JP2005212291A - Optical head - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical head which can form images of a good image quality even when an emission quantity of light is uneven among light emitting elements. <P>SOLUTION: There are set a light emitting element group with a plurality of light emitting elements arranged in a predetermined direction, a plurality of light emission data memories set corresponding to the plurality of light emitting elements for storing light emission data which show light emission times of the corresponding light emitting elements, a plurality of correction data memories set corresponding to the plurality of light emitting elements for storing correction data to correct the light emission times of the corresponding light emitting elements, a light emission data correcting part for correcting the light emission data corresponding to the correction data on the basis of the correction data, and an element driving circuit for making the light emitting elements emit light on the basis of the corrected light emission data. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an optical head for forming a latent image on a photoconductor in an electrophotographic printer or copying machine.

  In an image forming apparatus such as a printer or a copying machine, an optical head that irradiates a predetermined pattern of exposure light at high speed is used to form an electrostatic latent image on a previously charged photoconductor.

  Japanese Patent Application Laid-Open No. 61-182966 discloses that a plurality of light emitting elements are arranged in the sub-scanning direction and recorded at the same position of the photosensitive member a plurality of times, so that even if a light emitting element having a low light emission output is used, one light emission time is extended. An image forming apparatus is disclosed that realizes high-speed printing without being changed.

  This image forming apparatus has storage means for storing m × n image data, (A) one column of m image data is input to the storage means, and (B) an image stored in the storage means. By repeating the steps of turning on the recording array head according to the data, recording the electrostatic latent image on the photosensitive drum, and shifting the image data for one column in the storage means to the next column n times, Multiple exposure is realized.

JP 61-182966 A

  However, in the image forming apparatus disclosed in Japanese Patent Laid-Open No. 61-182966, there is a problem in that an image with high image quality cannot be formed because the light emission amount varies between light emitting elements arranged in the main scanning direction and the sub scanning direction. It was happening.

  Accordingly, it is an object of the present invention to provide an optical head that solves the above-described problems and forms a latent image on a photoconductor at high speed.

  In order to solve the above-described problems, an optical head according to the present invention is provided corresponding to a plurality of light emitting elements, each having a plurality of light emitting elements arranged in a predetermined direction, and a light emission time of the corresponding light emitting elements. A plurality of light emission data memories for storing light emission data indicating a plurality of light emission data, a plurality of correction data memories provided corresponding to the plurality of light emission elements and storing correction data for correcting the light emission time of the corresponding light emission elements, and correction data A light emission data correction unit that corrects light emission data corresponding to the correction data and an element drive circuit that causes the light emitting element to emit light based on the corrected light emission data. The light emitting element is preferably an organic EL element.

  In the above configuration, a memory for storing correction data for correcting the light emission amount of the light emitting element is provided for each light emitting element, and the light emission amount is corrected for each light emitting element. Therefore, even if there is a variation in the light emission amount among a plurality of light emitting elements, the light emission amount of each light emitting element can be corrected. For example, the light emission amount of the optical head can be made uniform. The light emission amount can be controlled to a desired value. Further, when the optical head has a plurality of light emitting element modules provided with a plurality of light emitting elements, correction data is set so that the light emission amount between the light emitting element modules is uniform, and light emission of each light emitting element is performed. The amount may be corrected. The plurality of light emission data memories and the correction data memory may be memories constituting a shift register.

  In the optical head, the plurality of correction data memories store the correction data of the light emitting elements corresponding to the respective correction data memories by sequentially shifting the correction data to the plurality of correction data memories. When the plurality of correction data memories store the correction data, the light emission data is sequentially shifted to the plurality of light emission data memories to store the light emission data of the light emitting elements corresponding to the respective light emission data memories. The drive circuit preferably causes the plurality of light emitting elements to emit light when the plurality of correction data memories shift the plurality of light emission data and store them in the plurality of light emission data memories.

  In the above configuration, when a plurality of correction data memories store necessary correction data, the plurality of light emission data memories store the light emission data. Further, while the element driving circuit is causing the plurality of light emitting elements to emit light based on the light emission data stored in the plurality of light emission data memories, the next light emission data is shifted and stored in the plurality of light emission data memories. Become. In this case, necessary correction data is already stored in the correction data memory, and the correction data memory does not need to store or shift the correction data further. An optical head can be provided.

  The optical head includes a control unit that generates a plurality of bit data including a plurality of bits as light emission data or correction data, and a plurality of shift registers that are provided corresponding to the plurality of light emitting elements and sequentially shift the plurality of bit data. The correction data memory stores the bit data as correction data when a predetermined bit in the bit data stored in the corresponding shift register indicates a predetermined value, and the light emission data memory When a predetermined bit in the bit data stored in the shift register indicates another value, it is preferable to store the bit data as light emission data. Here, the light emission data correction unit preferably includes an addition unit that corrects the light emission data by adding the correction data to the light emission data. Further, the light emission data memory and the correction data memory may be memories constituting the shift register.

  In the above configuration, the light emission data memory and the correction data memory determine whether the bit data is light emission data or correction data based on the bit value of the bit data. Therefore, since the shift register and / or the light emission data memory and the correction data memory can shift the light emission data and the correction data at a high speed and store them at a high speed, the time required for the store is not lost and the high speed is achieved. An optical head to be driven can be provided.

  Hereinafter, embodiments of the invention will be described with reference to the drawings. In the following, the structure of the organic EL array exposure head and the organic EL array exposure head chip according to the present invention will be described first, and then exposure time control and multiplexing are performed using the organic EL array exposure head according to the present invention. The operation when performing exposure control will be described.

