KR19990007108A - Optical printer - Google Patents

Abstract

The capacity is reduced and the processing time is increased.

A plurality of light-emitting dots 14 are linearly or rotationally moved relatively linearly or rotationally between the head and the recording medium so that the head is exposed on the surface of the recording medium to form an image on the recording medium. The count value incremented in synchronization with the input of the image data to 43 is input to the two-way correction memory 43. In the two-way correction memory 43, luminance correction data corresponding to the gradation for each light emitting dot 14 is stored. Data stored in the two-way correction memory 43 is read based on the image data input via the input data bus 46 and the count value from the counter 42 in synchronization with the input of the image data. The gradation control means 44 performs time division gradation control on the light emission time of each light-emitting dot 14 through the driving means 45 based on the data read out from the two-way correction memory 43.

Description

Optical printer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical printer such as an electrophotographic printer, a silver salt printer, a label printer, a video printer, in particular, an optical printer which requires high image quality, for forming a desired image on a recording medium such as a photosensitive film.

The applicant proposes an optical printer shown in Fig. 3 as an exposure apparatus for forming a desired image on a recording medium such as a photosensitive film.

The optical printer 1 records on the color film 3 as the recording medium with the fluorescent light emitting tube 2 serving as a print head as a light source and the three primary colors of light obtained from freely convertible color filters R, G and B. To form a full-color image. The optical printer 1 is driven by, for example, a digital color image signal obtained from a video device or the like, and can be used as a color video printer which prints an image in full color on a color film.

The optical printer 1 has the head 4 as shown in FIG. The head 4 moves in the sub-scanning direction shown by arrow A with respect to the color film 3 as the recording medium set at a predetermined position. The head 4 is positioned at a position corresponding to the light emitting portion of the fluorescent light emitting tube 2, which is the printhead, and the three color filters R, G, B which can be switched with respect to the fluorescent light emitting tube 2, and the fluorescent light emitting tube 2. It has a single optical system including the set lens 6 and the reflecting mirrors 7, 7.

The head 4 of the optical printer 1 reciprocates with respect to the color film 3 in the sub-scanning direction A by the moving means. The moving means includes guide means (not shown) for movably guiding the head 4 in the sub-scanning direction A, a pair of pulleys 9 and 9 and pulleys 9 and 9 on which the driving belt 8 is rotated. Has a drive motor 10 for rotating one side. When the driving belt 8 is circulated by driving the driving motor 10, the head 4 fixed to the driving belt 8 is guided to the guide means and moves along the sub-scanning direction A. FIG.

The head 4 is equipped with a fluorescent light emitting tube 2 which is a light source. The fluorescent light emitting tube 2 has an envelope 13 in which the inside is kept in a high vacuum state on a substantially rectangular parallelepiped formed by sealing a box-shaped container portion 12 to a translucent rectangular substrate 11.

On the inner surface of the substrate 11, a plurality of light emitting dots 14 are formed in a row at a predetermined interval along the longitudinal direction of the substrate 11. In the column of Fig. 3, the light emitting dot 14 is composed of an anode conductor provided on the substrate 11 and a phosphor layer deposited on each anode conductor. The parallel direction of the light emitting dot 14 is parallel to the main scanning direction orthogonal to the sub scanning direction A which is the moving direction of the head 4. Below the light emitting dot 14, the linear cathode 15 as an electron source is provided along the main scanning direction. The anode conductors of the respective light-emitting dots 14 are independently drawn out of the envelope 13, and can be driven independently by driving signals.

The head 4 is provided with color filters R, G and B. The color filters R, G and B are arranged in the vicinity of the outer surface side of the substrate 11 of the fluorescent light emitting tube 2 and are movable in the sub-scanning direction A. FIG. When the positions of the color filters R, G and B are switched, the types of the color filters R, G and B through which the light from the light emitting dot 14 passes can be set arbitrarily.

The mechanism described above is housed in a casing (not shown). In this casing, the color film 3 as a recording medium is stored. When the plurality of sheets of color film 3 are held at a predetermined position and recording by light (light) is completed, they are held by the spread roller 16 and discharged out of the casing.

The procedure for forming a full color image on the color film 3 using the optical printer 1 having the above-described configuration will be described. On the basis of the respective image signals of the image separated into three primary colors, the fluorescent light emitting tube 2 is driven, and the head 4 is moved in the sub scanning direction A in synchronization with this driving. At this time, in the light emission dot 14 of the fluorescent light emitting tube 2 of the head 4, the primary color filter R or G or B corresponding to the drive signal is set. The above operation is performed for each of the three primary colors, and three images separated into three primary colors are superimposed on the photosensitive surface of one color film 3 and recorded. In other words, when three scans are performed while switching the types of the color filters R, G and B, a full color image is formed on the color film 3.

