JP3673652B2 - Image reading apparatus, image reading method, and storage medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image reading apparatus that reads an image of a transparent original (also referred to as a transparent original) such as a developed photographic film or an opaque film original.
[0002]
[Prior art]
The configuration of a conventional film scanner will be described with reference to FIGS.
[0003]
18 is a perspective view of a main part of a conventional example of a film scanner, FIG. 19 is a schematic configuration diagram of the film scanner shown in FIG. 18, and FIG. 20 is a block diagram showing a circuit configuration of the film scanner shown in FIG.
[0004]
In the figure, 101 is a film carriage used as a document table, and 102 is a developed film, which is fixed on the film carriage 101. 103 is a lamp serving as a light source, 104 is a mirror, 105 is a lens, and 106 is a line sensor composed of a CCD or the like. Light from the lamp 103 passes through the film 102 and is reflected by the mirror 104 and is reflected by the lens 105. An image is formed on 106.
[0005]
Reference numeral 107 denotes a motor for moving the film carriage 101 in the scanning direction (arrow direction in FIGS. 18 and 19), 108 denotes a sensor for detecting the position of the film carriage 101, and 109 denotes the lamp 103 to the line sensor 106. , 110 is a control circuit, 111 is a lens holder for holding the lens 105, 112 is an outer case of the film scanner, and 113 is an input / output terminal.
[0006]
The lamp 103, the line sensor 106, the motor 107, the sensor 108, and the input / output terminal 113 are electrically connected to the control circuit 110. As shown in FIG. 20, the control circuit 110 includes a film scanner control circuit, a sensor control circuit, a motor control circuit, an image information processing circuit, a lamp control circuit, a line sensor control circuit, a film density detection circuit, and a motor drive speed determination circuit. It is comprised by.
[0007]
Next, an image information reading method for the film 102 will be described.
[0008]
First, when a command for film reading operation is input from the outside through the input / output terminal 113, the position of the film carriage 101 is detected by the sensor 108 and the sensor control circuit, and this information is transmitted to the film scanner control circuit. Then, in order to make the film carriage 101 stand by at a predetermined standby position, the motor 107 is driven by the motor control circuit to move the film carriage 101 to the standby position. Then, the film density detection circuit detects the density of the film 102 by a known method, and based on this information, the motor driving speed determination circuit determines the driving speed of the motor 107 for scanning. Then, the lamp 103 is turned on by the lamp control circuit, and the scan operation is performed by rotating the motor 107 at the previously determined driving speed. During this scanning, image information is transmitted from the line sensor 106 to the image information processing circuit through the line sensor control circuit. When this scanning operation is completed, the lamp 103 is extinguished by the lamp control circuit, and image information processing is performed by the image information processing circuit. Then, image information is output from the input / output terminal 113, and the film image reading operation of the film scanner is completed.
[0009]
In addition, in recent years, not only scanning with visible light as described above, but also scanning with infrared light in the same manner as described above, dust on the film and film wrinkles are detected, and image information of scanning with visible light is detected. Japanese Patent Publication No. 06-78992 proposes a film scanner that can superimpose and correct detected dust and wrinkles by image processing to provide an image free of dust and wrinkles.
[0010]
[Problems to be solved by the invention]
However, the conventional example has the following problems.
[0011]
The film image is scanned with infrared light to detect dust and film wrinkles on the film, and the dust and wrinkles detected by overlaying the image information from the scan with visible light are corrected by image processing. In order to obtain an image free from the influence of wrinkles, it is necessary to perform scanning with visible light and scanning with infrared light. Therefore, a film scanner capable of obtaining a film image in which dust and wrinkles are corrected requires a much longer scanning time than a conventional film scanner that does not correct dust and wrinkles.
[0012]
The present invention provides an image reading apparatus, an image reading method, and a storage medium that can be obtained under such circumstances, and that can obtain a film image with little influence of dust and wrinkles on the film in a short scanning time. It is for the purpose.
[0013]
[Means for Solving the Problems]
  In order to solve the above problems, in the present invention, an image reading apparatus is configured as described in the following (1) to (8), an image reading method is configured as described in the following (9) to (12), and a storage medium Is configured as follows (13).
  (1) An image reading apparatus that reads image information of a document by relative reciprocation between the document and a licensor,
  Visible and invisible light emitting means; and
  Irradiate the original with the visible light.A rough scan that reads the image information at a low resolution, and the original is irradiated with the visible light at a high resolution.Read the image informationFinesAnd invisible light scanning for reading the image information by irradiating the original with the invisible light.3Scanning means to perform type scanningWhen,
Scan speed determining means for determining the invisible light scan and the scan speed of the fine scan so that the invisible light scan is faster than the fine scan based on image information obtained by the rough scan.And
  Scanning meansReads the image information by irradiating the original with the visible light.An image reading apparatus that performs scanning by one-way relative motion in the reciprocating motion and performs the invisible light scan by relative motion in the other reciprocating motion.
