JP2016051946A - Image reading apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image reading apparatus configured to accelerate a processing speed during double-side reading by more effectively matching reading speeds of both sensors without performing such processing as changing an operation clock.SOLUTION: An image reading apparatus 22 includes: a reduction optical system reading part 4; a non-magnification optical reading part 5 of which the reading system is different from that of the reduction optical system reading part 4 and the reading speed is low; a mode switching part; and a horizontal synchronizing signal control part. When images on a first side and a second side are to be read in one process by the reduction optical system reading part 4 and the non-magnification optical system reading part 5, the mode switching part and the horizontal synchronizing signal control part change a phase of a horizontal synchronizing signal of the reduction optical system reading part 4 to be used for reading one scan line for a document into a phase of a horizontal synchronizing signal of the on-magnification optical system reading part 5.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an image reading apparatus, and more particularly to an image reading apparatus capable of reading a double-sided original applied to a facsimile machine, a copying machine, or the like.

  In recent years, information has been recorded on both sides of a sheet in order to save resources. In this way, an original on which information is recorded on both sides has been read one side at a time by one reading means. Then, the usability of the image reading apparatus is impaired.

  In view of this, an image reading apparatus has been proposed in which a close-contact optical image type image sensor is disposed on one side of the document conveyance path and a reduction optical system CCD (Charge Coupled Device) linear image sensor is disposed on the other side. (See Patent Document 1).

  Since the contact image sensor (CIS) does not require a mirror and the reflected light reaches the lens or sensor as it is, the apparatus size can be reduced and the apparatus body can be made smaller. The contact image sensor has almost the same function as a CCD linear image sensor for reading a flat original, but it cannot clearly read characters on an original with unevenness such as the inside of a thick book. On the other hand, the CCD linear image sensor has a configuration in which reflected light is reflected and collected by a mirror and read by the sensor through several lenses, so that the internal structure becomes large and the apparatus main body becomes large. Since the CCD linear image sensor is in focus even when the original is floating to some extent, it can clearly read characters even on an uneven original.

  In addition, an image reading apparatus is proposed that improves the processing speed at the time of double-sided scanning by changing the operation clock of the reading unit, the document conveying speed, and the signal amplification level depending on whether the duplex scanning mode or the single-sided scanning mode. (See Patent Document 2). In this image reading apparatus, at the time of double-sided reading, the operation clock or the like is changed to match the reading speed of the CCD linear image sensor having a high reading speed with the contact type image sensor having a low reading speed, and each image on the front and back sides of the document is displayed. Read in one step.

JP-A-3-240361 Japanese Patent Laid-Open No. 9-46484

  However, in the image reading apparatus described in Patent Document 2, the operation clock (pixel clock) that is changed to match the reading speed is a clock signal that processes data for one pixel at 1 CLK. Therefore, even if the operation clock is slowed down and the reading speed of the CCD linear image sensor is adjusted to the contact type image sensor, it is not very effective in reducing the reading speed when viewed as one whole reading line.

  Therefore, the present invention provides an image reading apparatus configured to improve the processing speed at the time of double-sided reading by matching the reading speeds of both sensors more effectively without performing processing that changes the operation clock. The purpose is to do.

  According to the present invention, in the image reading apparatus, the first reading unit that reads an image of the first surface of the conveyed document by the first reading sensor and the first reading unit are different in a reading method and the reading speed is the first reading unit. A second reading unit that reads an image on the second surface of the conveyed document that is later than the reading unit by a second reading sensor, and the first and second surfaces of the document by the first reading unit and the second reading unit. Control for changing the phase of the horizontal synchronizing signal of the first reading unit used for reading one line of scanning of the original to the phase of the horizontal synchronizing signal of the second reading unit when reading each image of the image in one step. And means.

  According to the present invention, it is possible to realize an image reading apparatus configured to improve the processing speed at the time of double-sided reading by combining the reading speeds of both sensors more effectively without performing processing that changes the operation clock. be able to.