As described above, in the optical printer 1 according to the above configuration, the head 4 having the fluorescent light emitting tube 2 having the light emitting dots 14 arranged in a linear direction in the main scanning direction is scanned by scanning in the sub-scanning direction A. The surface of the recording medium is exposed.

In the optical printer 1, the head 4 travels in the sub-scanning direction A by a distance equal to one dot of the light-emitting dot 14, and the light-emitting dot 14 within this time. The gray level is added while changing the time ratio of the light emission and non-light emission. According to this time control method, stable control with high linearity is possible as compared with the voltage control method.

By the way, in order to obtain a good image, it is preferable that the luminance of the light emitting dot 14 is the same. In order to look consistent with the human eye, it is considered necessary to suppress the stain by about 1%. However, on the manufacture of the head, staining of about tens of percent is difficult to avoid. Therefore, it is necessary to measure and correct the luminance of each light emitting dot.

For example, the luminance of each light emitting dot measured now is L (n), provided that n = 0, 1, 2,... The minimum value thereof is referred to as Lmin. If the data to be exposed is Din (n), the data Dout (n) of Equation 1 below is given to the light emitting dot so that the amount of light emitted is Dout (n) × L (n) = Din (n) × Lmin / L (n X L (n) = Din (n) × Lmin, which is irrelevant to the luminance L (n) for each light emitting dot.

As a result, the luminance spot can be corrected.

By the way, since the calculation of Formula (1) includes division and it is difficult to execute at high speed, the result calculated in advance is stored in the ROM as tabular data, and the operation is replaced by a table reference.

Fig. 4 shows an example of a table reference type correction circuit in the case of performing luminance spot correction. The correction circuit 21 includes a luminance smear correction memory 22 made of ROM and a counter 23. In the luminance spot correction memory 22, data for luminance spot correction is stored. In the luminance smear correction memory 22, A0 to AM-1 are connected to the input data bus 24, AM to AM + N-1 are connected to the counter 23, and D0 to DK-1 are output. do. The counter 23 inputs a count value incremented by the recording clock into the luminance smear correction memory 22 each time image data is input to the luminance smear correction memory 22.

In the correction circuit 21, when the number of dots of the light emitting dot 14 is 2 ^N and the input image data Din is 2 ^M gradation, the table of the luminance smear correction memory 22 is 2 ^{N + M} , that is, An address of N + M bits is required. In addition, the output bit number is a number of gradations of time control, when this as ^K 2, if able to reduce the calculation error in the last place is required K≥M relationship, and K> M is preferred.

In the correction circuit 21 having the above-described configuration, the count value of the counter 23 is incremented each time the image data Din (n) before correction enters from the input data bus 24. Then, as a count value at that time, the value of the address n × 2 ^M + Din (n) is read from the luminance smear correction memory 22 and output. For this reason, the Din (n) × Lmin / L (n) phosphorus value is previously recorded in the n × 2 ^M + Din (n) address of the luminance smear correction memory 22.

By the way, the photosensitive material used for a recording medium also has a nonlinear characteristic. FIG. 5 is a conceptual diagram in which the horizontal axis is the exposure amount and the vertical axis is the color development amount. However, in the silver salt film, an S-curved curved upper and lower surface is drawn as in FIG.

This curve is called t = F (s), and the maximum value of the color development amount is t max, and the amount of light emitted at this time is s max. The inverse function s = F ^-1 (t) of F (s) is used for correction. If the exposure amount before correction is s, the actual light emission amount s 'is represented by the following formula 2, and the color development amount is F (s') = F (F- ¹ (s × t max / s max)) = s × t max / s It is max and is proportional to s.

The calculation of formula (2) is also replaced by a table reference. In this case, when s is an input and s 'is an output, but s is 2 ^I gray and s' is 2 ^M gray, in order to reduce the calculation error of the last digit, it is necessary to make M≥I and M> I is desirable.

Further, as shown in Fig. 6, when the photosensitive material having extremely different sensitivity is used, when the exposure amount cannot be adjusted by another method, M becomes large enough to correspond to I. In other words, if the sensitivity ratio is about ² times as shown in Fig. 6, M?

