film forming material in the droplet FD is made uniform by the first agitation profile BP 1  having a sharp peak of the radiation intensity only in a rear portion with respect to direction Y of the color film forming area  23  and the second agitation profile BP 2  having a sharp peak of the radiation intensity only in a front portion with respect to direction Y. 
     The present invention is not limited thereto, and for example, a third agitation profile BP 3  having a pair of split sharp peaks in front and rear portions with respect to direction Y of the color film forming area  23  may be formed as shown with the solid line in  FIG. 11A , so that the color film forming material in the droplet FD is first split into a front portion and a rear portion with respect to direction Y as shown with the solid lines in  FIGS. 11B and 11C . Then, a fourth agitation profile BP 4  having a sharp peak in a central portion of the color film forming area  23  with respect to direction Y may be formed as shown with the dashed line in  FIG. 11A , so that the color film forming material in the droplet FD flows toward the central portion of the color film forming area  23  as shown with the dashed line in  FIG. 11C . 
     In the embodiment described above, the beam profile sequence is formed as a planarization sequence for making the thickness of the color film  24  uniform. The present invention is not limited thereto, and the beam profile sequence may be a sequence for making the color film  24  have a thickness increased at one end of the color film forming area  23 , and may be any sequence corresponding to a desired structure profile. 
     In the embodiment described above, the beam profile sequence is formed according to the beam profile forming information BPI, the time for forming each beam profile, and the order for forming each beam profile. The present invention is not limited thereto, and for example, a configuration in which scanning information for scanning each beam profile in a predetermined direction is set in the beam profile sequence, and the beam profile is scanned in a desired direction in a predetermined cycle may be employed. According to this configuration, the beam profile can be controlled with higher accuracy and a controllable range of the structure profile can further be expanded. 
     In the embodiment described above, the energy profile information is embodied in the form of a beam profile sequence. The present invention is not limited thereto, and for example, the energy profile information may be embodied in the form of beam profile forming information BPI (first agitation profile forming information BPI 1  and second agitation profile forming information BPI 2 ), and a structure such as a color film is controlled to be a desired structure profile by a single beam profile. 
     In the embodiment described above, an energy profile information determining section is embodied in the form of the control section  51 , and thickness distribution data Ib possessed by each beam profile sequence BPS is matched with desired thickness distribution data Ib to determine the beam profile sequence BPS. 
     The present invention is not limited thereto, and for example, a configuration in which a predetermined operation for generating the beam profile sequence BPS (beam profile information) from thickness distribution data Ib (structure profile) beforehand based on tests and the like, and the control section  51  carries out the predetermined operation for desired thickness distribution data Ib (structure profile) to generate the beam profile sequence BPS (energy profile information) may be employed. 
     According to this modified embodiment, energy file information corresponding to a desired structure profile can reliably be acquired. 
     In the embodiment described above, the position of irradiation of the laser beam B is made stationary relative to the droplet FD by the energy beam scanning section. The present invention is not limited thereto, and for example, a configuration in which the position of irradiation of the laser beam B is fixed, and each droplet FD is transferred to the position of irradiation of the laser beam B and irradiated with the laser beam B of the corresponding beam profile in a state of being stopped at the radiating position may be employed. According to this configuration, the laser beam B can be applied for a long time without being restricted by the scanning time. 
     In the embodiment described above, the liquid droplet ejection portion is embodied in the form of the ejection head FH, but the present invention is not limited thereto, and for example, a configuration in which a liquid is ejected by a liquid droplet ejection portion such as a dispenser may be employed. 
     In the embodiment described above, the energy beam scanning section is embodied in the form of an optical system having the polygon mirror  49 . The present invention is not limited thereto, and the energy beam scanning section may be formed with a galvanometer mirror or the like, and any scanning section for making the position of irradiation of the laser beam B stationary relative to the droplet FD. 
     In the embodiment described above, an energy outputting section is embodied in the form of the semiconductor laser L, but the present invention is not limited thereto, and the energy outputting section may be a carbon gas laser, a YAG laser, a LED or electron beam laser, or the like. 
     In the embodiment described above, a beam profile is formed using the electrically or mechanically driven phase modulating portion  48 . The present invention is not limited thereto, and the beam profile (energy profile) may be formed using, for example, a diffractive element, a mask, a diverging element or the like, and any means capable of forming a desired energy profile in the color film forming area  23  may be used. 
     In the embodiment described above, the color film forming area  23  is embodied in the form of substantially a square, but it is not limited to this shape, and the color film forming area  23  may be, for example, elliptical or polygonal. 
     In the embodiment described above, semiconductor lasers L is provided in a number equivalent to the number of nozzle holes N, but the present invention is not limited thereto, and an optical system in which a single laser beam B emitted from a laser beam source is split by a diverging element such as a diffractive element may be used. 
     In the embodiment described above, the liquid droplet ejection apparatus  30  is used for forming the color films  24  on the color filter substrate  10 . However, for example, an insulating film or a metal wiring pattern may be formed by the droplets FD, which are ejected by the liquid droplet ejection apparatus  30 . In this case, controllability of the structure profile of the insulating film or the metal wiring pattern can be improved as in the embodiment described above. 
     In the embodiment described above, the electro-optic device is embodied as the liquid crystal display  1 . The multiple color films  24  are formed in the liquid crystal display  1  in accordance with a certain pattern. However, the electro-optic device formed according to the present invention may be an electroluminescence display including light emission elements that are provided in accordance with a certain pattern. In this case, the droplet FD contains material for forming the light emission elements. The droplet FD is ejected onto a light emission element forming area, thus providing the corresponding light emission element. In this configuration, controllability of the structure profile of the light emission element can be improved. 
     In the embodiment described above, the electro-optic device is embodied as the liquid crystal display  1 , which includes the multiple color films  24  that are formed in accordance with a certain pattern. However, the electro-optic device formed according to the present invention may be a display having a field effect type device (an FED or an SED), in which an insulating film or a metal wiring is provided in accordance with a certain pattern. The field effect type device has a flat electron emission element and emits light from a fluorescent substance using electrons emitted by the electron emission element.