1 is a schematic cross-sectional view illustrating an image forming apparatus including an image reading apparatus according to an embodiment of the present invention. FIG. 2 is an external explanatory view showing an overall structure in a state where a cover is removed from the image reading apparatus in FIG. 1. It is explanatory drawing of the CCD linear image sensor used for the image reading apparatus in FIG. FIG. 3 is an explanatory diagram of a contact image sensor used in the image reading apparatus in FIG. 2. FIG. 2 is a block diagram illustrating a control system of the image reading apparatus in the present embodiment. It is a block diagram which shows an example of a structure of the horizontal synchronizing signal control part in FIG. (A)-(e) is a figure shown about each reading mode of the image reading apparatus in this embodiment, the horizontal synchronizing signal (HSYNC) corresponding to a mode, and a light source current value. 6 is a flowchart illustrating processing of the image reading apparatus according to the present embodiment.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described in detail with reference to the accompanying drawings. The embodiments described below are preferred specific examples of the present invention, and thus various technically preferable limitations are given. However, the scope of the present invention is particularly limited in the following description. Unless otherwise stated, the present invention is not limited to these embodiments.

[Image forming apparatus]
FIG. 1 is a cross-sectional view showing a copying machine, which is an example of an image forming apparatus according to the present embodiment, taken along a sheet conveyance direction. As shown in FIG. 1, an image forming apparatus 40 such as a copying machine has an apparatus main body 40a and an image reading device 22 provided on the upper part of the apparatus main body 40a.

  The image reading device 22 includes an image reading unit 102 and a document conveying unit (ADF) 1 provided on the image reading unit 102. The image reading device 22 reads an image of a sheet-like document D, converts the image into an electric signal, and forms image data based on the electric signal. In the apparatus main body 40a, an image is formed on the sheet Sh based on an electrical signal or image data of the image.

  The document conveying unit 1 is configured to automatically convey the document D before image reading placed on the document feeding tray (sheet stacking unit) 2 by the user or the like to the image reading unit 102. On the document feeding tray 2, documents D from which images are read are placed in a stacked manner. The image reading unit 102 receives reflected light of the light irradiated at the image reading position R on the conveyed document D, optically reads the document D and converts it into an electrical signal, and image data based on the electrical signal. (Image reading information) is created.

  The apparatus main body 40a of the image forming apparatus 40 forms a copy image on the sheet Sh based on the image data. The apparatus main body 40 a operates the exposure unit 123 based on the electrical signal and image data of the image of the document D, and forms an electrostatic latent image on the surface of the rotating photosensitive drum 121. The electrostatic latent image is developed (supplied with toner) by the developing device 124 and becomes a toner image.

  On the other hand, sheet placement units 137a, 137b, 137c, and 137d loaded with sheets Sh of various sizes are disposed below the apparatus main body 40a. The sheets Sh of the sheet placement units 137a to 137d are sent out one by one by the feeding rollers 138a, 138b, 138c, and 138d, and are delivered to the conveying roller 131. The sheet Sh is transferred from the manual feed tray 137e to the feeding roller 138e.

  Thereafter, the sheet Sh is straightly corrected by the registration roller pair 136 and the position thereof is synchronized with the toner image on the photosensitive drum 121, and is supplied between the photosensitive drum 121 and the transfer charger 125. . The sheet Sh is transferred with the toner image on the photosensitive drum by the transfer charger 125 and separated from the photosensitive drum 121 by the separation charger 126. The cleaner 127 cleans the surface of the photosensitive drum 121 to which the toner image is transferred. The charger 122 charges the surface of the photosensitive drum 121 in preparation for the next exposure.

  On the other hand, the sheet Sh to which the toner image is transferred is conveyed to the fixing device 129 by the belt conveying unit 128, and is heated and pressurized by the fixing device 129 to fix the toner image on the surface. Then, the sheet Sh on which the toner image is fixed is discharged to the discharge tray 130.

  The image forming apparatus 40 described above is controlled by the control unit 132 having a CPU provided in the apparatus main body 40a. Further, the image reading device 22 is provided with a reading device control unit 31 that controls the operation of the image reading device 22 in accordance with a command from the control unit 132 on the apparatus main body 40a side. The image forming unit 133 is configured by the photosensitive drum 121, the charger 122, the developing device 124, and the like.

[Original transport section]
Next, the detailed configuration of the image reading apparatus 22 according to the present embodiment will be described with reference to FIG. FIG. 2 is a schematic cross-sectional view of the image reading device 22 according to the present embodiment taken along the document conveyance direction.

