JP2006211124A - Image reading apparatus and image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To illuminate an original document by controlling a lighting frequency and lighting an exposure lamp in a desired lighting condition. <P>SOLUTION: The lamp is lighted with an inverter frequency f1 on the basis of a lamp lighting signal from a main body control unit (S101), and an original document is read with a CCD (S102). A-D converted digital data outputted from the CCD are inputted into an image data comparing circuit, and the inputted image data are compared with a previously set CCD output target value (S103). If the image data are not equal to the target value in this comparison, output date of the CCD are read again (S103 to S102). If the image data are equal to the target value, a frequency inputted into an inverter is changed from f1 to f0 (S104), and then, copy operation is started (S105) and the lamp is turned off after the copy operation is completed (S106). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an image reading apparatus using an inverter and an image forming apparatus such as a copying machine or a facsimile equipped with the image reading apparatus, and more particularly to lighting control of an exposure lamp.

  In the conventional image reading apparatus, since the reading cycle of each line and the light amount control cycle are not synchronized with each other, the lamp lighting cycle falls within one line cycle if the lamp lighting cycle is not sufficiently small with respect to one line cycle. The number of lamp lighting pulses varies for each line, and due to the variation, a difference occurs in the integrated light quantity for each line, resulting in uneven color of the read image in the sub-scanning direction.

  Therefore, in the invention described in Patent Document 1, the oscillator of the inverter of the power feeding device that supplies power to the lamp is a frequency variable oscillator, and the frequency variable oscillator is controlled so that the oscillation signal from the frequency variable oscillator is phase-locked to the external synchronization signal. Thus, the dielectric barrier discharge fluorescent lamp is caused to emit light in synchronization with the external synchronization signal without causing fluctuations in the amount of light.

  In the invention disclosed in Patent Document 2, in the discharge lamp lighting device, voltages are generated for the plurality of discharge lamps so that the phases are shifted from each other with respect to the plurality of discharge lamps, and the phase shifts are equally spaced. It was.

Further, the illumination device of the conventional image reading device has produced a light source with a specific illuminance for each device with respect to various reading speeds of the device system and a necessary light amount for the light receiving element. Therefore, for example, as disclosed in Patent Documents 3 and 4, the line synchronization and the lamp lighting / extinguishing cycle are made constant, or the light is adjusted by changing the frequency.
JP 2000-323292 A JP 2001-273996 A Japanese Unexamined Patent Publication No. 7-74890 Japanese Patent Laid-Open No. 11-265055

  However, in the method of changing the frequency and emitting light in synchronization, the lamp lighting frequency changes, so that there is a possibility of deviating from the optimum lighting condition lighting frequency of the lamp, and there is a disadvantage that the circuit configuration becomes complicated. In addition, in order to prevent photoelectric element saturation, an optical design that is slow and generally adapted to the color is performed. Therefore, in a system with a high reading speed, a necessary light amount is insufficient, and there is a concern about deterioration of S / N. Furthermore, since the same light source cannot be used in an apparatus system having different required light amounts, the enormous number of component types and the accompanying complexity of light amount control have been problems.

  The present invention has been made in view of such a situation of the prior art. The purpose of the present invention is to turn on an exposure lamp under a desired lighting condition by controlling a lighting frequency when the exposure lamp is turned on using an inverter. It is also possible to illuminate the original.

  Another object is to control the lamp lighting pulse generation timing so that the number of lighting pulses per line is constant and the lamp lighting pulse generation positions do not overlap in the sub-scanning direction at an arbitrary shift interval.

  Still another object is to change the lamp lighting frequency input to the inverter from the system side so that the amount of light can be adjusted.

  In order to achieve the above object, the first means is an image reading apparatus for irradiating an original with an exposure lamp, receiving reflected light with a photoelectric conversion element, and reading an electric signal for the original image line by line. Synchronously controlling the oscillation circuit of the inverter with a line synchronization signal that defines the reading start timing, and having means for lighting the exposure lamp based on the generated lamp lighting pulse, the means for lighting the exposure lamp is per line The lamp lighting pulse generation timing is switched so that the number of lighting pulses is constant and pulse generation positions do not overlap in the sub-scanning direction at an arbitrary shift interval.