  (2) The image reading apparatus according to (1), wherein an output signal level of the licensor during the invisible light scan is smaller than that during the visible light scan.
  (3) In the image reading apparatus according to (1) or (2), the spectral intensity characteristic of the light emitting means is such that the emission intensity in the invisible light wavelength region is larger than the emission intensity in the visible light wavelength region. .
  (4) In the image reading apparatus according to any one of (1) to (3), the spectral sensitivity characteristic of the line sensor is an image in which the sensitivity in the invisible light wavelength region is greater than the sensitivity in the visible light wavelength region. Reader.
  (5) The image reading apparatus according to any one of (1) to (4), wherein the image reading apparatus has an operation mode in which the invisible light scan is not performed, and the operation mode can be selected.
  (6) The image reading apparatus according to any one of (1) to (5), wherein the invisible light is infrared light.
  (7) The image reading apparatus according to any one of (1) to (6), wherein the original is a film original.
  (8) The image reading apparatus according to any one of (1) to (6), wherein the original is a transparent original.
  (9) An image reading method in an image reading apparatus for reading image information of the original by relative reciprocation between the original and a line sensor,
  A rough scan step of performing a rough scan to irradiate the original with visible light and read the image information at a low resolution;
  Irradiate the original with the visible light.In high resolutionRead the image informationfineScanfineA scanning step;
  Invisible light scanning step of performing invisible light scanning for reading the image information by irradiating the original with invisible lightWhen,
A scan speed determining step for determining the invisible light scan and the scan speed of the fine scan so that the invisible light scan is faster than the fine scan based on image information obtained by the rough scan.And
The image information is read by irradiating the original with the visible light.An image reading method in which scanning is performed by relative movement in one direction of the reciprocating movement, and invisible light scanning is performed by relative movement in the other direction of the reciprocating movement.
  (10) The image reading method according to (9), wherein the invisible light is infrared light.
  (11) The image reading method according to (9) or (10), wherein the original is a film original.
  (12) The image reading method according to (9) or (10), wherein the original is a transparent original.
  (13) A storage medium storing a program for realizing the image reading method according to any one of (9) to (12).
[0029]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to examples of film scanners. The present invention is not limited to the form of a film scanner (film image reading apparatus), but may be similarly implemented in the form of a film image reading method and further in the form of a storage medium storing a program for realizing this method. it can.
[0030]
【Example】
(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS.
[0031]
1 is a perspective view of an essential part of a “film scanner” according to a first embodiment of the present invention, FIG. 2 is a schematic configuration diagram of the film scanner shown in FIG. 1, and FIG. 3 is a circuit of the film scanner shown in FIG. FIG. 4 is a flowchart showing the operation of the film scanner shown in FIG. 1, FIG. 5 is a spectral sensitivity characteristic diagram of the line sensor, and R, G and B in the figure are spectral sensitivity characteristics of visible light ( R, G, and B are spectral sensitivity characteristics of the red, green, and blue light wavelength receiving portions of the line sensor, respectively, and IR is the spectral sensitivity characteristic of infrared light. FIG. 6 is an emission spectrum intensity distribution diagram of the lamp.
[0032]
In the figure, 1 is a film carriage used as a document table, and 2 is a developed film, which is fixed on the film carriage 1. A lamp 3 serves as a light source for visible light and infrared light, and has a light emission characteristic from the visible light wavelength region to the infrared wavelength. 4 is a mirror, 5 is a lens, and 6 is a line sensor composed of a CCD or the like. Light from the lamp 3 is transmitted through the film 2, reflected by the mirror 4, and imaged on the line sensor 6 by the lens 5. . The line sensor 6 has three light receiving regions, an R light receiving portion, a G light receiving portion, and a B light receiving portion, and has sensitivity to light wavelengths of red, green, and blue, respectively. At least one of the G light receiving portion and the B light receiving portion is sensitive to infrared light. Reference numeral 7 denotes a motor for moving the film carriage 1 in the scanning direction (arrow direction in FIGS. 1 and 2), 8 denotes a sensor for detecting the position of the film carriage 1, and 9 denotes the lamp 3 to the line sensor 6. A leading optical axis 10 is a filter for cutting infrared light, and is held on the optical axis 9 so as to freely enter and exit. 11 is a filter motor for moving the filter 10, 12 is a control circuit, 13 is a lens holder for holding the lens 5, 14 is an exterior case of the film scanner, 15 is an input / output terminal, and 16 is for detecting the film density. The density sensor 17 is a filter sensor for detecting the position of the filter 10.