<1. Overall Configuration of Organic EL Array Exposure Head>
FIG. 1 is a plan view of an organic EL array exposure head according to the present invention as viewed from above. In the figure, symbol 1 is an organic EL array exposure head chip (hereinafter simply referred to as a head chip), and symbol 2 is an organic EL array. An exposure head (hereinafter simply referred to as an exposure head), symbol 3 is a connector for receiving data from a printer controller (not shown), symbol 34 is a substrate on which the connector 3 and the head chip 1 are mounted. A glass cloth base epoxy resin laminate can be used.

  The board 34 has a rectangular shape with the major axis in the main scanning direction, and a connector 3 for receiving data from the printer controller is mounted at one end in the main scanning direction, and the other part is mounted. A plurality of head chips 1 are mounted in the main scanning direction. Although not shown in FIG. 1, each head chip 1 is electrically connected to the connector 3.

  In FIG. 1, the plurality of head chips 1 are arranged in a zigzag pattern in two rows. That is, the head chips 1 are arranged in two rows in the sub-scanning direction, and a plurality of head chips 1 are arranged in the first row at intervals slightly narrower than the length of the head chip 1 in the main scanning direction. In the second row, a plurality of head chips 1 are arranged at the same intervals as the first row in places where the first row of head chips 1 are not arranged. This interval will be described later. In the following description, the column direction means the sub-scanning direction.

  The number of head chips 1 mounted on the substrate 34 depends on the number of organic EL light emitting sections (hereinafter simply referred to as light emitting sections) formed in the main scanning direction and the maximum image in the main scanning direction. What is necessary is just to determine based on formation length etc. For example, if one head chip 1 is formed with 192 light-emitting portions in the main scanning direction, 40 head chips 1 can be formed on an A4 size sheet when an image can be formed with a resolution of 600 dpi. May be arranged on the substrate 34 in a zigzag pattern in two rows.

  2 is a view showing one of the head chips 1 mounted on the substrate 34, FIG. 2 (a) is a plan view thereof, and FIG. 2 (b) is a cross-sectional view in the major axis direction thereof. 2, 5 is a bonding pad on the head chip 1 side, 6 is a bonding pad on the substrate 34 side, 7 is a bonding wire, 8 is a positioning pad on the head chip 1 side, and 9 is a positioning pad on the substrate 34 side. Reference numeral 19 denotes a light hole of the condensing lens assembly 28, 26 denotes a driver IC for controlling light emission of a light emitting portion formed in an organic EL array assembly (hereinafter simply referred to as an array assembly) 27, and 27 denotes an array assembly. , 28 is a condenser lens assembly, 30 is a positioning pad on the condenser lens assembly 28 side, 32 is a die bond material, and 33 is an ultraviolet (UV) curable resin adhesive. 35 shows the anisotropic conductive adhesive are denoted by the same reference numerals same as FIG. 2A and 2B, details of the central portion are omitted.

  The head chip 1 has a configuration in which a driver IC 26 is provided at the bottom, an array assembly 27 is provided immediately above the driver IC 26, and a condenser lens assembly 28 is provided immediately above the driver IC 26. It is fixed with a bond material 32. When the head chip 1 is fixed to the substrate 34, the head chip 1 and the substrate 34 are positioned by the positioning pad 8 on the head chip 1 side and the positioning pad 9 on the substrate 34 side. That is, as shown in FIG. 2A, at the position where the head chip 1 of the substrate 34 is fixed, two positioning pads 9 are formed at an interval of the length of the head chip 1 in the main scanning direction. Further, positioning pads 8 are formed at both ends of the head chip 1, specifically, the driver IC 26 in the main scanning direction so as to face the positioning pads 9 on the substrate 34 side. The positioning pads 8 on the head chip 1 side are fixed to the pads 9 so as to face each other.

  The head chip 1 has a structure in which an array assembly 27 is bonded directly above the driver IC 26 with an anisotropic conductive adhesive 35, and a condenser lens assembly 28 is bonded directly above the array assembly 27 with a UV curable resin adhesive 33. It has become. As shown in FIG. 2B, the main scanning direction length and the sub-scanning direction width of the array assembly 27 and the main scanning direction length and the sub-scanning direction width of the condenser lens assembly 28 are substantially the same. The length of the IC 26 in the main scanning direction is longer than the length of the array assembly 27 and the condenser lens assembly 28 in the main scanning direction. The width of the driver IC 26 in the sub scanning direction is substantially the same as the width of the array assembly 27 and the condenser lens assembly 28 in the sub scanning direction.

  As will be described later, the driver IC 26, the array assembly 27, and the condenser lens assembly 28 are bonded to each other by first positioning the array assembly 27 with respect to the driver IC 26 and then bonding the array assembly 27 to the driver IC 26. Then, the condenser lens assembly 28 is attached and positioned with respect to the driver IC 26 and bonded.

  A predetermined number of wire bonding pads 5 are formed at both ends of the driver IC 26 other than the portion to which the array assembly 27 is bonded, and the same number of wire bonding pads 6 as the wire bonding pads 5 are formed on the substrate 34. The wire bonding pads 5 of the driver IC 26 are electrically connected to the corresponding wire bonding pads 6 and bonding wires 7 on the substrate 34 side, respectively.

  The wire bonding pad 6 on the substrate 34 side supplies various signals to the driver IC 26 from the connector 3 shown in FIG. 1, or supplies a power supply voltage or a ground potential to the driver IC 26 from a power supply circuit (not shown). It is provided for this purpose. For the connection between the wire bonding pad 6 and the connector 3 or power supply circuit, for example, a wiring pattern (not shown) may be formed on the substrate 34 in advance.