  The second means is characterized in that, in the first means, the shift interval of the lamp lighting pulse generation timing is changed according to the reading mode.

  The third means is characterized in that in the first means, the number of shift steps of the lamp lighting pulse generation timing is changed according to the reading mode.

  A fourth means is characterized in that, in the first means, the switching of the lamp lighting pulse generation timing is controlled in accordance with a reading mode.

  A fifth means is characterized in that, in any one of the second to fourth means, the reading mode is a color / monochrome mode and / or a character / photo mode.

  A sixth means is characterized in that, in the first means, means for inputting a clock signal as a reference of the lamp lighting pulse generation timing from the outside is provided.

  The seventh means includes an inverter circuit for lighting the exposure lamp, and a control circuit for controlling an exposure lamp lighting signal input to the inverter circuit and a pulse for lighting the exposure lamp, and exposes the document. In an image reading apparatus that irradiates with a lamp and receives reflected light by a photoelectric conversion element and reads an electric signal for an original image line by line, the light quantity of the exposure lamp is changed by changing the frequency of a pulse, and the photoelectric A frequency changing means for changing the output of the conversion element, wherein the frequency changing means sets the pulse frequency from the control circuit to be higher than the lighting pulse frequency at the minimum light quantity when the exposure lamp rises with the minimum light quantity. It is characterized by doing.

  The eighth means is characterized in that, in the seventh means, the light amount of the exposure lamp is changed by changing a pulse frequency from the control circuit based on data from the photoelectric conversion element.

  A ninth means is characterized in that, in the seventh means, the pulse frequency is changed so that the data from the photoelectric conversion element at the time of rising of the exposure lamp becomes a constant output.

  A tenth means is the seventh to ninth means, wherein the pulse frequency is changed through a plurality of stages.

  The eleventh means is characterized in that the image forming apparatus includes the image reading apparatus according to any one of the first to tenth means.

  According to the present invention, the lamp lighting pulse generation timing is switched so that the number of lighting pulses per line is constant and the pulse generation position does not overlap in the sub-scanning direction at an arbitrary shift interval. Since the lighting frequency is changed, the exposure lamp can be turned on under a desired lighting condition, and the original can be illuminated.

  Embodiments of the present invention will be described below with reference to the drawings.

<First Embodiment>
FIG. 1 is a diagram showing an overall configuration of a color image reading apparatus according to a first embodiment of the present invention.
In the figure, the color image reading apparatus is composed of a scanner SC and an automatic duplex document feeder ARDF. The scanner SC has a function of optically reading a document, and the automatic duplex document feeder ARDF has a function of automatically feeding a document to a document reading unit of the scanner SC. The automatic duplex document feeder ARDF also has a function of automatically inverting a document and transporting the document so that both sides of the document can be read by the scanner SC.

  Since the scanner SC itself is a known one, the configuration will be briefly described along with the operation. The scanner SC includes an illumination lamp 2 and a first mirror 3 mounted on the first carriage 31, second and third mirrors 5 and 4 mounted on the second carriage 32, a lens 1, and a CCD. The image information of the moving document is read by guiding the reading light from the first carriage 31 fixed at the sheet through position to the CCD, and the first and second carriages 31 and 32 are divided into two. The original image of the fixed original is read by moving in the sub-scanning direction at a one-to-one scanning speed.

  Specifically, the document placed on the document table glass 8 is irradiated with the illumination lamp 2, receives reflected light from the first mirror 3, and is scanned while moving under the document table. The scanning is performed while the first and second carriages 31 and 32 move in the sub-scanning direction, and the reflected light from the document surface received by the first mirror 3 is guided to the second and third mirrors 5 and 4. The lens 1 is incident on the image plane of the CCD mounted on the SBU 10 and is photoelectrically converted into an electrical signal. The first and second carriages 31 and 32 on which the first mirror 3, the illumination lamp 2 and the second mirror 5, and the third mirror 4 are mounted respectively are driven from the carriage home position to the maximum scanning region direction by using the traveling body motor 9 as a drive source ( It can be moved in the horizontal direction in the figure.