Therefore, conventionally, a table reference type correction circuit shown in Fig. 7 is employed, and two stages of correction and fastening of sensitivity correction and luminance speckle correction are performed in sequence.

The correction circuit 31 of FIG. 7 includes a sensory characteristic correction memory 32 made of ROM, a luminance unevenness correction memory 33 made of ROM, and a counter 34. The photosensitive characteristic correction memory 32 stores data for performing density correction (correction of nonlinearity of the sensitivity of the photosensitive material) of the photosensitive material. In the sensory characteristic correction memory 32, A0 to AI-1 are connected to the input data bus 35. In the luminance spot correction memory 33, data for luminance spot correction is stored. In the luminance smear correction memory 33, A0 to AM-1 are connected to D0 to DM-1 of the sensory characteristic correction memory 32, AM to AM + N-1 are connected to the counter 34, and D0. DK-1 is an output. The counter 34 is input to the luminance smear correction memory 33 as an address as a count value incremented by the recording clock whenever image data after density correction of the photosensitive material is input to the luminance smear correction memory 33. .

In the correction circuit 31 of FIG. 7, whenever the image data Din (n) before correction enters from the input data bus 35, density correction of the photosensitive material is performed. The counter 34 increments the count value each time the image data after density correction of the photosensitive material is input to the luminance smear correction memory. The image data after density correction of the photosensitive material is read out from the luminance smear correction memory 33 with the value of n × 2 ^M + Din (n) as the count value at that time.

In this manner, in the correction circuit 31, density correction of the photosensitive material is performed first, and luminance stain of the head is subsequently performed. In addition, in the case of using a plurality of photosensitive materials having different characteristics, the photosensitive characteristic correction memory 32 is prepared for each type of photosensitive material, and switched. Alternatively, the sensory characteristic correction memory 32 may be made of a recordable RAM, an EEPROM, or the like, and a table corresponding to the photosensitive material used at the time of initialization may be recorded.

By the way, in the home printer, since the price request is more severe than the image quality request and there is no use of a plurality of photosensitive materials with extremely different sensitivity, all the corrections have been uniformly performed as 8-bit operations (I = K = M = 8). Therefore, in this case, the size of the table does not matter much.

In other words, since the input image data is 8 (= I) bits, the data reduction characteristic correction memory 32 ends with 256 bytes of 1 byte per word since M words are 8 bits. In the case where the number of dots is 512 = 2 ⁹ (N = 9), since the M is 8, the number of addresses is 128 kilowords of N + M = 9 + 8 = 17 bits, K. Since it is 8 bits, one byte per word ends with 128 kilobytes and one megabit of ROM.

By the way, when a high quality is demanded like an industrial printer, the table becomes large like a snowball. For example, consider the case where the input image data increases the number of dots to 1024 (N = 10) by 8 (= I) bits. In that case, it is assumed that the photosensitive material having a sensitivity ratio of about four times is used.

Since I = 8 and 4 times the sensitivity ratio, M must be increased by 2 bits or more than I. By taking the extra bits and increasing them by 3 bits so as not to deteriorate the image quality, M = 11. Therefore, the data reduction characteristic correction memory 32 has the same 256 words, but one word is 11 bits.

In contrast, since the luminance smear correction memory 33 has N = 10 and M = 11, the address is inflated with N + M = 10 + 11 = 21 bits, that is, 2 megawords, and with K being 12 bits, 3 megabytes, 1 In the case of megabit ROM, 24 to 32 are required.

The above description is for a monoclonal optical printer, but when applied to a color optical printer having a three-head configuration of R (red), G (green), and B (blue), this triple ROM is simply required. It becomes

As described above, when performing density correction of the photosensitive material and luminance spot correction of the head, separate look-up tables (sensing material characteristic correction memory 32 and luminance spot correction memory 33) are used. Therefore, if the input image data is 2 ^I gradation and the density correction of the photosensitive material is 2 ^M gradation and the number of dots is 2 ^N , 2 ^I table is used for the density correction of the photosensitive material, and 2 ^{(M + N)} tables were required each.

In addition, when the correction circuit 31 shown in Fig. 7 is applied to a color optical printer, the luminance smear correction memory 33 requires an address of 2 megawords per RGB. By the way, only 256 words are used at the same time, and 256 words are selected and used out of 2 mega words by switching the photosensitive material. Therefore, there is a problem that the table of memory is unnecessarily consumed in the correction circuit of FIG.

Accordingly, the present invention has been made in view of the above problems, and an object of the present invention is to provide an optical printer which can reduce the capacity and speed up the processing time.