[0033]
The lamp 3, the line sensor 6, the motor 7, the sensor 8, the filter motor 11, the input / output terminal 15, the concentration sensor 16, and the filter sensor 17 are electrically connected to the control circuit 12. As shown in FIG. 3, the control circuit 12 includes a film scanner control circuit, a sensor control circuit, a density sensor control circuit, a filter sensor control circuit, a motor control circuit, a filter motor control circuit, an image information processing circuit, and a lamp control. The circuit includes a circuit, a line sensor control circuit, a film density detection circuit, a motor drive speed determination circuit, and an image information storage circuit.
[0034]
Next, the image information reading method of the film 2 will be described with reference to the flowchart of FIG.
[0035]
First, when a film reading operation command is input from the outside through the input / output terminal 15, the position of the film carriage 1 is detected by the sensor 8 and the sensor control circuit, and this information is transmitted to the film scanner control circuit. Then, in order to make the film carriage 1 stand by at a predetermined standby position, the motor 7 is driven at a predetermined drive speed by the motor control circuit, and the film carriage 1 is moved to the standby position. At the same time, the position of the filter 10 is detected by the filter sensor 17 and the filter sensor control circuit, and this information is transmitted to the film scanner control circuit. In order to retract the filter 10 from the optical axis 9, the filter motor control circuit 11 drives the filter motor 11 to move the filter 10 to the retracted position (see S1, the same applies hereinafter). Then, the density of the film 2 is detected by the density sensor 16 and the film density detection circuit (S2). Based on this information, the driving speed 1 of the motor 7 for scanning with infrared light by the motor driving speed determination circuit. The driving speed 2 of the motor 7 for scanning with visible light is determined (S3). Then, the lamp 3 is turned on by the lamp control circuit (S4), and the motor control circuit rotates the motor 7 in a predetermined direction at the previously determined driving speed 1 to obtain image information of the film 2 by infrared light. The scan operation is performed (S5). During this scan, an output signal (image information) is transmitted from the line sensor 6 to the image information processing circuit through the line sensor control circuit, and the infrared light transmission state, that is, infrared from most other regions on the film 2. By detecting a region on the film 2 where the light transmittance is different from a predetermined value or more, a range of dust and wrinkles on the film 2 is detected (S6). Then, the range information of the dust and the soot is transmitted to and stored in the image information storage circuit (S7). When the scanning operation for obtaining the image information of the film 2 by infrared light, that is, the range information of dust and wrinkles is completed, the motor 7 is reversed at a predetermined speed and the film carriage 1 is moved to the standby position described above. Let At the same time, while the position of the filter 10 is detected by the filter sensor 17 and the filter sensor control circuit, the filter motor 11 is driven by the filter motor control circuit to the position where the light beam centered on the optical axis 9 is covered. Is moved to the cover position (S8). Then, a scanning operation for obtaining image information of the film 2 by visible light is performed by rotating the motor 7 in the same direction as the scanning by infrared light by the motor control circuit at the previously determined driving speed 2 (S9). During this scan, an output signal (image information) is transmitted from the line sensor 6 to the image information processing circuit through the line sensor control circuit.
[0036]
When this scanning operation ends, the lamp 3 is extinguished by the lamp control circuit (S10) and at the same time, the range information of dust and soot is transmitted from the image information storage circuit to the image information processing circuit. Image information processing for correcting the range of dust and wrinkles in the image information is performed. Then, image information is output from the input / output terminal 15 (S11), and the film image reading operation of the film scanner is completed.
[0037]
Here, the above-described scanning with infrared light is for detecting dust and wrinkles on the film 2 by detecting a region where the infrared light transmittance of the film 2 is different from that of other portions. It is not for obtaining high-quality image information like scanning. In other words, scanning with infrared light only needs to detect an area where the infrared light transmittance of the film 2 is different from that of the other part and detect a range of dust and wrinkles. The output signal level of the sensor 6 may be smaller than that during visible light scanning. Further, since the visible light scan is for obtaining high-quality image information as compared with the infrared light scan, the maximum value of the output signal level of the line sensor 6 by the visible light scan is preferably large, and the line sensor 6 has a sufficient exposure amount. The scan speed is set so that Therefore, at the time of infrared light scanning, the exposure amount of the line sensor 6 per unit time in the resolution limit 1 line is lowered to reduce the output signal level, and a region where the infrared light transmittance is different from other parts can be detected. The scanning speed is increased to a certain extent. For this reason, the driving speed 1 is set larger than the driving speed 2, and the infrared light scan is performed in a shorter time than the visible light scan.