  On the other hand, in the automatic duplex document feeder ARDF, the documents stacked along the document guide 12 of the document table 11 are called the calling roller 14 and the feeding roller 15 and the separation roller when the single-sided document reading is selected. 17. The first conveyance roller passes through the reading position between the DF original glass 6 and the reflection guide plate 20, and is sent to the second conveyance roller 21 and the paper discharge roller 23 to discharge the original. A registration sensor 19 is disposed in front of the DF document glass 6 and can detect the timing of the leading and trailing edges of the paper entering the reading unit.

  On the other hand, when double-sided original reading is selected, first, the front side of the original is read in the same manner as when single-sided original reading is selected. When reading the surface of the document, a reading position (sheet-through reading) between the DF document glass 6 and the reflection guide plate 20 by the calling roller 14, the paper feeding belt 16, the transport roller 15, the separation roller 17, and the first transport roller 18. ) Through the second transport roller 21 and the paper discharge roller 23. Then, without discharging the document, the branching claw 24 is switched downward and transferred onto the reversing table 26 by the reversing roller 25, and the branching claw 24 is switched upward after the trailing edge of the document passes through the paper discharge roller 23. Then, the reversing roller stops once.

  In order to read the back side of the document, the document is conveyed from the reversing table 26 to the first conveying roller 18 by rotating the reverse roller 25 once stopped in the opposite direction. After passing through the first transport roller 18 and passing through the reading position between the DF original glass 6 and the reflection guide plate 20 in the same manner as the surface, the paper is fed to the second transport roller 21 and the paper discharge roller 23, and then the original is discharged. The

  When the original passes through the reading position between the DF original glass 6 and the reflection guide plate 20 for both reading of the front and back surfaces, the illumination lamp 2 on the first carriage 31 is stopped near the reading position. The reflected light is guided to the lens 1 by the first mirror 3 and the second mirror 5 and the third mirror 4 that are integrally formed. Thereafter, photoelectric conversion is performed in the same manner as in the case of the document placed on the document table.

  The sheet feeding mechanism of the calling roller 14, the sheet feeding belt 16, the conveying roller 15, and the separation roller 17 of the automatic duplex document conveying device ARDF is driven by a sheet feeding motor (not shown). Further, the transport mechanisms of the first transport roller 18, the second transport roller 21, the paper discharge roller 23, and the reverse roller 25 are driven by a transport motor (not shown). Further, the automatic duplex document feeder ARDF has a set sensor 13 for detecting whether or not a document is set on the document table 17 in order to detect the document, a width size detection board 28 for detecting the document size, a document length. Sensors 29 and 30 and a document trailing edge sensor 27 for detecting the trailing edge of the document are mounted. The SCU 7 for controlling the operation of the color image reading apparatus including the scanner SC main body and the automatic duplex document feeder ARDF is mounted on the scanner SC main body.

  2 and 3 are block diagrams showing the overall configuration of the color image reading apparatus according to this embodiment.

  In FIG. 2, the automatic double-sided document feeder ARDF is connected to the ADU 42 having a function of relaying the power supply of the electrical components used in the ARDF unit. ADF lift-up sensor, document set sensor 13, ADF cover open sensor, paper discharge sensor 22, reverse tray sensor, document width size detection sensor 28, document length size detection sensors 29 and 30, document trailing edge detection sensor 27, paper feed clutch A bottom plate solenoid, a reversing solenoid, a paper feed / reversing motor, a conveyance motor, and the like are connected and supplied with power.

  The scanner SC includes VICU 33 with SCU7, PSU44, SBU10, ADU42, document size sensors (width, length) 29, 30, home position sensor, scanner motor 9, lamp ballast 114, SOP43, SWB, NIC operation panel, and the like. The SCU 7 is connected to an OIPU 36, a NIC 41, an ISIC 40, and the like. The lamp stabilizer 114 is connected to the xenon lamp 2 for illumination.

  As shown in FIG. 3, a CCD 100 is mounted on the SBU 10, and the reflected light of the original that has entered the CCD 100 is converted into an analog signal having a voltage value corresponding to the light intensity in the CCD 100. Output separately. The analog image signal of the SBU 10 is input to the A / D converter 102 after the dark potential portion is removed by the analog processing circuit 101 on the VIOB 33, the odd bits and the even bits are combined, and the gain is adjusted to a predetermined amplitude. Signaled.