  In FIG. 2, 20 pairs of wire bonding pads 5 and 6 are provided. However, how many wire bonding pads are provided may be appropriately determined based on the number of signals supplied to the driver IC 26 and the like.

  The condensing lens assembly 28 has light holes 19 formed in a plurality of rows. That is, a predetermined number of light holes 19 are formed in the main scanning direction, and a plurality of light holes 19 are formed in the sub scanning direction. Here, the light holes 19 are formed in one-to-one correspondence with the light emitting portions formed in the array assembly 27. That is, in FIG. 2A, it is assumed that a light emitting portion is formed immediately below each light hole 19.

  How many light holes 19 are formed in the main scanning direction, that is, how many light emitting portions are formed in the array assembly 27 in the main scanning direction may be determined according to the required resolution. In this example, as described above, 192 light holes and light-emitting portions are formed in the main scanning direction. Out of the 192 odd-numbered light holes and light emitting portions are arranged in the first row in the sub-scanning direction, and out of the 192 even-numbered light holes and light emitting portions are arranged in the second row in the sub-scanning direction. In the same manner, 192 × 4 light holes and light emitting portions are formed in one head chip 1 in a total of eight rows in a staggered manner. It should be noted that how many rows of light holes and light emitting portions are arranged in the sub-scanning direction may be determined based on the amount of light emitted from the light emitting portions, and may be arranged not in a staggered pattern but in an aligned grid pattern.

  Further, when the light emitting portions and the light holes 19 are formed in a staggered manner as shown in FIG. 2A, depending on the required resolution, one line exposure of the image to be formed can be performed only for one line of the light holes 19. You can also do this with However, from the viewpoint of resolution, one line of the image is exposed by the light emitting portions and the light holes 19 in the first and second rows, and the light emitting portions and the light holes 19 in the third and fourth rows are adjacent to each other. It is desirable to expose one line of the image by the light emitting portions and the light holes 19 arranged in a zigzag pattern in two rows, such as performing line exposure. In the case shown in FIG. 2A, according to the former, eight lines of the image can be exposed, and according to the latter, four lines of the image can be exposed.

  By the way, the interval between the head chips 1 for each column when the head chips 1 are arranged in a zigzag pattern as shown in FIG. 1 will be described with reference to FIG. In FIG. 3, 4a shows the light emitting part of the first row of one head chip 1 in the first row of FIG. 1, 4b shows the rightmost light emitting part of the head chip 1, and the head chip 1 and staggered Assuming that the first row of light emitting portions of the second row of head chips 1 is shown, the light emitting portion 4b and the light emitting portion 4c are the same as the interval between the light emitting portions in each row in the main scanning direction. Place them apart by an interval. With such an arrangement, even in the area where the head chips 1 are arranged in a staggered manner, the pixel interval in the main scanning direction is constant.

  Further, as shown in FIG. 3, the light emitting unit 4a and the light emitting unit 4c are arranged apart from each other by 16 columns of the light emitting units in the sub-scanning direction. The deviation of the 16 columns can be solved, for example, by processing the output order of the image data in an appropriate process in which print image data is generated by the printer controller and output to the exposure head 2.

  The head chips 1 are fixed to the substrate 34 in a zigzag manner in two rows so as to be arranged as described above.

  The above is the description of the overall structure of the exposure head 2, and each part will be described below. First, as described above, the substrate 34 can be made of an insulating material, for example, a glass cloth base epoxy resin laminate, and is used for positioning when fixing the head chip 1 at a predetermined location. A positioning pad 9 and a wire bonding pad 6 are formed, and a connector 3 is provided at an end thereof.

  FIG. 4A is an enlarged plan view of a part of FIG. 2 regarding the arrangement of the organic EL elements in the condenser lens array assembly 4. Symbol 19 is a light hole, and symbol 13 is a condenser lens. Immediately below the condenser lens is an organic EL light emitting section.

  Assuming that the resolution in the principal axis direction of the organic EL print head is 600 dpi, the pitch A of the light emitting parts is 1/600 (inch), the pitch of the light emitting parts on the same line in the principal axis direction is 2 A, and 1/300 ( inch). When the light emitting portion light emission shift speed in the sub-axis direction matches the paper feed speed, the light emitting portion pitch B is B = A. The organic EL array is arranged in a staggered manner in the sub-axis direction with such a configuration.

  FIG. 4B is a plan view showing the result of irradiating the photosensitive member with the organic EL print head having the configuration shown in FIG. 4A at a pitch (A = B) of 600 dpi in the main axis and sub-axis directions. The exposed state is shown.

  FIG. 5 is a plan view showing the arrangement of organic EL elements according to a modification to FIG. In this example, the print result is 600 dpi in both the main axis direction and the sub axis direction, but the light emitting portion pitch of the organic EL head is an example (A ≠ C) in which the pitch is different between the main axis direction and the sub axis direction. That is, it shows the arrangement of the organic EL elements when the paper feed speed is faster than the light emission portion light emission shift speed in the sub-axis direction. The exposure result when the photosensitive member is irradiated is as shown in FIG. Similarly, the positional relationship of the light emitting portions of the organic EL print head when exposed at a pitch of 600 dpi (A = B) in the main axis and sub-axis directions is shown.

<2. Exposure control circuit>
FIG. 6 shows a configuration example of an exposure control circuit of a tandem printer, centering on the image data path in the tandem printer. In this figure, the function of each unit will be described while following the flow of image data.