[0038]
Further, when the lamp 3 has a lower infrared light emission intensity than the visible light emission intensity, the line sensor 6 is connected to, for example, FIG. 5 (R, G, and B are spectral sensitivity characteristics of visible light, and IR is red). A line sensor having a spectral sensitivity characteristic shown in (external light spectral sensitivity characteristic) and a high sensitivity of infrared light may be used.
[0039]
When the line sensor 6 is less sensitive to infrared light than visible light, a lamp having a large emission intensity of infrared light having an emission spectrum intensity distribution shown in FIG. That's fine.
[0040]
Further, the range information of dust and wrinkles on the film 2 and the image information of the film 2 by visible light are separately output from the output terminal 15, and the film 2 by visible light is connected by an unillustrated device connected to the output terminal 15. Image information processing may be performed to correct the dust or wrinkle range of the image information.
[0041]
In addition, an operation mode is provided in which a scan operation using infrared light, that is, a scan operation for obtaining dust and wrinkle range information is not performed, and only a scan operation for image information of the film 2 using visible light is performed. May be selected. In this way, when scanning a film having almost no dust and wrinkles, or when it is not necessary to correct dust and wrinkles in the output image, image information processing for correcting the dust and wrinkle range of the image information on the film 2 is performed. The effect that the time concerning the image information processing for obtaining the image information of the film 2 by visible light without performing the process can be shortened is obtained.
[0042]
(Second embodiment)
A “film scanner” according to a second embodiment of the present invention will be described with reference to FIGS. 1 to 3 and FIGS.
[0043]
1 to 3 and FIGS. 5 to 6 are the same as those of the first embodiment, and the description thereof is omitted. FIG. 7 is a flowchart showing the operation of the film scanner shown in FIG.
[0044]
Also, since the reference numerals are the same as those in the first embodiment, the description thereof is omitted.
[0045]
This embodiment is a modified embodiment of the first embodiment. In the film scanner having the same configuration as that of the first embodiment, when the film carriage 1 reciprocates with respect to the line sensor 6 by the motor 7, the reciprocating motion is performed. When the hysteresis due to is very small, that is, when an image is to be captured by moving the film carriage 1 in a predetermined direction and moving in the opposite direction, an image obtained by moving both of them (reciprocating and reciprocating) This is an embodiment in the case where information can be easily superimposed.
[0046]
Next, the image information reading method of the film 2 will be described with reference to the flowchart of FIG.
[0047]
First, when a film reading operation command is input from the outside through the input / output terminal 15, the position of the film carriage 1 is detected by the sensor 8 and the sensor control circuit, and this information is transmitted to the film scanner control circuit. Then, in order to make the film carriage 1 stand by at a predetermined standby position, the motor 7 is driven at a predetermined drive speed by the motor control circuit, and the film carriage 1 is moved to the standby position. At the same time, the position of the filter 10 is detected by the filter sensor 17 and the filter sensor control circuit, and this information is transmitted to the film scanner control circuit. Then, in order to retract the filter 10 from the optical axis 9, the filter motor control circuit 11 drives the filter motor 11 to move the filter 10 to the retracted position (S21). Then, the density of the film 2 is detected by the density sensor 16 and the film density detection circuit (S22). Based on this information, the driving speed 1 of the motor 7 for scanning with infrared light by the motor driving speed determination circuit. The driving speed 2 of the motor 7 for scanning with visible light is determined (S23). Then, the lamp 3 is turned on by the lamp control circuit (S24), and the motor control circuit rotates the motor 7 in a predetermined direction at the previously determined driving speed 1 to obtain image information of the film 2 by infrared light. The scan operation is performed (S25). During this scan, an output signal (image information) is transmitted from the line sensor 6 to the image information processing circuit through the line sensor control circuit, and the infrared light transmission state, that is, infrared from most other regions on the film 2. By detecting a region on the film 2 where the light transmittance is different from a predetermined value or more, a range of dust and wrinkles on the film 2 is detected (S26). Then, the range information of the dust and the soot is transmitted to and stored in the image information storage circuit (S27). When the scanning operation for obtaining the image information of the film 2 by infrared light, that is, the range information of dust and wrinkles is completed, the optical axis is detected while the position of the filter 10 is detected by the filter sensor 17 and the filter sensor control circuit. The filter motor control circuit 11 drives the filter motor 11 to a position covering the luminous flux centered at 9 and moves the filter 10 to the cover position (S28). Then, the scanning operation for obtaining the image information of the film 2 by visible light is performed by rotating the motor 7 in the reverse direction by the motor control circuit at the previously determined driving speed 2 (S29). During this scan, an output signal (image information) is transmitted from the line sensor 6 to the image information processing circuit through the line sensor control circuit.
