JP2687446B2 - Image exposure equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of use] The present invention relates to an image exposure apparatus, and more specifically, an image forming an image by simultaneously exposing a photosensitive paper carrying two or more coloring components on its surface. The present invention relates to an exposure apparatus.

[Prior Art] Conventionally, in an apparatus that forms an image by exposing a photosensitive paper carrying on its surface two or more colors, for example, cyan, magenta, and yellow color-forming components, the most suitable illumination for each color-forming component. Since the energies are different from each other, the exposure time is adjusted and the exposure is performed together with the adjustment of the irradiation energy corresponding to the color of the predetermined image, so that each color exhibits the best color development. In the case of using a halogen lamp as a light source to guide the transmitted or reflected light from the original to the photosensitive paper for exposure, it is necessary to change the transmittance of the filter for each color or adjust the aperture to perform such adjustment. I take it, but the adjustment is not easy.

On the other hand, as illustrated in FIG. 13, yellow, magenta,
In recent years, an apparatus has been proposed in which a multicolor optical image corresponding to cyan is displayed on a color cathode ray tube CRT and the photosensitive paper OS is exposed by this optical image. In such a device, in order to obtain a multi-gradation image, the signals input from the control device CTL to the circuits CY, CM and CC for driving the color cathode ray tube CRT are adjusted. Such adjustment will be described with an example.

The photosensitive paper CS shown in FIG. 13 has light-softening type microcapsules carried on its surface, and each color component enclosed in the microcapsules has the coloring characteristics shown in FIG. That is, the yellow dye has a wavelength of 450 nm and an energy of 5,000.
It begins to develop color when exposed to a light amount equivalent to erg / cm ² , and develops 100% at 7,000 erg / cm ² , and the gradation between them has the characteristic of changing linearly. Also, the magenta dye is
It starts to develop color with light of wavelength 550nm and energy 3,000erg / cm ² ,
100% color development at 4,500 erg / cm ² . On the other hand, the cyan dye starts to develop with light having a wavelength of 650 nm and energy of 4,000 erg / cm ² , and develops 100% at 8,000 erg / cm ² . In order to produce black color in multi-gradation expression, it is necessary to develop 100% of all colors, so 450 nm light is 7,000 erg / cm ² , 550 nm.
Light of 4,500 erg / cm ² , and light of 650 nm needs to be 8,000 erg / cm ² . Considering the case of applying light with a color cathode ray tube CRT, if the radiant energy of 450 nm light, 550 nm light, and 650 nm light is all equal, the ratio of the exposure time is 7: 4.
5: 8.

[Problems to be Solved by the Invention] However, in the configuration in which the exposure time for each color is adjusted, there is a problem in that the exposure cannot be finished at the same time, and the exposure requires a troublesome labor. In order to obtain an image of multicolor gradation, the exposure time ratio itself must be adjusted. For example, in a photosensitive paper OS having the characteristics shown in FIG. 14, in order to obtain a black color, yellow 7,000 erg / cm ² , magenta 4,500 erg / cm ² , and cyan 8,000 erg / cm ² are required, and the ratio is It will be 7: 4.5: 8. Therefore, in order to make the exposure time for each color component the same and to simultaneously expose all three colors at the same time, the amplification degree of each circuit CY, CM, CC (resultingly, the brightness of the cathode ray tube CRT) is set in advance. It must be adjusted for each ingredient.

Moreover, since the energy for starting color development differs for each color component, it is only possible to deal with a specific color by adjusting the adjustment resistors RTY, RTM, RTC of each circuit and simply changing the amplification degree. That is, if the radiant energy ratio is adjusted so that white is correctly obtained, the color balance in the case of black is lost, and if the amplification degree is adjusted to match black, white cannot be obtained. These problems also occur when trying to represent an arbitrary color. Therefore, the exposure of each dye component of the photosensitive paper OS cannot be completed at the same time regardless of the color of the image, and it is extremely troublesome to adjust the exposure time of each color in order to accurately reproduce the color of the original image. It costs. Therefore,
A pre-exposure method has also been proposed in which the light energy required to start color development is applied to the photosensitive paper OS in advance, but since the process is required prior to the exposure, the problem that the entire exposure time becomes long or the process becomes complicated Will be newly invited.