  The digitized image signal is subjected to shading correction by the shading unit 103, subjected to image processing such as gamma correction and MTF correction by the IPU (image processing unit) 104 on the SCU 7 from the VIOB 33, and then subjected to a synchronization signal and an image clock. At the same time, it is input as a video signal to the memory controller 105 that manages the image data storage means SDRAM 106, and is stored in an image memory composed of SDRAM.

  The image data stored in the image memory SDRAM 106 is sent to the external I / F driver 107 and transferred to the external output device 120 such as a personal computer or a printer. The external I / F driver in the embodiment generically refers to drivers such as SCSI, IEEE 1394, and LAN, and local video signals.

  A CPU 108, ROM 109, RAM 110, NVRAM 111, and motor driver 112 are mounted on the SCU (scanner control unit) 7. The CPU 108 is a traveling motor 9 that is a stepping motor of the scanner body, and an ARDF paper feed motor (see FIG. The timing control of a conveyance motor (not shown) is also performed.

  An input port connected to the CPU 108 on the SCU 7 is connected to the main body operation panel SOP 43 via the VIOB 33. A start switch (not shown) and a stop switch (not shown) are mounted on the main body operation panel SOP43. When each switch is pressed, the CPU detects that the switch is turned on via the input port.

  FIG. 4 is a diagram showing a circuit configuration of a lamp lighting circuit using an inverter. In the figure, in the case of synchronous lighting, when a line synchronization signal TG-INV142, a clock signal CLK145, a control signal CNT143, and a gate signal GATE144 that define the read start timing of each line are input, the lighting control unit 135 operates and an inverter Control the circuit. The output from the inverter circuit 131 is applied to the lamp 133 via the step-up transformer 132. Note that the CNT 143 is a lamp ON / OFF control signal, the GATE signal 144 is a control signal for the lamp pause period, and 130 is a constant voltage power source.

  FIG. 5 is a diagram showing an example of a circuit configuration of the inverter in FIG. As shown in the figure, when the lamp ON / OFF control signal CNT143 is at a high level, TR1 is turned on, and power is supplied to IC1 of the inverter control IC. IC1 has a built-in driver for driving the switching element FET1, oscillates at a predetermined period in accordance with the clock signal 145, drives the built-in driver by the oscillation pulse, and drives the switching element FET1 by the output of the driver. When the switching element FET1 is turned on by the drive signal, a current flows through the path of the constant voltage power supply 130 → the primary winding 132 of the step-up transformer → the switching element FET1, and energy is stored in the step-up transformer 132. Next, when the switching element FET1 is turned OFF and the current flowing through the step-up transformer 132 is interrupted, the stored energy is released, and the voltage having a steep rise on the primary and secondary sides of the step-up transformer 132. A waveform is generated. This voltage waveform decays with time, and then when the switching element FET1 is turned on and then turned off, a voltage waveform having a steep rise again is generated as described above. That is, each time the switching element FET1 is turned on / off, a voltage waveform having a steep rise is generated again, a current flows repeatedly through the lamp 133, the lamp 133 is lit, and light is emitted. Further, the inverter control IC 1 stops the output during the period when the 1GATE signal 44 is input.

  As shown in FIG. 4, the inverter oscillates at a predetermined cycle in response to a clock signal CLK145 input from the outside of the inverter. By making the clock signal CLK145 outside the inverter, it is possible to reduce the influence of heat received from inverter heat generating components such as FETs and transformers, and to improve the oscillation accuracy.

  The timing chart of the control signal is shown in FIGS. FIG. 6 shows the timing of the lamp ON / OFF signal CNT and the line synchronization signal TG-INV. In addition to the lamp ON / OFF signal CNT, the line synchronization signal TG-INV is supplied for the purpose of synchronizing the lighting frequency. . The lamp ON / OFF signal CNT and the line synchronization signal TG-INV are supplied asynchronously, and the lamp ON / OFF signal CNT is turned on and off arbitrarily.

  FIG. 7 shows the timing of the line synchronization signals TG-INV, GATE, and CLK and the inverter output light waveform. T1 and T2 shown in FIG. 7 are pause periods, and the number of lighting pulses per line can be set to an arbitrary value by providing this pause period according to the required document surface illuminance. In FIG. 7, the lamp lighting pulse generation timing in the main scanning direction can be arbitrarily controlled by controlling the GATE signal, controlling the end timing of the lamp pause period, the CLK signal, and switching the lamp lighting pulse generation timing.