[0048]
When this scanning operation ends, the lamp 3 is extinguished by the lamp control circuit and at the same time the range information of dust and soot is transmitted from the image information storage circuit to the image information processing circuit, where the image information of the film 2 by visible light is transmitted. Image information processing for correcting the range of dust and wrinkles is performed (S30). Then, image information is output from the input / output terminal 15 (S31), and the film image reading operation of the film scanner is completed.
[0049]
Here, as in the first embodiment, scanning with infrared light only needs to detect a region where the infrared light transmittance of the film 2 is different from that of other portions and detect a range of dust and soot. If it can be detected, the output signal level of the line sensor 6 at the time of infrared light scanning may be smaller than that at the time of visible light scanning. Further, since the visible light scan is for obtaining high-quality image information as compared with the infrared light scan, the maximum value of the output signal level of the line sensor 6 by the visible light scan is preferably large, and the line sensor 6 has a sufficient exposure amount. The scan speed is set so that Therefore, at the time of infrared light scanning, the exposure amount of the line sensor 6 per unit time in the resolution limit 1 line is lowered to reduce the output signal level, and an area where the infrared light transmittance is different from other parts can be detected. The scan speed is increased. For this reason, the driving speed 1 is set larger than the driving speed 2, and the infrared light scanning is performed in a shorter time than the visible light scanning.
[0050]
Further, when the lamp 3 has a lower infrared light emission intensity than the visible light emission intensity, the line sensor 6 is connected to, for example, FIG. 5 (R, G, and B are spectral sensitivity characteristics of visible light, and IR is red). A line sensor having a spectral sensitivity characteristic shown in (external light spectral sensitivity characteristic) and a high sensitivity of infrared light may be used.
[0051]
When the line sensor 6 has a lower infrared light sensitivity than the visible light sensitivity, a lamp having a high emission intensity of infrared light having an emission spectrum intensity distribution shown in FIG. That's fine.
[0052]
Further, the range information of dust and wrinkles on the film 2 and the image information of the film 2 by visible light are separately output from the output terminal 15, and the film 2 by visible light is connected by an unillustrated device connected to the output terminal 15. Image information processing may be performed to correct the dust or wrinkle range of the image information.
[0053]
In addition, an operation mode is provided in which a scan operation using infrared light, that is, a scan operation for obtaining dust and wrinkle range information is not performed, and only a scan operation for image information of the film 2 using visible light is performed. May be selected. In this way, when scanning a film having almost no dust and wrinkles, or when it is not necessary to correct dust and wrinkles in the output image, image information processing for correcting the dust and wrinkle range of the image information on the film 2 is performed. The effect that the time concerning the image information processing for obtaining the image information of the film 2 by visible light without performing the process can be shortened is obtained.
[0054]
(Third embodiment)
A third embodiment of the present invention will be described with reference to FIGS.
[0055]
FIG. 8 is a perspective view of an essential part of the film scanner of the third embodiment, FIG. 9 is a schematic configuration diagram of the film scanner shown in FIG. 8, and FIG. 10 is a block diagram showing a circuit configuration of the film scanner shown in FIG. 11 is a flowchart showing the operation of the film scanner shown in FIG. 8, FIG. 12 is a spectral transmission characteristic diagram of a physical property element used in this embodiment in a visible light and infrared light transmission state, and FIG. 13 is in this embodiment. It is a spectral transmission characteristic figure of the infrared-light impervious state of the physical property element used for this.
[0056]
In the figure, 31 is a film carriage used as a document table, and 32 is a developed film, which is fixed on the film carriage 31. Reference numeral 33 denotes a lamp serving as a light source for visible light and infrared light, and has a light emission characteristic from a visible light wavelength region to an infrared wavelength. Reference numeral 34 denotes a mirror, reference numeral 35 denotes a lens, and reference numeral 36 denotes a line sensor composed of a CCD or the like. Light from the lamp 33 passes through the film 32, is reflected by the mirror 34, and forms an image on the line sensor 36. . The line sensor 36 has three light receiving regions, an R light receiving portion, a G light receiving portion, and a B light receiving portion, and is sensitive to light wavelengths of red (R), green (G), and blue (B), respectively. In addition, at least one of the R light receiving portion, the G light receiving portion, and the B light receiving portion is sensitive to infrared light (IR). 37 is a motor for moving the film carriage 31 in the scanning direction (arrow direction in FIGS. 8 and 9), 38 is a sensor for detecting the position of the film carriage 31, and 39 is from the lamp 33 to the line sensor 36. The optical axis 40 is a physical element such as electrochromy (EC) that can electrically control the transmittance of visible light and infrared light. 41 is a control circuit, 42 is a lens holder for holding the lens 35, 43 is an outer case of the film scanner, and 44 is an input / output terminal.