An image exposure apparatus of the present invention has an object to solve such a problem and easily reproduce a multi-tone / multi-color image.

Structure of the Invention [Means for Solving the Problems] The image exposure apparatus of the present invention exposes a photosensitive paper on which at least two kinds of microcapsules in which color-forming components are encapsulated and which are softened or cured by light are carried on the surface. An image exposure apparatus for forming a multicolor image on the photosensitive paper by applying an irradiation light having energy corresponding to the input signal based on the input signal input for each color corresponding to the color forming component. An exposure unit that forms an optical image for each color according to the color-forming component and exposes the photosensitive paper with the optical image, and an intensity for each color according to the color-forming component that is generated based on the color of the original image. Each intensity signal is input based on the relationship between the energy of the irradiating light that irradiates the photosensitive paper that has a characteristic different for each color forming component and the ratio of the color forming component to color by the irradiation light. And a color-specific exposure amount signal conversion means for converting each of the color development components to correspond to the energy range of the irradiation light from the start of color development to the full color development, and inputting to the exposure means. That is the summary.

[Operation] In the image exposure apparatus of the present invention having the above-described configuration, the photosensitive paper on which at least two types of microcapsules in which the color-forming component is encapsulated and which is softened or hardened by light is carried on the surface is exposed to expose the photosensitive paper. To form a multicolor image.

At this time, the color-specific exposure amount signal converting means inputs the intensity signal for each color corresponding to the color-forming component generated based on the color of the original image, and irradiates the photosensitive paper having different characteristics for each color-forming component. Based on the relationship between the energy of the irradiation light and the ratio of the coloring component to be colored by the irradiation light, each intensity signal corresponds to the energy range of the irradiation light from when the coloring component starts coloring to when the coloring component is completely colored. Then, the exposure means forms an optical image for each color corresponding to the color-forming component by the irradiation light having energy corresponding to the converted intensity signal, based on the converted intensity signal. The photosensitive paper is exposed by the image.

Example Next, an example of the present invention will be described. As a first embodiment of the present invention, the image exposure apparatus converts the intensity signal for each color by a discrete circuit. FIG. 1 is a schematic configuration diagram of the image exposure apparatus of this embodiment. This device is a device that reproduces an image by using a photosensitive paper carrying a light-softening type microcapsule encapsulating a coloring component on its surface, and as shown in the figure, outputs an intensity signal forming an image for each color. Controller 1, drive circuits 2, 3 and 4 for yellow, magenta and cyan colors to which the intensity signals are input, and drive circuits 2, 3 and 4
Color cathode ray tube driven by (hereinafter color CRT
It is called 11). The color CRT 11 is provided with electron guns 12, 13, 14 for each color.

The control device 1 is a circuit that color-separates an original image into yellow, magenta, and cyan, and generates and outputs an intensity signal for each color. The drive circuits 2, 3 and 4 are circuits that convert the intensity signals for each color of yellow, magenta and cyan, and have the same basic configuration. Therefore, the configuration and function of the drive circuit 2 will be described first.

The drive circuit 2 is configured with the external resistors R1 and R2 to perform non-inverting amplification, the operation capacitor OP, the coupling capacitor C, and the resistors R4, R5, and R6 as a cathode drive circuit. Transistors Tr
1, Tr2, Tr3 and eight diodes D1 or 8 connected in series that determine the DC component of the input signal of the cathode drive circuit
It is composed of D8 and a backflow prevention diode D9.
The amplification degree of the circuit centering on the operational amplifier OP as the preamplifier is twice, and the amplification degree of the cathode drive circuit corresponding to the latter stage is -20 times.

Next, the function of this circuit will be described. Control device 1
The intensity signal SY for yellow from is a 1-2V signal,
It is output that the yellow density is 0 [%] at 1V and the yellow density is 100 [%] at 2V.

This intensity signal is non-inverted and amplified by the preamplifier by a factor of 2, and then input to the cathode drive circuit AC-coupled by the coupling capacitor C. An input voltage (base of the transistor Tr1) of the cathode drive circuit is given an offset voltage corresponding to the forward voltage decrease by the diodes D1 to D8, and the input voltage is 2V (= 2 ×) with respect to the offset potential. Only (2-1)) changes.