In order to achieve the above object, the invention of claim 1 includes a head having a plurality of light emitting dots arranged in a line, a moving mechanism for relatively linearly or rotationally moving the head and the recording medium, and a drive for emitting the light emitting dots. An optical printer having a means, wherein the head is subjected to surface exposure on the surface of the recording medium to form an image on the recording medium.

A counter for outputting a count value incremented in synchronization with the input of image data;

Correction data storage means for storing luminance correction data according to the gradation for each of the light emitting dots, and reading the stored data based on the image data and the count value from the counter;

And gradation control means for time-division gradation control of the light emission time of each light-emitting dot driven by the drive means based on the data read out from the correction data storage means.

The invention of claim 2 is that, in the optical printer of claim 1, the correction data storage means is provided for each type of photosensitive material, and is switched to the correction data storage means according to the type of photosensitive material used for the recording medium. It features.

The invention of claim 3 is characterized in that in the optical printer of claim 1, the correction data storage means comprises a memory capable of record exchange.

1 is a block diagram showing one embodiment of the present invention;

FIG. 2 is a diagram showing a relationship between an address and an output value of a two-way correction memory in FIG. 1;

3 is a diagram showing the overall configuration of an optical printer;

4 is a diagram showing a conventional configuration in the case of performing luminance unevenness correction;

5 is a conceptual diagram of nonlinear characteristics of a photosensitive material;

6 is a conceptual diagram of characteristics of a photosensitive material having significantly different sensitivity;

Fig. 7 is a conventional configuration diagram when density correction and luminance speckle correction of the photosensitive material are performed.

[Explanation of symbols on the main parts of the drawings]

1: optical printer 4: head

8: drive belt 9: pulley

10: drive motor 14: light emitting dot

41: correction circuit 42: counter

43: Two-way correction memory (calibration data storage means)

44: gradation control means 45: driving means

1 is a diagram showing the form of one embodiment of the present invention.

The structure of this embodiment is applied to the optical printer of FIG. 3 demonstrated in the term of the prior art. This embodiment differs from the conventional example in the structure for performing density | concentration correction of the photosensitive material (correction | amendment of the nonlinearity of the sensitivity of the photosensitive material), and brightness | luminance stain of a head. Moreover, the optical printer to which this embodiment is applied is not limited to the structure shown in FIG.

The correction circuit 41 of this embodiment is roughly comprised by the counter 42, the two-way correction memory (correction data storage means) 43, the gradation control means 44, and the drive means 45. As shown in FIG.

The counter 42 inputs the recording clock, increments the counter value by the recording clock in synchronization with the input of the image data to the two-way correction memory 43, and inputs the counter value to the two-way correction memory 43. have.

The two-way correction memory 43 is composed of, for example, a ROM, and stores luminance data according to the gradation for each light emitting dot 14. In the two-way correction memory 43, AI to AI + N-1 are connected to the output of the counter 42, A0 to AI-1 are connected to the input data bus 46, and D0 to DK-1 which are outputs. Is connected to the input of the gradation control means 44. In the two-way correction memory 43, for example, when I = 8, parallel image data of 8 bits is inputted through the input data bus 46 for each light emitting dot 14. The two-way correction memory 43 addresses the image data for each of the light emitting dots 14 input through the input data bus 46 and the count value from the counter 42 in synchronization with the input of the image data. The data stored at the address is read.

In other words, a value of F ⁻¹ (Din (n) × L min × t max / s max) / L (n) is previously set at n × 2 ^I + Din (n) of the two-way correction memory 43. It is recorded. 2 is a diagram showing a relationship between an address and an output value of the two-way correction memory 43. As shown in FIG. In the figure, n = 0 to 255 show counter values input from the counter 42. Din (0) to Din (n) show the image data inputted for each of the light emitting dots 14 through the input data bus 46. Dout (n) _{0 to} Dout (n) ₂₅₅ are output data. For example, when K = 11, values of 0 to 2047 are output.

The gradation control means 44 controls time division gradation of the emission time of each light-emitting dot 14 driven by the drive means 45 based on the data read out from the two-way correction memory 43. The value of the data read from 43 is converted into data indicating the lighting time of the light emitting dot 14 and output to the drive means 45.

The driving means 45 is a driver circuit for driving light emission dots 14 of the head 4, and drives the light emission dots 14 corresponding to the time according to data from the gray scale control means 44. Doing. As a result, each of the light-emitting dots 14 is time-divided gradation controlled from the gradation control means 44 via the driving means 45.