[0057]
The lamp 33, the line sensor 36, the motor 37, the sensor 38, the physical property element 40, and the input / output terminal 44 are electrically connected to the control circuit 41. As shown in FIG. 8, the control circuit 41 includes a film scanner control circuit, a sensor control circuit, a physical element control circuit, a motor control circuit, an image information processing circuit, a lamp control circuit, a line sensor control circuit, and a film density detection circuit. , A motor drive speed determination circuit, and an image information storage circuit.
[0058]
Next, the image information reading method of the film 32 will be described with reference to the flowchart of FIG.
[0059]
First, when a film reading operation command is input from the outside through the input / output terminal 44, the position of the film carriage 31 is detected by the sensor 38 and the sensor control circuit, and this information is transmitted to the film scanner control circuit. Then, in order to make the film carriage 31 stand by at a predetermined standby position, the motor 37 is driven at a predetermined drive speed by the motor control circuit to move the film carriage 31 to the standby position. At the same time, the spectral transmission characteristic of the physical element 40 is changed to a visible light and infrared light transmission state as shown in FIG. 12 by the physical element control circuit (S41). Then, the lamp control circuit turns on the lamp 3 (S42), and the motor control circuit rotates the motor 37 in a predetermined direction at a predetermined speed in order to scan the image range of the film 32 in the film surface direction at a predetermined speed. Then, a rough scan operation for obtaining image information of the film 32 by visible light and infrared light is performed (S43). During this rough scan, an output signal (image information) is transmitted from the line sensor 36 to the image information processing circuit through the line sensor control circuit, and based on this information, the visible light and infrared light of the film 32 are detected by the film density detection circuit. Light transmittance, that is, film density is detected (S44). When the film carriage 31 is returned to its standby position and the rough scan operation is completed, the motor drive speed determination circuit uses infrared light so that an image with an appropriate amount of light can be obtained based on the detected film density of the entire film. A driving speed 1 of the motor 37 for performing scanning and a driving speed 2 of the motor 37 for performing fine scanning with visible light are determined (S45). Then, in order to scan the video range of the film 32 in the film surface direction, the motor 37 is rotated in a predetermined direction at the driving speed 1 previously determined by the motor control circuit to obtain image information of the film 32 by infrared light. The scanning operation is performed (S46). During this scan, an output signal (image information) is transmitted from the line sensor 36 to the image information processing circuit through the line sensor control circuit, and the infrared light transmission state, that is, infrared from most other regions on the film 32. By detecting an area on the film 32 where the light transmittance is different from a predetermined value or more, a range of dust and wrinkles on the film 32 is detected (S47). Then, the range information of the dust and soot is transmitted to the image information storage circuit and stored (S48). When the scanning operation for obtaining the image information of the film 32 by infrared light, that is, the scanning operation for obtaining the range information of dust and wrinkles is completed, the spectral transmission characteristics of the physical element 40 are shown in FIG. Infrared light opaque state as shown in FIG. Then, a fine scan operation is performed by reversing the motor 37 by the motor control circuit at the previously determined drive speed 2 (S50). During the fine scan, an output signal (image information) is transmitted from the line sensor 36 to the image information processing circuit through the line sensor control circuit. Then, the image reading operation for fine scanning is finished, the motor 37 is rotated by the motor control circuit at a predetermined driving speed, the film carriage 31 is returned to its standby position (S51), and the lamp control circuit is finished when the fine scanning operation is finished. As a result, the lamp 33 is extinguished, and at the same time, the range information of dust and soot is transferred from the image information storage circuit to the image information processing circuit. The image information processing for correcting is performed (S52). Then, image information is output from the input / output terminal 44 (S53), and the film image reading operation of the film scanner is completed.