  First, CMYK image data subjected to image processing by the printer controller 64 is subjected to parallel-to-serial conversion by the image data transmission unit 65, and each CMYK organic data in the head control unit 68 on the printer engine side as a CMYK LVDS SERDES signal 66. It is sent to the EL print head 2. A predetermined number of driver ICs 26 are connected in a daisy chain to the exposure head 2, and each driver IC divides and receives image data for one line in the main scanning direction, and serial-to-parallel conversion is performed. Sequentially held in the shift register. After that, in synchronization with the printing operation of the printer mechanism, the organic EL element is ON / OFF controlled in accordance with the gradation value of the image data.

  Symbol 2a is a print head for cyan (C). Similarly, symbol 2b is a print head for magenta (M), symbol 2c is yellow (Y), and symbol 2d is a print head for black (K).

  FIG. 7 shows a control circuit configuration of the organic EL array exposure head 2. As shown in FIG. 7, the organic EL array exposure head 2 has a predetermined number of driver ICs 26 mounted on the substrate in the main scanning direction, and each driver IC 26 has pixels in the main scanning direction and the sub-scanning direction. A certain block is controlled / driven.

  The data control line 57 is a signal line for connecting a predetermined number of driver ICs 26 in the main scanning direction with the same signal line, and sending print data for each line sent from the printer controller to the assigned driver IC. .

  The power supply line 58 is a power supply line that supplies power to the driver ICs 26 arranged in a predetermined number in the main scanning direction.

  The data control line 57 and the power supply line 58 are both connected in parallel to the driver IC as shown in FIG.

  FIG. 8 shows a circuit configuration of the organic EL array driver IC (driver IC 26). A predetermined number of driver ICs that cover the print width in the main scanning direction are mounted on the exposure head 1. In this figure, 192 organic EL elements are controlled by one driver IC, and the number of driver ICs is 40, but this is arbitrary. Reference numeral 27 denotes an organic EL array, which is described for easy understanding of the configuration of the organic EL array that is handled by the driver IC. In the case of this figure, the circuit configuration of a driver IC that controls four organic EL elements arranged in the sub-scanning direction is used, but this number is also optional if necessary. The configuration and function of each part will be described below along the signal flow. The operation timing will be described with reference to FIGS.

  A symbol 47 is a data input line, and is connected to the image data transmission unit 65 on the printer controller side by five sets of differential signal wirings 66 as shown in FIG. Further, inside the driver IC, it is connected to the organic EL array exposure head chip 1.

  Symbol 48 is a power supply line pad, of which a half is VDD and a half is GND.

  The address setting pad 63 sets the address of each driver IC. In the case shown in FIGS. 6 and 7, when 40 driver ICs are mounted, 40 combinations are made. Become. This combination can be determined by digitally setting the address setting pad 63 to 1 or 0 on the wiring board. The timing controller counts the number of SP (P / N) signals on the control line, compares it with the set address, and takes in data when they match.

  Symbol 69 indicates a timing controller. The light emission time data (gradation data) input from the data input line 47 is converted from serial data to 6-bit parallel data by a deserializer (not shown) in the timing controller input unit. In FIG. Are sequentially sent to the shift register 70 (o, e) extending in the right direction in the figure in synchronization with the clock. This shift register 70 (o, e) corresponds to the store means of the present invention. In 192 registers of the shift register 70 (o, e) in this example, 6-bit light emission time data per pixel is stored for 192 pixels (one line in the main scanning direction).

  A total of 192 shift registers 71 (o, e) are provided corresponding to the 192 registers of the shift register 70 (o, e) which is a store means. Each shift register 71 (o, e) has four registers corresponding to the organic EL array 8 connected in the sub-scanning direction.

  From the 192 registers of the shift register 70 (o, e), 6-bit light emission time data is output to the shift register 71 (o, e), respectively. The timing controller 69 provides a SHIFT CLK signal and an SRn (o, e) signal for controlling the shift timing of the shift register 71 (o, e), and the timing of the organic EL element driving circuit 74 (o, e). OELn (o, e) signal for controlling the light emission, and a counter clock CCLK signal for controlling the light emission time is provided to the counter 72.

  The shift register 71 sequentially shifts the light emission time data sent from the shift register 70. Further, the light emission time data held in the selected register is output to the comparator 73 (o, e) by the SRn (o, e) signal from the timing controller 69.

  The counter 72 is a counter for controlling the light emission time, and the number of bits of the counter (here, 6 bits) is the same as the bit length of the light emission time data entering the shift register 71. The input frequency of this counter is the reciprocal (frequency) of the result of time-converting the pixel pitch in the sub-scanning direction and dividing the period by the number of counts. Here, the counter 72 outputs a 6-bit count value to the comparator 73 (o, e).

The comparator 73 (o, e) has a 6-bit light emission time sent from the shift register 71 (o, e) in synchronization with the timing input signal SRn (o, e) to the shift register 71 (o, e). The data is compared with the 6-bit count value from the counter 72. As a result of the comparison, if the count value is smaller than the light emission time data, an ON signal is output to the capacitor line 52. When the count value increases and becomes the same as or larger than the light emission time data, an OFF signal is output to the capacitor line 52. Since the capacitor line 52 is connected to the organic EL element driving circuit 74 (o, e), an ON signal is output to the organic EL element driving circuit 74 (o, e) within the period specified by the light emission time data. When the emission time elapses, an OFF signal is output. Since the light emission time data is 6 bits as described above, 2 ⁶ = 64 gradations are expressed by the length of the light emission time for each pixel. The timing input signal SRn (o, e) from the timing controller 69 to the shift register 71 (o, e) is performed at a time interval obtained by dividing the clock cycle of the counter 72 by the number of lines in the main scanning direction. The organic EL element driving circuit 74 (o, e) is controlled by an output signal (capacitance line) from the comparator 73 (o, e) and timing signals OEL1 / O to 4 / E (scanning lines) from the timing controller 69. The organic EL element 79 selected by the EL element anode connection terminal 75 and the organic EL element cathode connection terminal 76 is driven in an active matrix. Details of this circuit will be described with reference to FIG.