  As shown in FIG. 2, the image reading device 22 includes a document transport unit 1 (ADF) that can be opened and closed at a predetermined angle in an upper direction of a main body case 3, and a so-called book type document (book) below the document transport unit 1. A book-type image reading unit 102 capable of reading a document image. The image reading device 22 automatically passes the document D placed on the document feeding tray 2 through the equal-magnification optical system reading unit 5 as the second reading unit, and the image reading position R (see FIG. 1). Is sent to a reduction optical system reading unit 4 serving as a first reading unit arranged in the above.

  The document transport unit 1 includes a document feeding tray 2, a separation unit 25, and a width direction (front-back direction in FIG. 2) perpendicular to the document feeding direction (direction of arrow A) of the document D on which an image is formed. And an automatic document feeder 26 extending in a slender shape along the line. The document transport unit 1 includes a feed roller 24 that feeds the document D on the document feed tray 2, and a separation transport roller pair 44 that separates and transports the document D fed by the feed roller 24 one by one. , A registration roller pair 27, and conveyance roller pairs 28, 29, and 30.

  The document conveying unit 1 is provided below the feeding roller 24 with a conveying roller pair 47, a discharge roller pair 48, an equal magnification optical system reading unit (second reading unit) 5, and a reduction optical system reading unit (first reading unit) 4. And a document discharge tray 50 that receives a document that has been read and sent. Further, a conveyance switching member 49 is disposed between the conveyance roller pair 47 and the discharge roller pair 48.

  The image reading unit 102 includes a main body case 3, an original table glass 6 and a surface shading plate 7 that are arranged side by side so as to be the same level on the upper surface of the main body case 3, and an original table glass 6 in the main body case 3. And a reduction optical system reading unit (first reading unit) 4 disposed below.

[Reduction optical system reading unit (first reading unit)]
Next, details of the reduction optical system reading unit (first reading unit) 4 will be described with reference to FIG. FIG. 3 is an explanatory diagram of the reduction optical system reading unit 4 used in the image reading device 22.

  As shown in FIG. 3, the reduction optical system reading unit (first reading unit) 4 converts an image on the first surface (front surface in the present embodiment) of the document D being conveyed into a CCD linear image sensor (first reading sensor). ) 14. The reduction optical system reading unit 4 includes a first mirror 8, a second mirror 9, a third mirror 10, a fourth mirror 11, a fifth mirror 12, and a lens 13, a CCD linear image sensor (first reading sensor) 14, and a first mirror. One light source (LED) 15a, 15b is provided.

  As the first light sources 15a and 15b, those in which white LEDs are arranged on the array are used. Since the reduction optical system reading unit 4 can read R, G, and B (RED, GREEN, and BLUE) at the same time by using white LEDs for the first light sources 15a and 15b, it reads the same magnification optical system. Reading faster than the unit 5 can be executed. The above-described reduction optical system reading unit 4 uses the first light sources 15a and 15b as white LEDs, uses the plurality of mirrors 8 to 12 and the lens 13, and repeats the reflection and aggregation of the light beam, and then transmits the light from the document D to the optical system. Is guided to a CCD linear image sensor 14 which is an image sensor.

  In such a reduction optical system reading unit 4, when the document D is set on the document table glass 6, the light irradiated to the document D from the first light sources 15 a and 15 b passes through the document table glass 6 and is first on the document surface. Reflected by the mirror 8. Thus, the first mirror 8 reflects incident light to the second mirror 9, the second mirror 9 reflects incident light to the third mirror 10, and the third mirror 10 reflects incident light to the fourth mirror 11. The fourth mirror 11 reflects incident light to the fifth mirror 12. The fifth mirror 12 reflects incident light to the lens 13, and the lens 13 forms an image on the light receiving surface of the CCD linear image sensor (first reading sensor) 14.

[Close-contact type reading unit (second reading unit)]
Next, details of the equal magnification optical system reading unit (second reading unit) 5 will be described with reference to FIG. FIG. 4 is an explanatory diagram of the equal magnification optical system reading unit 5 used in the image reading device 22.