  8 and 9 are timing charts showing control signal timings when the shift interval of the ramp pulse generation timing is changed according to the reading mode (color / monochrome, character / photo, etc.). When the start and end timings of the pause period in the initial state are controlled as shown in FIG. 7 in accordance with the lamp lighting frequency and the required document surface illuminance, the CLK signal is controlled for each line with respect to the line synchronization signal TG-INV. In addition, the lamp lighting pulse generation timing is controlled at an arbitrary cycle so that the pulse generation positions do not overlap in the sub-scanning direction. An example in which the timing interval is shifted with respect to timing 0 in the initial state is shown.

  Timing 0 (solid line) at the nth line of sub-scanning, timing 1 (dashed line) at the n + 1 line, timing 2 (dashed line) at the n + 2 line, timing 3 (dashed line) at the n + 3 line, etc. By controlling the timing so that the pulse generation positions do not overlap at an arbitrary shift interval, vertical white stripes in the sub-scanning direction are diffused, and vertical white stripes in the sub-scanning direction due to lamp lighting noise can be reduced. In FIG. 8, as an example, the timing control is shown with four shift intervals of 1.5 μs and timings 0 to 3 in a sub-scanning three-line cycle. However, in the present invention, sub-scanning is performed at an arbitrary shift interval. Control may be performed at an arbitrary plurality of timings such as n timings of timings 0 to n−1 in an n line cycle. However, when the control is performed at arbitrary plural timings, the number of lighting pulses per line is controlled so as to match in each line.

  The shift interval of the lamp lighting pulse generation timing is changed according to the reading mode (color / monochrome, character / photo, etc.). As an example, FIG. 9 shows four cases of timing control with a shift interval of 0.75 μs and timings 0 to 3 in a sub-scanning three-line cycle. For example, in a mode in which vertical white streak in the sub-scanning direction is likely to occur due to lamp lighting noise, such as color / photo mode, the vertical white streak in the sub-scanning direction is controlled by controlling the shift interval in the main scanning direction to be large. It is diffused and the generation density level of vertical white stripes can be reduced. Also, in a mode in which vertical white streaking in the sub-scanning direction due to lamp lighting noise is unlikely to occur, such as black and white / character mode, control is performed so that the shift interval in the main scanning direction is small.

  The timing chart of FIG. 10 and FIG. 11 shows the timing of the control signal when the number of shift steps of the ramp pulse generation timing is changed according to the reading mode (color / monochrome, character / photo, etc.).

  When the start and end timings of the pause period in the initial state are controlled at the timing shown in FIG. 7 according to the lamp lighting frequency and the required document surface illumination, the GATE signal and the CLK signal are controlled, and the line synchronization signal TG− With respect to INV, the lamp lighting pulse generation timing is controlled at an arbitrary cycle so that the pulse generation positions do not overlap in the sub-scanning direction. FIG. 10 shows an example of changing the number of timing shift steps with respect to timing 0 in the initial state.

  Timing 0 (solid line) at sub-scanning n line, timing 1 (dashed line) at n + 1 line, timing 2 (dashed line) at n + 2 line, timing 3 (two-dot chain line) at n + 3 line, timing at n + 4 line 4 (dotted line), n + 5th line, timing 5 (one-dot chain line),..., And pulse generation positions do not overlap at an arbitrary number of shift steps (shift interval 0.75 μs in the main scanning direction in FIG. 10). By controlling the timing in this manner, vertical white stripes in the sub-scanning direction are diffused, and vertical white stripes in the sub-scanning direction due to lamp lighting noise can be reduced.

  In FIG. 10, as an example, timing control is performed with a shift interval of 0.75 μs and six shift steps of 6 timings of timing 0 to 5, but in the present invention, any shift interval and arbitrary shift are shown. The control may be performed at arbitrary plural timings such as n times from timing 0 to n−1 in the number of steps and the sub-scanning n-line period. However, when the control is performed at arbitrary plural timings, the number of lighting pulses per line is controlled so as to match in each line.