The current amplification factors of the transistors Tr1 to Tr3 of the cathode drive circuit and the values of the resistors R4 to R6 are designed so that the amplification degree of the entire cathode drive circuit is -20 times.
Therefore, with respect to the yellow intensity signal SY, the output voltage (cathode potential) of the drive circuit 2 changes in the range of 100-60V as shown by the solid line in FIG. As a result, the radiant energy varies in the range of 5,000-7,000 erg / cm ² . This is because the relationship between the cathode potential and the radiant energy has a good linearity as shown in FIG.

On the other hand, the drive circuit 3 for magenta has the same configuration as that of the drive circuit 2 for yellow, except that the amplification degree of the preamplifier is 1.5 and the offset voltage of the cathode drive circuit is different. Have. Therefore, the cathode potential for the magenta intensity signal (1-2 V) is (140-110 V) as shown by the alternate long and short dash line in FIG. As a result, the radiant energy varies between 3,000 and 4,500 erg / cm ² .

Further, in the cyan drive circuit 4, the amplification degree of the preamplifier is 4 and the offset voltage is different. Therefore, the cathode potential for the cyan intensity signal (1-2V) is the second
As shown by the broken line in the figure, it becomes 120-40V. As a result, the radiant energy varies between 4,000 and 8,000 erg / cm ² .

According to the image exposure apparatus of the present embodiment having the above configuration, when each intensity signal changes between 1-2 V for each color component of yellow, magenta, and cyan, the minimum radiation that does not cause each color component to develop 100 color components from energy (yellow 5,000, magenta 3,000, cyan 4,000erg / cm ² )
[%] Maximum radiant energy to develop color (Yellow 7,000,
Radiant energy can be changed linearly up to magenta 4,500, cyan 8,000erg / cm ² ).

For example, as shown in FIGS. 4 (A), (B), and (C), when the intensity signal changes to 1V or 2V between times T1 and T5, FIG. 5 (A), (B) , (C), the cathode voltage of the electron gun 12 corresponding to yellow is 100V.
Alternatively, the cathode voltage of the electron gun 13 corresponding to 60 V, magenta is 140 V or 110 V, and the electron gun corresponding to cyan is 140 V.
The cathode voltage of 14 changes to 120V or 40V, respectively. Therefore, the ratio of color development is correctly proportional to the magnitude of the intensity signal, and the image is reproduced with the same gradation and chromaticity as the original image.

Further, in this embodiment, the corresponding electron guns 12, 13 and 14 are driven according to the exposure characteristics of the dyes on the photosensitive paper, so that the exposure of the dyes on the photosensitive paper is completed at the same time within a certain fixed time. can do.

Incidentally, in this embodiment, as shown in FIG. 6, the cathode tube can be of a three-tube type. At this time, each cathode tube 22,2
3, 24 work independently to emit light energy corresponding to the dye on the photosensitive paper 30 and expose the image on the photosensitive paper 30.

Next, a second embodiment of the present invention will be described. The image exposure apparatus of the second embodiment changes the characteristics of the electron gun,
It emits light energy according to the characteristics of the photosensitive paper. The change rate of the energy of each dye is performed by changing the flow of electrons emitted from the electron gun in the cathode tube according to the characteristics of the photosensitive paper.

That is, in the cathode ray tube shown in FIG. 7, the amount of electron flow is determined by the relationship between the bias voltage, which is the difference between the grid voltage and the cathode voltage, and the anode current, as shown in FIG. Furthermore, by increasing the second grid voltage, the anode current of the cathode ray tube can be increased. By changing the rate of change of the anode current with respect to the bias voltage in this manner, it is possible to emit the energy of the intermediate color between the maximum energy and the minimum energy of the above-described light energy for coloring that matches the corresponding dye. Further, in order to change the electron emission energy, the first shown in FIG.
A configuration may be adopted in which the size D of the holes through which the electrons of the grid pass is changed.

In this way, the image exposure apparatus of this embodiment can emit light energy according to the characteristics of the microcapsules of each color carried on the surface of the photosensitive paper, similarly to the first embodiment, and the photosensitive paper is exposed appropriately. can do. Moreover, when the characteristics of the photosensitive paper are fixed, the electronic circuits can have the same configuration, and the versatility and compatibility of the circuits can be improved.

Next, a third embodiment of the present invention will be described. The image exposure apparatus of the third embodiment uses a photosensitive paper carrying photo-curable microcapsules and exposes it using a CRT as in the first embodiment.