  As shown in FIG. 4, the equal-magnification optical system reading unit 5 is different in reading method from the reduction optical system reading unit 4 and has a reading speed slower than that of the reduction optical system reading unit 4. Then, the equal-magnification optical system reading unit 5 converts the image on the second surface (back surface in the present embodiment) of the document D being conveyed into a light receiving element (second image sensor) (CIS: Contact Image Sensor). (Reading sensor) 21 is configured to read. The equal-magnification optical system reading unit 5 is fixed on the LED light source unit 17, the light guide 18, the SELFOC (registered trademark) lens array 19 (hereinafter simply referred to as “lens array 19”), the substrate 20, and the substrate 20. A light receiving element 21 is provided.

  The light guide 18 reads the light emitted from the LED light source unit 17 and diffuses it uniformly in the main scanning direction. Irradiation light emitted from the light guide 18 is reflected by the document D, and this reflected light is imaged on the light receiving element 21 through the lens array 19. The imaged light is photoelectrically converted by the light receiving element 21 and sequentially output as an image signal.

  The above equal-magnification optical system reading unit 5 uses an LED light source unit 17 having R, G, and B three-color LEDs as a light source. Then, R, G, and B are respectively switched at high speed, and light from the document D is directly guided to the light receiving element 21 that is an image pickup element through the lens array 19.

  The equal-magnification optical system reading unit 5 is arranged in the middle of the document conveyance path from the document feeding tray 2 and reads image information (image) on the second surface of the document D being conveyed along the document conveyance path to obtain an image. Output a signal. The LED light source unit 17 is composed of LEDs (light emitting diodes) of three colors of R, G, and B. Since each LED is switched on and lit, the LED light source unit 17 reads more than the reduction optical system reading unit (first reading unit) 4. Takes a long time (slow reading speed).

  Since the light receiving element 21 of the equal magnification optical system reading unit 5 is formed as a single light receiving element from a plurality of elements, there are variations in sensitivity and AC / DC components between the elements, and if the accumulation time is short, the output image signal Since the variation becomes large, it is necessary to lengthen the accumulation time. For this reason, if control is performed so that the fast reading speed of the reduction optical system reading unit (first reading unit) 4 matches the slow reading speed of the equal magnification optical system reading unit (second reading unit) 5, the light receiving element (second reading unit). The image of the second surface read by the sensor 21 is deteriorated. Therefore, in this embodiment, control is performed so that the slow reading speed of the equal-magnification optical system reading unit 5 matches the high reading speed of the reduction optical system reading unit 4.

[Control system of image reading apparatus]
Next, a control system for controlling the image reading device 22 will be described with reference to FIG. FIG. 5 is a block diagram showing a control system of the image reading apparatus 22 in the present embodiment.

  That is, as shown in FIG. 5, the control system of the image reading device 22 includes a reading device control unit 31. Various setting information selected and input by the operation panel 34 provided in the apparatus main body 40a is input to the reader control unit 31. Settings and copy execution instructions on the operation panel 34 are once transmitted to the control unit 132 of the apparatus main body 40 a and then transmitted to the reading device control unit 31. Therefore, the operation panel 34 functions as an operation unit that performs setting input, reading mode setting, and the like of the image reading device 22.

  The reading device control unit 31 includes a horizontal synchronization signal control unit 36 and a light source current control unit 37, a mode switching unit 39, and a storage unit 38 provided in the CPU 35 as a central processing unit. The reading device control unit 31 is connected with a reduction optical system reading unit (first reading unit) 4 in the image reading unit 102 and an equal magnification optical system reading unit (second reading unit) 5 in the document conveying unit 1. ing. The storage unit 38 can be composed of non-volatile and volatile memories such as RAM (Random Access Memory), ROM (Read Only Memory), HDD (Hard Disk Drive), and flash ROM.

  The mode switching unit 39 uses the reduction optical system reading unit (first reading unit) 4 and the equal magnification optical system reading unit (second reading unit) 5 to process each image on the first surface and the second surface of the document D in one step. The reading mode (double-sided reading mode) can be switched. The mode switching unit 39 is further configured to be able to switch between the first reading mode, the second reading mode, and the third reading mode (double-sided reading mode).