  Further, the number of shift steps of the lamp lighting pulse generation timing is changed according to the reading mode (color / monochrome, character / photo, etc.). As an example, FIG. 11 shows four timing control cases where the timing is 0 to 3 at a shift interval of 0.75 μs and a sub-scanning three-line period. For example, in a mode in which vertical white streak in the sub-scanning direction due to lamp lighting noise is likely to occur, such as in the color / photo mode, the vertical white streak in the sub-scanning direction is controlled by increasing the number of shift steps in the main scanning direction. Is diffused, and the generation density level of vertical white stripes can be reduced. Also, in a mode in which vertical white streaking in the sub-scanning direction due to lamp lighting noise is unlikely to occur, such as black and white / character mode, control is performed so that the number of shift steps in the main scanning direction is small.

  Further, the switching ON / OFF of the lamp lighting pulse generation timing can be controlled according to the reading mode (color / monochrome, character / photo, etc.). For example, in a mode in which vertical white streaking in the sub-scanning direction is likely to occur due to lamp lighting noise, such as the color / photo mode, the shift amount in the main scanning direction and the control line in the sub-scanning direction as shown in FIGS. By controlling the period, vertical white stripes in the sub-scanning direction are diffused, and the generation density level of vertical white stripes can be reduced. Further, in a mode in which vertical white streaking in the sub-scanning direction due to lamp lighting noise is unlikely to occur, such as black and white / character mode, the lamp lighting pulse generation timing switching control is turned off.

  In the present embodiment, an image reading apparatus is illustrated that includes a scanner SC and an automatic duplex document feeder ARDF. However, the image reading apparatus is used alone connected to a network, or an image forming unit (not shown). Can be used as a reading device of an image forming apparatus.

As described above, according to the present embodiment,
1) In the synchronous lighting in which the lamp 133 is turned on by synchronously controlling the oscillation circuit IC1 and FET1 of the inverter with the line synchronization signal TG-INV that defines the reading start timing of each line, the lamp lighting pulse generation timing is turned on per line. Since the number of pulses is switched to be constant, it is possible to control so that the lamp lighting pulse generation positions do not overlap in the sub-scanning direction at an arbitrary shift interval.
2) Since the lamp lighting pulse generation timing shift interval is changed according to the reading mode (color / monochrome, character / photo, etc.), the lamp lighting pulse generation position is controlled so as not to overlap in the sub-scanning direction. The occurrence of vertical white stripes in the sub-scanning direction due to lamp lighting noise can be reduced.
3) The lamp lighting pulse generation position is controlled not to overlap in the sub scanning direction by changing the number of shift steps of the lamp lighting pulse generation timing according to the reading mode (color / monochrome, character / photo, etc.). Therefore, it is possible to reduce the occurrence of vertical white stripes in the sub-scanning direction due to lamp lighting noise.
4) Switching the lamp lighting pulse generation timing ON / OFF according to the reading mode (color / monochrome, text / photo, etc.), so that the lamp lighting pulse generation position does not overlap in the sub-scanning direction. Therefore, the occurrence of vertical white stripes in the sub-scanning direction due to lamp lighting noise can be reduced.
5) Since the clock signal is input from the outside of the inverter, the transmission circuit is prevented from being affected by temperature, so that the fluctuation of the transmission frequency due to the temperature characteristic fluctuation of the inverter components can be reduced.
There are effects such as.

<Second Embodiment>
12 to 19 are for explaining a color image reading apparatus according to the second embodiment of the present invention. The color image reading apparatus itself, the inverter circuit, the operation, and the like are configured in the same manner as those described with reference to FIGS. 1 to 7 in the first embodiment. The following description is based on the configuration of FIGS. 1 to 7 according to the first embodiment, and the description regarding FIGS. 1 to 7 is omitted.

  FIG. 12 is a block diagram showing a circuit configuration of a lamp lighting control circuit according to the second embodiment of the present invention, and FIG. 13 is a flowchart showing an operation procedure of the circuit of FIG. The control circuit shown in FIG. 12 includes a lamp (light source) 2, an inverter 201 for lighting the lamp 2, a CCD 100 that reads a document image, an A / D circuit 202, an image processing circuit 203, an image data comparison circuit unit 204, The frequency switching circuit unit 205 is basically configured.