As shown in FIG. 10, the image exposure apparatus includes an electronic control unit 50, an image scanner 53 that reads an original image written on an original 52, a color cathode ray tube (hereinafter, referred to as color CRT) 55, and an exposure. And a developing unit 60 for developing the photosensitive paper 57 under pressure. Color CRT55 has the first
Similar to the embodiment, electron guns 62, 63, 64 for each color are provided.

The electronic control unit 50 is a well-known CPU 71, ROM 72, RAM 73, timer
The input port 76, the CRT controller (CRTC) 78, and the scanning circuit 80 connected to the CRTC 78 are connected to each other via the bus 75.
Drive circuits 82, 83, 84 are provided.

The input port 76 is connected to the image scanner 53, receives a command from the CPU 71, and receives the image scanner 5
The image data read by 5 is input and expanded in a predetermined area of the RAM 73. The image data includes gradation information of 256 levels for each color, but is expanded into normalized data from a value 0 (lowest density) to a value 1 (highest density) corresponding to the density. . On the other hand, the CRTC 78 is a circuit that controls the color CRT 55, controls the voltage applied to the deflection coil 85 of the color CRT 55 via the scanning circuit 80, and controls the electron guns 62 to 62 of each color via the drive circuits 82 to 84. Drive 64. As a result, a high voltage is applied to the electron guns 62 to 64 for each color based on the image of each color developed in the RAM 73, and the photosensitive paper 57 is exposed. The photosensitive paper 57 has a surface on which a microcapsule which is a photo-curing type and internally encapsulates a dye precursor of each color, and a developer which reacts with the dye precursor and develops a color. . Therefore, after exposure, by performing pressure development by the developing unit 60, the dye precursor leaked from the uncured microcapsules reacts with the color developer, and an image is revealed.

Next, the exposure control routine executed by the electronic control unit 50 will be described with reference to the flowchart shown in FIG. When the electronic control unit 50 starts this routine,
First, an image is input from the image scanner 53 through the input port 76 (step S100), and the image is input to the yellow, magenta,
The image data obtained by decomposing it into the three primary colors of cyan
Perform processing to expand to a prescribed area of RAM73 (step S
110).

When all the images written on the original 52 have been input, the time required for exposure is set in the timer 74 (step S12).
0), scanning of the color CRT 55 is started via the scanning circuit 80 (step S130). After that, each image data of the three primary colors is sequentially read according to the scanning direction (step S140), the offset of the color development start level is given to the data, and the process of calculating the signal intensity corresponding to the emission energy according to the gradation is performed ( Step S150).

FIG. 12 is a graph showing the relationship between the exposure amounts of the three primary colors of the photosensitive paper 57 and the color density in this example. As shown in the figure, the exposure amount corresponding to the range of 100 [%] to 0 [%] of the color density used for gradation expression on the characteristic of each microcapsule of the photosensitive paper 57 is as follows.
Different for each of the three primary colors. To give an offset,
Substituting the image data (values normalized from 0 to 1 corresponding to gradation) Dy, Dm, Dc of each color read in step S140 into the following equations (1), (2), (3) , Exposure Ey, Em, Ec
This is equivalent to adding LogEY1, LogEM1, and LogEC1 in the process of obtaining.

LogEy = (LogEY2-LogEY1) (1-Dy) + LogEY1 (1) LogEm = (LogEM2-LogEM1) (1-Dm) + LogEM1 ... (2) LogEc = (LogEC2-LogEC1) (1-Dc) + LogEC1 ... (3) Therefore, even when the color density is 1 (100 [%] color), that is, when the microcapsules do not need to be photocured (as a result, black is obtained), the exposure amounts are EY1, EM1, and EC1. The offset value given in this way must be accurately adjusted in order to accurately reproduce the intermediate gradation + intermediate color,
In this embodiment, this is done with black as the reference. That is, the completely black original is exposed and reproduced, and the offset value is adjusted until the reflectance thereof slightly exceeds zero.
If you do not use white as a reference, it is difficult to obtain perfect white,
This is because the adjustment may be deviated depending on the color when the original 52 is used.

In this way, after obtaining the exposure amount, that is, the light emission intensity, the color CRT 55 is driven through the drive circuits 82 to 84 based on this light emission intensity.
The electron guns 62 to 64 for the respective colors are driven (step S16
0).