  The horizontal synchronization signal control unit 36 controls the CCD linear image sensor 14 in the reduction optical system reading unit 4 through an AFE (Analog Front End) 42 and receives light in the equal magnification optical system reading unit 5 through an AFE 52. The element 21 is controlled. The horizontal synchronization signal control unit 36 performs control so that the phase of the first horizontal synchronization signal (HSYNC) matches the phase of the second horizontal synchronization signal (HSYNC). The first horizontal synchronization signal (HSYNC) is a reading start trigger to the reduction optical system reading unit 4 for reading one scanning line of the document D in response to switching to the reading mode by the mode switching unit 39. . The second horizontal synchronization signal (HSYNC) is a reading start trigger to the equal magnification optical system reading unit 5.

  The first reading mode is a mode in which the image on the first surface of the document D is read by the reduction optical system reading unit (first reading unit) 4. The second reading mode is a mode in which an image on the second surface of the document D is read by the equal-magnification optical system reading unit (second reading unit) 5. Further, in the third reading mode (double-sided reading mode), after the first surface of the document D is read by the reduction optical system reading unit 4, the document D is reversed and the second surface of the document is read by the reduction optical system reading unit 4. This is the reading mode. In the present embodiment, such various reading modes can be freely switched by the mode switching unit 39 in accordance with the selection input from the operation panel 34.

  The light source current control unit 37 is connected to the light source device 57 in the reduction optical system reading unit 4 of the image reading unit 102 and to the light source device 58 in the equal magnification optical system reading unit 5 of the document conveying unit 1. The light source current control unit 37 controls the CCD linear image sensor 14 of the light source device 57 via the LED driver 45 and controls the LED light source unit 17 of the light source device 58 via the LED driver 55. The storage unit 38 stores various information output from each unit of the image reading device 22.

  The reduction optical system reading unit (first reading unit) 4 includes first light sources 15 a and 15 b that irradiate the image with light when the CCD linear image sensor (first reading sensor) 14 reads the image. The equal-magnification optical system reading unit (second reading unit) 5 includes an LED light source unit 17 that is a second light source that emits light to the image when the light receiving element (second reading sensor) 21 reads the image. ing.

  The reading device control unit 31 reduces the light amounts of the first light sources 15a and 15b in accordance with the reading speed of the reduction optical system reading unit (first reading unit) 4 that has become slow due to the phase change of the first horizontal synchronization signal. To control. Thereby, it is possible to save the current related to the light amount of the first light sources 15a and 15b.

  Next, an example of the circuit configuration of the horizontal synchronization signal control unit 36 in FIG. 5 will be described with reference to FIG. FIG. 6 is a block diagram showing this circuit configuration.

  That is, the horizontal synchronization signal control unit 36 that constitutes a control unit together with the mode switching unit 39 includes a phase synchronization circuit (PLL: Phase Locked Loop) 43 shown in FIG. The phase synchronization circuit 43 includes a phase comparator 63, a loop filter (filter circuit) 64, a variable frequency oscillator (VCO) 65, and a frequency divider 62.

  The phase synchronization circuit 43 converts the phase of the first horizontal synchronization signal (horizontal synchronization signal of the first reading unit) H1 of the reduction optical system reading unit 4 to the second horizontal synchronization signal (second reading of the equal magnification optical system reading unit 5). Horizontal synchronization signal) of the signal H2 'synchronized with the phase of H2. When the reading speed of the reduction optical system reading unit 4 is changed to be equal to the slow reading speed of the equal magnification optical system reading unit 5 by the output of the signal H2 ', the reading device control unit 31 performs the following control. That is, the drive system is controlled so that the conveyance speed when the document D passes through the reduction optical system reading unit 4 is equal to the conveyance speed when the document D passes through the equal-magnification optical system reading unit 5.

  The phase comparator 63 inputs the first horizontal synchronizing signal H1 to one terminal T1, and also inputs the fed back signal S4 to the other terminal T2, and outputs the first horizontal synchronizing signal H1 and the feedback signal S4. The phase difference S1 is output. The loop filter 64 is interposed between the phase comparator 63 and the variable frequency oscillator (VCO) 65, and cuts AC components from the output (phase difference S1) of the phase comparator 63 to remove unnecessary short-cycle fluctuations. The signal S2 of the form is output.