  In the control circuit of FIG. 12, the lamp 2 is lit at the inverter frequency f1 (step S101) and read by the CCD 100 (step S102) by a lamp lighting signal from a main body control unit (not shown) as shown in the flowchart of FIG. . The A / D converted digital data of the CCD output is input to the image data comparison circuit unit 204, and the input image data is compared with a preset CCD output target value (step S103). In this comparison, when the target value and the image data are not equal, the output data of the CCD is read again (step S103 → step S102). When the target value is equal to the image data, the frequency input to the inverter is changed from f1 to f0 (step S104), the copying operation is started (step S105), and the lamp is turned off after the copying operation is completed. (Step S106). The copy operation is performed by the image processing unit 203.

  In the conventional exposure lamp, when the lamp is started up, it takes time until the CCD output becomes constant as shown in FIG. 14. However, as shown in the flowchart of FIG. 13, the lighting frequency of the lamp is set to the lighting frequency f1. When the frequency f0 after matching with the target value is switched, as shown in FIG. 15, the rise of the lamp light quantity at the time of start-up becomes faster and the CCD output can be stabilized earlier than before.

  FIG. 16 is a block diagram showing a modification of the control circuit of FIG. 12, and FIG. 17 is a flowchart showing an operation procedure of the control circuit of FIG. In this modified example, a frequency calculation circuit unit 206 is used instead of the frequency switching circuit unit 205 of FIG. Thus, the A / D converted digital data of the CCD output is input to the image data comparison circuit unit 204, and the input image data is compared with the preset CCD output target value, and the target value and the image are compared. If the data are not equal (step S103—NO), the difference from the target value is calculated and sent to the frequency calculation circuit unit 206 at the next stage. The frequency calculation unit 206 determines the next frequency based on a program stored in advance in the ROM 109 (see FIG. 3). Then, returning to step S102, image reading is performed at the determined frequency. This operation is repeated, and copying is performed when the target value matches the read value (steps S103 and S105). Other parts and operations not specifically described are the same as those described with reference to FIGS.

Here, the image data comparison unit 204 and the frequency calculation unit 206 will be described in more detail.
Except for the temperature factor, the lighting frequency and the light source emission amount have a relationship of frequency increase → light source emission amount increase, frequency decrease → light source emission amount decrease. When changing the frequency, a program is stored in the ROM 109 in advance. A density reference plate (reference white plate) (not shown) is read, and the target value after A / D conversion is α, and the measured value is β. Calculate α−β and calculate the difference Δβ with respect to the target value.
Δβ = α-β
Ask for. A table of this Δβ is shown in FIG. In the table, a frequency change amount ΔfKHz to be selected for each Δβ (each numerical value is ** or more) is determined. For example,
Δβ = −26
No. in the table. A value corresponding to −30 of 2;
Δf2 = −15 KHz
When the current lighting frequency is f = 100 KHz,
f + Δf2 = 85 KHz
Thus, the lighting frequency can be reduced and dimmed.

on the other hand,
Δβ = 15
No. in the table. A value corresponding to 10 of 6,
Δf6 = + 5KHz
Select.

If the current lighting frequency is f = 100 KHz,
f + Δf2 = 105 KHz
Thus, it is possible to increase the lighting frequency and increase the brightness.

  Based on the result determined by the frequency calculation unit, the frequency input to the inverter is changed, the lamp light quantity sent to the inverter is changed, the image data from the CCD is checked again, The operation is repeated. When the target value is equal to the image data, the copying operation is started and the lamp is turned off after the copying operation is completed. The above operation is performed when the lamp is turned on.

  In the conventional lamp, when the lamp is started up, as shown in FIG. 14, the rise of the lamp light amount is slow and it takes time until the CCD output becomes constant, but the lamp lighting frequency is controlled as in the above flow. Thus, as shown in FIG. 18, the rise of the lamp light amount at the time of start-up becomes faster, and the CCD output can be stabilized earlier than before. In addition, the frequency may be changed from a high frequency to a low frequency, or may be changed from a low frequency to a high frequency.

  Other parts that are not particularly described are configured in the same manner as the first embodiment and function in the same manner.