  FIG. 9 is a diagram illustrating an example of the configuration of the light amount correction circuit of the organic EL element 79. The shift register 70 is provided with an adder circuit 84 having inputs A and B and an output Y. In the adder circuit 84, correction data for correcting the light emission amount of the organic EL element 79 is input to the input A, and light emission data indicating the light emission amount of the organic EL element 79 is input to the input B. The adder circuit 84 has a function as a correction data memory for storing correction data and a function as a light emission data memory for storing light emission data.

  The 6-bit data output from the timing controller 69 includes 5-bit data indicating light emission data or correction data, and 1-bit data indicating selection data. At inputs A and B, 5-bit data is supplied to the terminals D0 to D4, and selection data is supplied to the terminal D5.

  In this example, the input A is enabled when the selection data indicates “0”, and the input B is enabled when the selection data indicates “1”. That is, when the selection data indicates “0”, the adding circuit 84 receives the 5-bit data output from the timing controller 69 as the correction data at the input A. Then, the adding circuit 84 latches the received correction data. When the selection data indicates “1”, the adder circuit 84 receives the 5-bit data as light emission data at the input B. Then, the adder circuit 84 adds the correction data to the light emission data, converts the addition result into 6-bit data, and supplies the result to the shift register 71 from the output Y. Thereby, the light quantity correction circuit corrects the light quantity of the organic EL element 79 in the main scanning direction.

  FIG. 10 is a diagram illustrating an example of the configuration of the light amount adjustment circuit of the organic EL element 79. The light amount adjustment circuit includes a power adjustment circuit 77 that is an example of a module light emission amount control unit, and a reference voltage circuit 80 that is an example of a module light emission amount correction unit, and for each driver IC 26 that is an example of a light emitting element module. The light emission amount of the organic EL element is adjusted. Specifically, the power adjustment circuit 77 has a function of adjusting the power supplied to the organic EL element drive circuit group 74 (o, e) through the power supply line.

  The reference voltage circuit 80 has a plurality of resistors connected in series between VDD and GND, and supplies a voltage at a connection point of the plurality of resistors to the power adjustment circuit 77 as a reference voltage Vref. At least one of the plurality of resistors is provided so that the resistance value can be trimmed. The resistor is provided on the substrate 34 (see FIG. 7) by printing or the like, and the resistance value is adjusted by laser trimming. The adjustment may be performed after the organic EL array exposure head 2 is assembled.

  By adjusting the resistance value of the resistor provided in the reference voltage circuit 80, the voltage supplied to the organic EL element 79 supplied to the power supply line 51 is adjusted. That is, the light emission amount of the organic EL element 79 is adjusted. That is, the light amount adjustment circuit adjusts the light emission amount for each driver IC 26.

  The resistance value of the resistor provided in the reference voltage circuit 80 is adjusted so that the light emission amount of the organic EL element 79 is substantially uniform between the plurality of driver ICs 26 constituting the organic EL array exposure head 2. desirable. For example, the light emission amount of the organic EL element 79 is measured in the plurality of driver ICs 26, and the resistance value of the resistor in each driver IC 26 is adjusted based on the light emission amount.

  The power adjustment circuit 77 includes an error amplification circuit 81, a control circuit 82, and a voltage dividing circuit 83. The voltage dividing circuit 83 includes a plurality of resistors connected in series between VDD and GND. The voltage dividing circuit 83 supplies a voltage at a connection point of the plurality of resistors, that is, a voltage obtained by dividing VDD to the error amplifying circuit 81. The error amplification circuit 81 compares the voltage divided by the voltage dividing circuit 83 with the reference voltage Vref, and supplies a predetermined voltage based on the comparison result to the control circuit 82.

  The control circuit 82 is a MOS transistor in which VDD is supplied to one of the source and the drain and the other is connected to one end of the voltage dividing circuit 83 and the power supply line 51. A predetermined voltage is supplied from the error amplifier circuit 81 to the gate of the MOS transistor. That is, the control circuit 82 controls the power supplied to the power supply line 51 based on the comparison result of the error amplification circuit 81.

  FIG. 11 shows a circuit of the organic EL array exposure head driving unit. In this circuit, four organic EL element driving circuits 78 are connected corresponding to the four rows of organic EL elements 79, and constitute an organic EL element driving circuit group 74 (o, e). As shown in FIG. 8, the organic EL element drive circuit group 74 (o, e) is divided into odd lines and even lines in the driver IC1.

  The inputs of the organic EL element driving circuit group 74 (o, e) are the capacitor line 52, the scanning line 53, and the power supply line 51. The capacitor line 52 corresponds to the second signal line of the present invention, is connected to the output of the comparator 73 (o, e) as shown in FIG. 8, and is a signal line common to the four organic EL element driving circuits 78. The ON / OFF of the organic EL element 79 is controlled. The scanning line 53 corresponds to the first signal line of the present invention, and selectively drives the organic EL element driving circuit 78 of each line by the timing signals OEL1 / O to 4 / E which are scanning line outputs of the timing controller 69. The power supply line 51 is connected to the output of the power adjustment circuit 77 and is a drive power supply line for the organic EL element 79.