  The variable frequency oscillator (VCO) 65 changes the oscillation frequency based on the output (signal S2) output from the phase comparator 63 and passed through the loop filter 64, and outputs the result. The frequency divider 62 divides the frequency of the output from the variable frequency oscillator 65 and feeds it back to the other terminal T2. In this way, by using the output signal of the variable frequency oscillator 65 divided by the frequency divider 62, the phase of the first horizontal synchronizing signal H1 of the reduction optical system reading unit 4 which is the input signal to the phase comparator 63 is used. Can be changed to generate a signal H ′ having a frequency multiplied by an arbitrary integer.

  The horizontal synchronizing signal control unit 36 and the mode switching unit 39 in the present embodiment constitute a control means. The control means (36, 39) scans the original for one line when reading the images on the first and second surfaces of the document D in one step by the reduction optical system reading unit 4 and the equal magnification optical system reading unit 5. The phase of the first horizontal synchronizing signal H1 used for reading out is changed to the phase of the second horizontal synchronizing signal H2.

  Next, the operation of the image reading device 22 in the present embodiment will be described with reference to FIGS. 7A to 7E are diagrams illustrating each reading mode of the image reading device 22, a horizontal synchronization signal (HSYNC) corresponding to the mode, and a light source current value. FIG. 8 is a flowchart for explaining the processing of the image reading device 22.

  First, when reading an image of a document, the reading device control unit 31 has a reading mode selected by the mode switching unit 39 based on an input from the operation panel 34, and both reading units 4 and 5 read both sides of the document D. It is determined whether or not the reading mode is set (S1001).

  As a result, in the case of the double-sided reading mode, it is further determined whether the double-sided reading mode in which both sides of the document D are simultaneously read (in one step) by the reading units 4 and 5 or the double-sided reading mode in which reading is alternately performed. (S1002). As a result, if double-sided simultaneous reading is selected, the reading device control unit 31 reads the image information of the document in one step using both the reduction optical system reading unit 4 and the equal magnification optical system reading unit 5. (S1003). On the other hand, if the double-sided alternate reading is selected, the reading device control unit 31 conveys the original while inverting it, and reads the first surface and the second surface one by one by the reduction optical system reading unit 4 (S1004). .

  Further, when the reading device control unit 31 determines that the reading mode selected in S1001 is not the double-sided reading mode, it further confirms whether the reading is front side reading or back side reading (S1005). As a result, when the reading device control unit 31 determines that the front side reading is performed, the reading optical control unit 31 performs control so that the reduction optical system reading unit 4 reads (S1006). Control is performed to read (S1007).

  At the time of each reading described above, the relationship between the light source current and the horizontal synchronization signal (HSYNC) in each reading mode is as follows.

  That is, when the single-sided reading mode shown in FIG. 7A is selected and reading is performed by the reduction optical system reading unit (first reading unit) 4, the light source currents of the first light sources 15a and 15b are set to 20 mA, and the horizontal Let t be the period of the synchronization signal H1 (see FIG. 6).

  Further, when the single-sided reading mode shown in FIG. 7B is selected and reading is performed by the equal-magnification optical system reading unit (second reading unit) 5, the light source current of the LED light source unit 17 is set to 25 mA, and equal-magnification optical. The period of the second horizontal synchronizing signal H2 (see FIG. 6) of the system reading unit 5 is 2t. The reason why the horizontal synchronization signal (HSYNC) differs depending on the reading sensor is as described above.

  When the double-sided simultaneous reading mode shown in FIGS. 7C and 7D is selected, the fast reading speed of the reduction optical system reading unit (first reading unit) 4 is set to the same magnification optical system reading unit (first reading unit). It is necessary to match the slow reading speed of (2 reading section) 5. Therefore, the first horizontal synchronizing signal H1 (see FIG. 6) of the reduction optical system reading unit (first reading unit) 4 is set to 2t. At this time, since the first horizontal synchronization signal H1 of the reduction optical system reading unit 4 has doubled, the light from the first light sources 15a and 15b is irradiated onto the document, and the light is emitted from the CCD linear image sensor 14 (see FIG. 3). The time accumulated in is doubled. Double the accumulation time is equivalent to double the amount of light, so the amount of light can be halved. Therefore, the light quantity in the reduction optical system reading unit (first reading unit) 4 can be set to half of 10 mA.