In the correction circuit 41, image data of a predetermined number of bits of each of the light emitting dots 14 is sequentially input to the two-way correction memory 43 through the input data bus 46. The counter 42 increments the counter value by the recording clock and inputs it to the two-way correction memory 43 each time image data is input to the two-way correction memory 43. From the two-way correction memory 43, image data input via the input data bus 46 and data stored at an address by a count value from the counter 42 in synchronization with the input of the image data at that time are read out. It is input to the gradation control means 44. The gradation control means 44 converts the data value from the two-way correction memory 43 into data indicating the lighting time and outputs it to the drive means 45. The driving means 45 drives the light emitting dot 14 corresponding to the time of data from the gray scale control means 44 to emit light.

By adopting the correction circuit 41 according to the above structure to the optical printer 1 shown in Fig. 3, n × 2 of the two-way correction memory 43 is applied to the image data D _in (n) during exposure. The data of the address ^I + Din (n) is read. As a result, the exposure amount is expressed by the following equation.

The amount of color development is expressed by the following equation (4).

As apparent from Equation 4, since the amount of color development is irrelevant to either L (n) or F (s), both density correction and luminance speckle correction of the photosensitive material for each light emitting dot 14 are performed at once.

By the way, in the correction circuit 41 of the above structure, when using a plurality of photosensitive materials having different characteristics, the two-way correction memory 43 is prepared and switched for each photosensitive material just as before. Also, the two-way correction memory 43 may be made of a RAM or an EEPROM capable of recording exchange, and a table corresponding to the photosensitive material used at the time of initialization may be recorded.

In this manner, according to the above embodiment, the density correction and the luminance stain correction of the photosensitive material can be simultaneously corrected by one table (two-way correction memory 43). In this case, the two-way correction memory 43 outputs K bits of data to an address of N + I bits. This results in 2 ^{I + N} tables. In addition, since I < M, the size of the table can be greatly reduced than before, resulting in a cost reduction in manufacturing an optical printer.

When the numerical value is displayed, when the input image data increases the number of dots to 8 (= I) bits to 1024 (N = 10), the address is 10 + 8 = 18 bits, i.e. 256 kilowords, 1 word 12 bits, and 384 kilobytes. And can be reduced to 1/8 capacity. As a result, three to four 1-megabit SRAMs or one 4-megabit DRAM can be implemented as correction memory. When using the RGB three-system circuit in the color is three times this.

In addition, since the two-stage table references of the sensory characteristic correction memory 32 and the luminance spot correction memory 33 are reduced to the two-way correction memory 43 only, the electrical delay time is also reduced by half compared to the conventional one. This has the effect of speeding up the processing time and facilitating circuit design. As a result, the drive circuit having the same function can be realized at a lower cost and a lower power consumption.

As apparent from the above description, according to the present invention, the density correction of the photosensitive material and the luminance smear correction of the head can be simultaneously corrected in one table. As a result, the size of the table can be significantly reduced compared with the conventional one, and the optical printer can be manufactured at a cost down. In addition, the electrical delay time is reduced by about half, the processing time can be increased, and the circuit design becomes easy.

Specifically, 2 ^{I is the} number of gradations in the input image data, 2 ^{M is the} image data after the density correction of the photosensitive material of the recording medium, 2 ^{N is the} number of dots of the light emitting dots, and image data after the luminance smear correction of each light emitting dot. If hayeoteul to 2 ^K, with a table of prior art is 2 ^I dog × M-bit, 2 ^{(M + N)} more ×, 2 ^{(I + N)} with respect to who K bits each require a separate table in the × K bits You can complete it.

Claims (3)

A head having a plurality of light emitting dots arranged in a line, a moving mechanism for relatively linearly or rotationally moving the head and the medium to be recorded, and driving means for light-emitting driving the light emitting dot, An optical printer for surface-exposure on a surface to form an image on the recording medium, A counter for outputting a count value incremented in synchronization with the input of image data; Correction data storage means for storing luminance correction data according to the gradation for each of the light emitting dots, and reading the stored data based on the image data and the count value from the counter; And gradation control means for time-division gradation control of the emission time of each light-emitting dot driven by said drive means based on the data read out from said correction data storage means. The optical printer according to claim 1, wherein the correction data storage means is provided for each type of photosensitive material and is switched to the correction data storage means according to the type of photosensitive material used for the recording medium. An optical printer according to claim 1, wherein said correction data storage means comprises a memory capable of recording exchange.