  On the other hand, the output of the organic EL element driving circuit group 74 (o, e) drives the four organic EL elements 79. The cathode connection terminal 75 is connected to the cathode of the organic EL element 79, and the anode connection terminal 76 is connected to the anode side of the organic EL element 79 and connected to the common side (power supply line).

  FIG. 12 is a circuit diagram showing the light emitting section and individual organic EL element driving circuits 78 for driving the light emitting section in an active matrix. In FIG. 12, an organic EL (OEL) element 79 is used as a light emitting part, K is a cathode terminal thereof, and A is an anode terminal thereof. The anode terminal A is connected to the power supply line 51. A scanning line 53 is connected to the gate Ga of the switching transistor (Tr1). A capacitor line 52 is connected to the source Sa of the switching transistor Tr1. Reference numeral 51 denotes a power supply line, and Ca denotes a storage capacitor.

  The source Sb of the organic EL driving transistor (Tr2) is GND 54, and the drain Db is connected to the cathode terminal K of the organic EL. Further, the gate Gb of the driving transistor Tr2 is connected to the drain Da of the switching transistor Tr1.

  Next, the operation of the circuit diagram of FIG. 12 will be described. The timing signals OEL1 / O to 4 / E from the timing controller 69 are scanned while the ON signal output from the comparator 73 (o, e) to the capacitor line 52 is applied to the source of the switching transistor Tr1. When the line 53 is energized, the switching transistor Tr1 is turned on. For this reason, the gate voltage of the driving transistor Tr2 rises, and the drain Db and the source Sb become conductive. As a result, the organic EL element operates and emits light with a predetermined amount of light. The storage capacitor Ca is charged with the voltage of the capacitance line 52.

  Even when the switching transistor Tr1 is turned off, the driving transistor Tr2 is still in the conductive state based on the electric charge charged in the storage capacitor Ca, so that the organic EL element 79 maintains the light emitting state. Therefore, when the active matrix is applied to the drive circuit of each light emitting section formed in the array assembly 27, the operation of the organic EL element continues to maintain light emission even when the switching transistor Tr1 is turned off. The pixel can be exposed with high brightness. Further, the light emission maintenance by the charge of the storage capacitor Ca when the switching transistor Tr1 is turned off is continued regardless of the signal of the capacitor line 52 as long as the switching transistor Tr1 is turned off. For this reason, the light emission start and end of the organic EL elements can be controlled in a time-sharing manner as will be described later by using the common capacitance line 52 in the four organic EL element driving circuits 78.

  The signal output from the comparator 73 (o, e) to the capacitor line 52 is turned OFF, and the switching transistor Tr1 is turned ON by the timing signals OEL1 / O to 4 / E output from the timing controller 69 to the scanning line 53. In this case, the charge charged in the storage capacitor Ca is absorbed by the capacitance line 52 through the switching transistor Tr1. Accordingly, the gate voltage of the driving transistor Tr2 is lowered, and the light emission of the organic EL element 79 is finished.

  FIGS. 13 and 14 show an organic EL element driving circuit 78 according to a modification to FIGS. 11 and 12. In the organic EL element driving circuit 78 of FIGS. 11 and 12, the anode terminal A of the light emitting unit is shared and connected to the power supply line 51. However, in FIGS. 13 and 14, the cathode terminal K is shared and is connected to GND. Connected. In this case, the anode terminal A is connected to the drain Db of the driving transistor Tr2 of each organic EL element driving circuit 78, and the power supply line 51 is connected to the source Sb of the driving transistor Tr2. Even with such a configuration, the organic EL element can be driven in accordance with the ON / OFF signal supplied from the capacitor line 52.

  The driver IC 1 as described above can be configured by using a known semiconductor manufacturing technique, and thus a detailed description of the manufacturing method is omitted.

<3. Control timing>
FIG. 15A shows the input signal timing of the timing controller 69 of FIG. 8, and shows the timing of the input signal of the driver IC. The control line of the driver IC is composed of five sets of differential lines, and FIG. 15 (a) will explain timing related to fetching light emission time data.

  SP (P / N) is a start signal that generates a pulse before receiving light emission time data, and thereafter occurs every time before reception of 192 pixels × 6 bits = 1152 light emission time data. The timing controller 69 counts the number of the SP (P / N) pulses, compares it with the address value set in the driver IC, and takes in 192 × 6 data thereafter when they match.

SDCLK (P / N) is a serial data synchronization clock, and reads serial data at both rising and falling edges of the clock. The SDCLK period is a value obtained by dividing the maximum light emission time of each element by the number of light emitting elements in the main axis direction, further dividing by the light emission time data width, and multiplying that value by the number of reads in the SDCLK period. In this figure, when the A4, 600 dpi, 50 ppm tandem color printer is used, the result is as follows.
Maximum light emission time = 170 (μsec)
Number of light emitting elements in main axis direction = 7680 (pieces)
Light emission time data width = 6 (bits)
Number of reads in SDCLK cycle = 2 (times)
SDCLK cycle = 170 (μsec) ÷ 7680 ÷ 6 × 2≈7.4 (nsec)
Therefore, the frequency of SDCLK is about 135.5 MHz.

  SD (P / N) is a set of 6-bit serial data (light emission time data) and is read in synchronism with SDCLK as shown in FIG.

  FIG. 15B shows the input signal timing of the timing controller 69 of FIG. 8, and two sets of inputs other than the input signal shown in FIG. 15A among the five sets of differential input signals of the driver IC. Signal timing is shown.