[0060]
Here, as in the first embodiment, scanning with infrared light only needs to detect a region where the infrared light transmittance of the film 2 is different from that of other portions and detect a range of dust and soot. If it can be detected, the output signal level of the line sensor 6 at the time of infrared light scanning may be smaller than that at the time of fine scanning by visible light. Further, since the fine scan is for obtaining high-quality image information as compared with the infrared light scan, the maximum value of the output signal level of the line sensor 6 by the visible light scan is preferably large, and the line sensor 6 has a sufficient exposure amount. The scan speed that can be obtained is set. Therefore, at the time of infrared light scanning, the exposure amount of the line sensor 6 per unit time in the resolution limit 1 line is lowered to reduce the output signal level, and an area where the infrared light transmittance is different from other parts can be detected. The scan speed is increased. For this reason, the driving speed 1 is set larger than the driving speed 2, and the infrared light scan is performed in a shorter time than the visible light scan.
[0061]
Further, when the lamp 3 has a lower infrared light emission intensity than the visible light emission intensity, the line sensor 6 is connected to, for example, FIG. 5 (R, G, and B are spectral sensitivity characteristics of visible light, and IR is red). A line sensor having a spectral sensitivity characteristic shown in (external light spectral sensitivity characteristic) and a high sensitivity of infrared light may be used.
[0062]
When the line sensor 36 has a lower infrared light sensitivity than the visible light sensitivity, a lamp having a high emission intensity of infrared light having an emission spectrum intensity distribution shown in FIG. That's fine.
[0063]
Further, the range information of dust and wrinkles on the film 32 and the image information of the film 32 by visible light are separately output from the output terminal 44, and the film 32 by visible light is connected by an unillustrated device connected to the output terminal 44. Image information processing may be performed to correct the dust or wrinkle range of the image information.
[0064]
Further, the scanning operation for obtaining image information of the film 32 by infrared light may be performed by the reciprocating operation of the film carriage 31 during the rough scanning operation, without performing the reciprocating operation of the film carriage 31 during the fine scanning operation. . At this time, after the rough scan operation, a scan operation for obtaining image information of the film 32 by infrared light is performed.
[0065]
In addition, an operation mode may be provided in which only a scan operation for image information of the film 32 by visible light is performed without performing a scan operation by infrared light, and this operation mode can be selected. In this way, when scanning a film having almost no dust and wrinkles, or when it is not necessary to correct dust and wrinkles in the output image, image information processing for correcting the dust and wrinkle range of the image information on the film 32 is performed. The effect that the time concerning the image information processing for obtaining the image information of the film 32 by visible light without performing this can be shortened is obtained.
[0066]
(Modification of the first to third embodiments)
Next, as a modification of the first to third embodiments, a modified embodiment in the case of reading image information of a photographic film will be described with reference to FIGS.
[0067]
14 is a spectral transmission characteristic diagram of an overexposed negative film, FIG. 15 is a spectral transmission characteristic diagram of an underexposed negative film, and FIG. 16 is an explanatory diagram of a spectral transmission characteristic of an overexposed positive film. FIG. 17 is a spectral transmission characteristic diagram of a positive film with insufficient exposure.
[0068]
The developed photographic negative film appears to be opaque due to overexposure, that is, the transmittance of infrared light is high as shown in FIG. 14 even when the transmittance of visible light is low. Further, even when the exposure amount is insufficient and it looks transparent, that is, in a state where the visible light transmittance is high, the infrared light transmittance is higher than that as shown in FIG. 15, and the transmittance is excessive. Even if the exposure amount is insufficient, there is almost no change. Similarly, a developed positive film for photographic images appears transparent due to excessive exposure, that is, the transmittance of infrared light is as shown in FIG. 16 even when the transmittance of visible light is high. More than that. Further, even if it is opaque due to insufficient exposure, that is, even in a state where the transmittance of visible light is low, the transmittance of infrared light is high and the transmittance is excessive as shown in FIG. However, even if the amount of exposure is insufficient, there is almost no change. For this reason, when reading image information of a photographic film, scanning with infrared light may be performed at a predetermined driving speed of a predetermined motor. At this time, it is determined in advance from the driving speed of the motor for performing scanning with visible light determined by the density sensor of the first and second embodiments and the film density detected by the rough scan of the third embodiment. The predetermined driving speed of the motor for performing scanning with infrared light is set larger.
[0069]
As described above, when reading image information on a photographic film, the reading operation time required for the image information reading operation using infrared light is easily made shorter than the reading operation time required for the image information reading operation using visible light. Can do.
[0070]
【The invention's effect】
As described above, according to the present invention, it is possible to obtain an image with less influence of dust and wrinkles on a document.
[Brief description of the drawings]
FIG. 1 is a perspective view of a main part of a film scanner according to a first embodiment.