Reading of the image data described above (step S140), calculation of emission intensity (step S150), driving of the electron gun (step S1)
60) is repeated until the exposure time elapses (step S17
0), when the exposure time set in advance in the timer 74 is completed, the scanning of the color CRT 55 is finished (step S180),
Exit to "END" to end this control routine.

As described above, according to the exposure control apparatus of the present embodiment, the gradation of the original image read by the image scanner 53 can be reproduced in full color by using the photocurable photosensitive paper 57. In this case, the exposure amount required for the microcapsules carried on the surface of the photosensitive paper 57 to start polymerization, that is, the exposure amounts EY1, EM1, EC1 shown in FIG.
No need for pre-exposure, only one exposure process is required, and the exposure of each color is completed at the same time. As a result, the exposure work is simplified.

Although several embodiments of the present invention have been described above,
The present invention is not limited to these examples, and may be implemented in various modes without departing from the gist of the present invention, such as a configuration using a plasma display instead of a color CRT as an exposure unit. Of course.

EFFECTS OF THE INVENTION The image exposure apparatus of the present invention described in detail above converts the intensity signal based on the relationship between the energy of the irradiation light and the ratio of the color-developing component to the color. Accordingly, the color development can be performed at a rate of 0 to 100%, and the relationship between the intensity signal and the rate at which the color development component develops the color can be the same.

As a result, the photosensitive paper can be exposed with a desired exposure amount, and by extension, the gradation and the color tone of the image reproduced on the photosensitive paper by the exposure can be controlled with a high degree of freedom.

That is, by setting all the intensity signals to the maximum amplitude or the minimum amplitude, when the color balance of either black or white is adjusted, the effect that the color balance on the non-adjusted side is not disturbed, and the color development is prevented. Even when a plurality of color-forming components having different starting energies are used for the photosensitive paper, various excellent effects such as exposure can be performed for a fixed exposure time without performing pre-exposure can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of an image exposure apparatus according to a first embodiment of the present invention, FIG. 2 is a graph showing a relationship between cathode potential and radiant energy according to an input intensity signal, and FIG. 3 is a cathode potential and radiation of a color CRT. Fig. 4 is a graph showing the relationship with energy, Fig. 4 is a graph showing an example of the intensity signal for each color on the input side, Fig. 5 is a graph showing the cathode potential on the output side corresponding to this, Fig. 6 is the first embodiment. An overall view showing a modified example of the example, FIG. 7 is a schematic view showing the constitution of the cathode ray tube in the second embodiment, FIG. 8 is a graph showing the relationship between the anode current and the bias voltage, and FIG. 9 is a constitution of the grid. FIG. 10 is a schematic diagram showing the third embodiment of the present invention, and FIG.
FIG. 11 is a flow chart showing the same exposure control routine, FIG. 12 is a graph showing the characteristics of the photosensitive paper in the third embodiment, FIG. 13 is a block diagram showing the configuration of a conventional image exposure apparatus, and FIG. It is explanatory drawing which shows an example of the characteristic of paper. 1 ... Control device, 2,3,4 ... Driving circuit 11,22,23,24,55 ... Color CRT 12,13,14,62,63,64 ... Electron gun 50 ... Electronic control device, 53 …… Image scanner

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Claims (1)

(57) [Claims] 1. An image for forming a multicolor image on a photosensitive paper by exposing a photosensitive paper on which at least two kinds of microcapsules, in which a coloring component is encapsulated and which is softened or cured by light, are carried. An exposure apparatus, based on an input signal input for each color corresponding to the color forming component, to form an optical image for each color corresponding to the color forming component by irradiation light having energy corresponding to the input signal, An exposure unit that exposes the photosensitive paper with the optical image, and an intensity signal for each color corresponding to the color-forming component generated based on the color of the original image are input, and the characteristics that are different for each color-forming component are obtained. Based on the relationship between the energy of the irradiation light with which the photosensitive paper is irradiated and the ratio of the color-forming component to be colored by the irradiation light, each of the intensity signals is generated until the color-forming component starts to color completely. Image exposure apparatus and a Color exposure signal conversion means each convert to be input to the exposure unit so as to correspond to the energy range of the irradiation light.