  RCLR (P / N) is a data clear signal of the shift register 70 (o, e), and the light emission time data output to the shift register 71 (o, e) is cleared by this pulse.

  TCCLK (P / N) is a reference clock related to the light emission time control of the organic EL element controlled by the timing controller 69 of FIG. 8, and based on this, SHIFT CLK, CCLK, OELn (o, e), SRn The timing of (o, e) is determined.

  FIG. 16 shows the transfer timing of parallel image data (light emission time data) sent from the timing controller 69 to the shift register (o, e) 70. DTSP (P / N) is a transfer start signal of image data, and DCLK (P / N) is a synchronous clock at the time of data transfer. PADn is parallel image data, and this description represents the case of 6-bit data. PADn is sequentially written to the shift register 70 (o, e) in synchronization with the rising and falling edges of DCLK.

  FIG. 17 shows details of the selector section output signal timing of the timing controller 69 of FIG.

TCCLK is a reference clock for controlling the light emission time of the organic EL element, and a period obtained by dividing the maximum light emission time of each element by the light emission time control division number and further dividing by the number of lines in the sub-scanning direction. . In this figure, when the A4, 600 dpi, 50 ppm tandem color printer is used, the result is as follows.
Maximum light emission time = 170 (μsec)
Light emission time control division number = 2 ⁶ = 64 (division)
Number of lines in the sub-scanning direction = 8 (lines)
TCCLK cycle = 170 (μsec) ÷ 64 ÷ 8≈332 (nsec)
Therefore, the frequency of TCCLK is about 3 MHz.

  SHIFT CLK is a clock for sequentially shifting the register holding value of the shift register 71 (o, e), and is obtained by dividing the maximum light emission time of each element by the light emission time control division number.

  CCLK is a count input signal of the counter 72 of FIG. 8, and has the same frequency as SHIFT CLK.

  The scanning line signal OEL1 / O and the register selection signal SR1 / O generate a pulse corresponding to one cycle of the TCCLK clock at the same timing in synchronization with the rising edge of the first TCCLK from the falling edge of the SHIFT CLK.

  OEL ON / OFF indicates the ON time (light emission time) of the organic EL element 79 in FIG. 8. In this example, the light emission time width is from 0 μsec to the maximum light emission time 170 μsec.

  The light emission operation will be described with reference to these signals. The light emission time data output from the first-stage register of the shift register 71o by the register selection signal SR1 / O is compared with the counter value, and an ON or OFF signal is output to the capacitor line 52. On the other hand, at the same timing, the scanning line signal OEL1 / O is output to the first-stage organic EL element driving circuit 78 at regular intervals.

  As described above, if the capacitance line 52 is ON when the scanning line signal OEL1 / O is ON, the OEL is ON and the organic EL element 79 is lit. Even when the scanning line signal OEL1 / O is turned off, the organic EL element 79 is kept on. Further, if the capacitance line 52 is OFF when the scanning line signal OEL1 / O is ON, OEL is OFF and the organic EL element 79 is turned off.

  FIG. 18 shows signal timings of the selector unit and the light emitting element driving circuit of the timing controller 69 of FIG. In FIG. 17, OEL1 / O and SR1 / O have been described as the basic operation. However, in FIG. 18, the light emission control timing of the organic EL elements of 8 lines including the even lines and the odd lines in the sub-scanning direction. explain.

  The scanning line signal OELn / O and the register selection signal SRn / O generate pulses corresponding to one cycle of the TCCLK clock in synchronization with the rising edge of the nth TCCLK from the falling edge of the SHIFT CLK at the same timing. Since the register selection signal SRn / O selects the n-th line register (see FIG. 8) of the shift register 71, the light emission time data output from the register is compared with the counter value by the comparator 73, and the capacitance line 52 An ON or OFF signal is output to. On the other hand, at the same timing, the scanning line signal OELn / O selects the nth organic EL element scanning line (see FIG. 8). As described above, the organic EL element driving circuit 78 can turn on / off the organic EL element depending on the state of the capacitance line 52 only when the scanning line is selected. Therefore, the plurality of organic EL element driving circuits 78 can be driven in a time-sharing manner by shifting the selection timing of the scanning lines connected to other organic EL element driving circuits that share the capacitor line 52.

  When all the light emission based on the light emission time data of each register of the shift register 71 is completed, the light emission time data of each register of the shift register 71 is shifted to the next register every 64 pulses of SHIFT CLK, and light is emitted in the same manner. At this time, by moving the relative positions of the photoconductor and the organic EL array in the sub-scanning direction, exposure based on the same light emission time data can be performed on the same pixel on the photoconductor.

  In the present embodiment, since ON / OFF of the plurality of rows of organic EL elements is controlled in a time-sharing manner, all of them can be made to emit light at the same time. On the other hand, when the data rewrite time of the shift register 71 is long, there is a possibility that the lighting of the organic EL element may be hindered. However, in the present embodiment, the data for one line is temporarily stored in the shift register 70 which is a store means. Since the data is shifted to the shift register 71 at once after the store, the data rewriting is completed in a short time, and the lighting of the organic EL element is not hindered.

  In the present embodiment, a comparator 73 common to the plurality of organic EL element driving circuits 78 is connected via the capacitor line 52. In the present embodiment, the register selection signal SRn / O and the scanning line signal OELn / O are synchronized, and the selection timing of the scanning line connected to the other organic EL element driving circuit 78 sharing the comparator 73 is shifted. Therefore, even if the comparator 73 is shared, the plurality of organic EL element drive circuits 78 can be driven with different light emission times.