FIG. 2 is a schematic configuration diagram of the film scanner shown in FIG.
3 is a block diagram showing a circuit configuration of the film scanner shown in FIG.
FIG. 4 is a flowchart showing the operation of the film scanner shown in FIG.
Fig. 5 Spectral sensitivity characteristics of line sensor
FIG. 6 Luminescent spectrum intensity distribution diagram of the lamp
FIG. 7 is a flowchart showing the operation of the second embodiment.
FIG. 8 is a perspective view of main parts of a film scanner according to a third embodiment.
9 is a schematic configuration diagram of the film scanner shown in FIG.
10 is a block diagram showing a circuit configuration of the film scanner shown in FIG.
FIG. 11 is a flowchart showing the operation of the film scanner shown in FIG.
FIG. 12 is a spectral transmission characteristic diagram of a physical property element in a visible light and infrared light transmission state.
FIG. 13 is a spectral transmission characteristic diagram of a physical property element in an infrared light opaque state.
FIG. 14 Spectral transmission characteristics of overexposed negative film
Fig. 15 Spectral transmission characteristics of negative film with insufficient exposure
Fig. 16 Spectral transmission characteristics of over-exposed positive film
Fig. 17 Spectral transmission characteristics of a positive film with insufficient exposure
FIG. 18 is a perspective view of the main part of a conventional film scanner.
FIG. 19 is a schematic configuration diagram of the film scanner shown in FIG.
20 is a block diagram showing a circuit configuration of the film scanner shown in FIG.
[Explanation of symbols]
1 Film carriage
2 film
3 lamps
6 Line sensor

Claims (13)

An image reading device for reading image information of the original by relative reciprocation of the original and the licensor,
Visible and invisible light emitting means; and
A rough scan for reading the image information by irradiating the low resolution the document by the visible light, and a fine scan for reading the image information by irradiating the high resolution the document by the visible light, said by the invisible light Scanning means for performing three types of invisible light scans for reading the image information by irradiating a document ;
Based on image information obtained by the rough scan, the invisible light scan comprises a scan speed determining means for determining the invisible light scan and the scan speed of the fine scan so that the invisible light scan is faster than the fine scan ,
The scanning means performs scanning for reading the image information by irradiating the original with the visible light by the relative movement in one direction of the reciprocating motion, and performing the invisible light scanning by the relative motion in the other direction of the reciprocating motion. An image reading apparatus. 2. The image reading apparatus according to claim 1 , wherein an output signal level of the licensor during the invisible light scan is smaller than that during the visible light scan. 3. The image reading apparatus according to claim 1, wherein the light emission means has a spectral intensity characteristic in which the light emission intensity in the invisible light wavelength region is larger than the light emission intensity in the visible light wavelength region. apparatus. The image reading apparatus according to any one of claims 1 to claim 3, the spectral sensitivity characteristics of the line sensor, characterized in that the larger the sensitivity of the invisible light wavelength region than the sensitivity in the visible light wavelength region Image reading device. The image reading apparatus according to any one of claims 1 to claim 4, having an operation mode that does not perform pre-Symbol invisible light scanning, the image reading apparatus is characterized in that the selectable this mode of operation. The image reading apparatus according to any one of claims 1 to 5, the image reading apparatus, wherein the invisible light is an infrared light. The image reading apparatus according to any one of claims 1 to 6, the image reading apparatus, wherein the original is a film original. The image reading apparatus according to any one of claims 1 to 6, the image reading apparatus, wherein the document is a transparent original. An image reading method in an image reading apparatus that reads image information of the original by relative reciprocation between the original and a line sensor,
A rough scan step of performing a rough scan to irradiate the original with visible light and read the image information at a low resolution;
And fine scan performing a fine scan for reading the image information with high resolution by irradiating the document with the visible light,
An invisible light scanning step of performing an invisible light scan for reading the image information by irradiating the original with invisible light ;
A scan speed determining step for determining the invisible light scan and the scan speed of the fine scan so that the invisible light scan is faster than the fine scan based on image information obtained by the rough scan ,
A scan for irradiating the original with the visible light and reading the image information is performed by a relative motion in one direction of the reciprocating motion, and the invisible light scan is performed by a relative motion in the other direction of the reciprocating motion. Image reading method. The image reading method according to claim 9 , wherein the invisible light is infrared light. The image reading method according to claim 9 or claim 10, an image reading method, wherein said original is a film original. The image reading method according to claim 9 or claim 10, an image reading method, wherein the document is a transparent original. A storage medium storing a program for realizing the image reading method according to any one of claims 9 to 12 .

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