  On the other hand, when the double-sided reverse reading mode shown in FIG. 7E is selected, since the reduction optical system reading unit (first reading unit) 4 reads, the light source currents of the first light sources 15a and 15b are set to 20 mA. Let t be the period of one horizontal synchronizing signal H1.

  The light source current value and the period of the horizontal synchronization signal (HSYNC) described above are merely examples, and are not limited to the above values, and may be changed and set as appropriate.

  In this embodiment, the equal-magnification optical system reading unit (second reading unit) 5 is arranged on the document conveying unit 1 side, and the reduction optical system reading unit (first reading unit) 4 is arranged on the image reading unit 102 side. However, these relationships can be set in reverse. In other words, the reduction optical system reading unit 4 can be arranged on the document conveying unit 1 side, and the equal magnification optical system reading unit 5 can be arranged on the image reading unit 102 side. In this case, substantially the same effect can be obtained.

  As described above, in this embodiment, it is possible to suppress power by reducing the light amount of the light source in accordance with the change of the horizontal synchronization signal without using an amplifier circuit, and it is possible to suppress the power, and to achieve a high quality image with a more energy saving and inexpensive configuration. Can be provided. Further, the reading speed of the reduction optical system reading unit 4 and the equal-magnification optical system reading unit 5 can be more effectively matched to improve the processing speed at the time of double-sided reading without performing processing that changes the operation clock. It can be constituted as follows.

  4. Reduction optical system reading unit (first reading unit) / 5. Same-magnification optical system reading unit (second reading unit) / 14 ... CCD linear image sensor (first reading sensor) / 15a, 15b ... First light source / 21 ... light receiving element (second reading sensor) / 22 ... image reading device / 36, 39 ... horizontal synchronization signal control unit, mode switching unit (control means) / 43 ... phase synchronization circuit / 62 ... frequency divider / 63 ... phase Comparator / 64 ... Loop filter (filter circuit) / 65 ... Variable frequency oscillator / D ... Original / H1 ... First horizontal synchronizing signal (horizontal synchronizing signal of the first reading unit) / H2 ... Second horizontal synchronizing signal (second Horizontal synchronizing signal of reading unit) / H2 ′... Signal synchronized with phase of second horizontal synchronizing signal / T1... One terminal / T2.

Claims (5)

A first reading unit that reads an image of a first surface of a conveyed document by a first reading sensor;
A second reading unit having a reading method different from that of the first reading unit and having a reading speed slower than that of the first reading unit and reading an image of the second surface of the conveyed document by a second reading sensor;
When the first reading unit and the second reading unit read each image on the first side and the second side of the document in one step, the horizontal level of the first reading unit used for reading one scanning line of the document. Control means for changing the phase of the synchronization signal to the phase of the horizontal synchronization signal of the second reading unit,
An image reading apparatus. The first reading unit includes a first light source that emits light to the image when the image is read by the first reading sensor;
The control means controls to reduce the light amount of the first light source in accordance with the reading speed of the first reading unit that has become slow due to the change in the phase of the horizontal synchronizing signal.
The image reading apparatus according to claim 1. The control means includes a phase synchronization circuit that outputs a signal obtained by synchronizing the phase of the first reading sensor with the phase of the second reading sensor.
The image reading apparatus according to claim 1, wherein the image reading apparatus is an image reading apparatus. The phase synchronization circuit includes:
A phase comparator that inputs a horizontal synchronization signal of the first reading sensor to one terminal, inputs a feedback signal to the other terminal, and outputs a phase difference between the horizontal synchronization signal and the feedback signal When,
A variable frequency oscillator for changing the oscillation frequency based on the output from the phase comparator,
A frequency divider that divides the frequency of the output from the variable frequency oscillator and feeds back to the other terminal.
The image reading apparatus according to claim 3. Between the phase comparator and the variable frequency oscillator, there is interposed a filter circuit that outputs an AC component from the output of the phase comparator to remove unnecessary short period fluctuations.
The image reading apparatus according to claim 4.

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