  In the present embodiment, a common counter 72 is connected to the plurality of comparators 73o and 73e. As shown in FIGS. 17 and 18, since all the emission time data and the counter output are compared by the register selection signal SRn within the period of the counter clock CCLK1, even if the counter 72 is shared, the individual emission time data. Gradation control based on is possible.

It is the top view which looked at the organic EL array exposure head concerning this invention from the top. FIGS. 2A and 2B are views showing one of the head chips 1 mounted on a substrate 34, FIG. 2A is a plan view thereof, and FIG. 2B is a cross-sectional view in the major axis direction thereof. It is a top view for demonstrating the space | interval of the head chip 1 for every row | line | column in the case of arrange | positioning the head chip | tip 1 in 2 rows zigzag form. FIG. 4A is a plan view showing the details of the arrangement of the light emitting portion of the organic EL array exposure head, and FIG. 4B is an exposure on the surface of the photoreceptor using the organic EL array exposure head shown in FIG. It is a top view explaining the exposure position when doing. It is a reference top view of element arrangement | positioning of the organic electroluminescent exposure head which concerns on the modification of Fig.4 (a). FIG. 2 is a diagram illustrating an overall configuration of an exposure head control circuit in a tandem printer. It is a figure which shows the circuit structure of an organic EL array exposure head. It is a figure which shows the circuit structure of the driver IC used for an organic EL array exposure head. 3 is a diagram illustrating an example of a configuration of a light amount correction circuit of an organic EL element 79. FIG. 5 is a diagram illustrating an example of a configuration of a light amount adjustment circuit of an organic EL element 79. FIG. It is a figure which shows the circuit structure of an organic EL array exposure head drive part. It is a figure which shows the detailed circuit of the drive part of an organic EL element. It is a figure which shows the circuit structure of the organic electroluminescent array exposure head drive part which concerns on the modification of FIG. It is a figure which shows the detailed circuit of the drive part of the organic EL element which concerns on the modification of FIG. It is a figure which shows the timing regarding image data (light emission time data) reception of a driver IC. It is a figure which shows the timing which transfers image data to the shift register of a spindle direction. It is a figure which shows the main signal of the part which controls electricity supply of an organic electroluminescent array, and a PWM control timing. It is a figure which shows the detail of the electricity supply timing with respect to organic EL of the some line which comprises an organic EL array.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Organic EL array exposure head chip 2 ... Organic EL array exposure head 3 ... Connector 4a, 4b, 4c ... Light emission part 5 ... Wire bonding pad 6 ... Wire bonding pad 7 ... Bonding wire 8 ... Positioning pad 9 ... Positioning pad 13 ... Condensing lens 19 ... Light hole 25 ... Light emitting part 26 ... Driver IC
27 ... Organic EL array assembly 28 ... Condensing lens assembly 30 ... Positioning pad 32 ... Die bond material 33 ... Ultraviolet (UV) cured resin adhesive 34 ... Substrate 35 ... Anisotropic conductive adhesive 47 ... Data input line 48 ... Power line 51 ... Power supply line 52 ... Capacity line (second signal line)
53. Scanning line (first signal line)
54 ... GND
57 ... Data control line 58 ... Power line 64 ... Printer controller 65 ... Image data transmission unit (printer controller side)
66 ... Differential signal wiring 68 ... Printer engine side head controller 69 ... Timing controller 70 ... Shift register (o, e) (store means)
71: Shift register (o, e)
72 ... Counter 73 ... Comparator (o, e)
74 ... Organic EL element drive circuit (o, e)
75 ... Organic EL element anode connection terminal 76 ... Organic EL element cathode connection terminal 77 ... Power adjustment circuit 78 ... Organic EL element drive circuit details 79 ... Organic EL element (light emitting element)

Claims (5)

A light emitting element group having a plurality of light emitting elements arranged in a predetermined direction;
A plurality of light emitting data memories provided corresponding to the plurality of light emitting elements, and storing light emission data indicating the light emission time of the corresponding light emitting elements;
A plurality of correction data memories provided corresponding to the plurality of light emitting elements and storing correction data for correcting the light emission time of the corresponding light emitting elements;
A light emission data correction unit that corrects the light emission data corresponding to the correction data based on the correction data;
An optical head comprising: an element drive circuit that causes the light emitting element to emit light based on the corrected light emission data. In claim 1,
The plurality of correction data memories store the correction data of the light emitting elements corresponding to the respective correction data memories by sequentially shifting the correction data to the plurality of correction data memories,
The plurality of light emission data memories correspond to each of the light emission data memories by sequentially shifting the light emission data to the plurality of light emission data memories when the plurality of correction data memories store the correction data. Storing the light emission data of the light emitting element;
An optical head in which the element driving circuit causes the plurality of light emitting elements to emit light when the plurality of correction data memories shift and store the plurality of light emission data in the plurality of light emission data memories. In claim 1,
A control unit that generates a plurality of bit data composed of a plurality of bits as the light emission data or the correction data;
A plurality of shift registers provided corresponding to the plurality of light emitting elements and sequentially shifting the plurality of bit data;
The correction data memory stores the bit data as the correction data when a predetermined bit in the bit data stored in the corresponding shift register indicates a predetermined value,
The light emission data memory is an optical head that stores the bit data as the light emission data when the predetermined bit in the bit data stored in the corresponding shift register indicates another value. In any one of Claim 1 to 3,
The light emission data correction unit includes an addition unit that corrects the light emission data by adding the correction data to the light emission data. In any one of Claims 1-4,
The light emitting element is an optical head which is an organic EL element.

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