As described above, according to the present embodiment,
1) At the start-up of the exposure lamp with the maximum light amount, the rise time at the start-up of the exposure lamp is controlled by controlling the pulse frequency from the control circuit unit to be higher than the lighting pulse frequency with the minimum light amount. It can be done quickly and the light quantity can be stabilized quickly.
2) The amount of light from the exposure lamp can be changed by changing the pulse frequency from the control unit based on the data from the CCD so that the required CCD output level can be stabilized quickly.
3) The required CCD output level can be stabilized quickly by changing the pulse frequency so that the data from the CCD when the exposure lamp is turned on becomes a constant output.
4) The change of the pulse frequency when the exposure lamp rises can be changed more smoothly by dividing it into several stages, so that the light quantity can be changed more smoothly.
There is an effect.

1 is a diagram illustrating an overall configuration of a color image reading apparatus according to a first embodiment of the present invention. 1 is a block diagram illustrating an overall configuration of a color image reading apparatus according to an embodiment. 1 is a block diagram illustrating an overall configuration of a color image reading apparatus according to an embodiment. It is a figure which shows the circuit structure of the lamp lighting circuit which uses an inverter. It is a figure which shows an example of the circuit structure of the inverter in FIG. It is a timing chart which shows the timing of the lamp ON / OFF signal CNT and the line synchronization signal TG-INV. It is a timing chart which shows the timing of line synchronous signal TG-INV, GATE, and CLK and an inverter output optical waveform. It is a timing chart which shows the timing of the control signal in the case of changing the shift interval of the ramp pulse generation timing according to the reading mode (color / monochrome, character / photo, etc.). It is a timing chart which shows the other timing of the control signal in the case of changing the shift interval of a ramp pulse generation timing according to reading modes (color / monochrome, a character / photograph, etc.). It is a timing chart which shows the timing of the control signal in the case of changing the number of shift steps of the ramp pulse generation timing according to the reading mode (color / monochrome, character / photo, etc.). It is a timing chart which shows the other timing of the control signal in the case of changing the number of shift steps of the ramp pulse generation timing according to the reading mode (color / monochrome, character / photo, etc.). It is a block diagram which shows the circuit structure of the control circuit of the lamp lighting control in the 2nd Embodiment of this invention. 13 is a flowchart showing an operation procedure of the circuit of FIG. It is a figure which shows the relationship between the time at the time of the lamp rising of the conventional exposure lamp, and CCD output. It is a figure which shows the relationship between the time at the time of the lamp rising of the exposure lamp in 2nd Embodiment, and CCD output. It is a block diagram which shows the modification of the control circuit of FIG. It is a flowchart which shows the operation | movement procedure of the control circuit of FIG. It is a figure which shows the relationship between the time at the time of the lamp rising of the exposure lamp in a control circuit of FIG. 16, and CCD output. It is a figure which shows the table which memorize | stored the relationship between (DELTA) (beta) and (DELTA) f in the case of changing a frequency.

Explanation of symbols

2,133 lamp (light source)
7 SCU
10 SBU
100 CCD
101 Analog processing circuit 102, 202 A / D converter 103 Shading unit 104 IPU
105 memory controller 106 SDRAM
108 CPU
109 ROM
110 RAM
111 NVRAM
130 constant voltage power supply 131, 201 inverter 132 step-up transformer 135 lighting control unit 203 image processing unit 204 image data comparison unit 205 frequency switching circuit unit 206 frequency calculation circuit unit

Claims (11)

In an image reading apparatus that irradiates an original with an exposure lamp, receives reflected light by a photoelectric conversion element, and reads an electric signal for the original image line by line.
A means for controlling the oscillation circuit of the inverter in synchronization with a line synchronization signal that defines the read start timing of each line, and lighting the exposure lamp based on the generated lamp lighting pulse;
The means for lighting the exposure lamp switches the lamp lighting pulse generation timing so that the number of lighting pulses per line is constant and the pulse generation position does not overlap in the sub-scanning direction at an arbitrary shift interval. Image reading device.   The image reading apparatus according to claim 1, wherein a shift interval of the lamp lighting pulse generation timing is changed according to a reading mode.   The image reading apparatus according to claim 1, wherein the number of shift steps of the lamp lighting pulse generation timing is changed according to a reading mode.   The image reading apparatus according to claim 1, wherein switching of the lamp lighting pulse generation timing is controlled according to a reading mode.   5. The image reading apparatus according to claim 2, wherein the reading mode is a color / monochrome mode and / or a character / photo mode. 6.   2. The image reading apparatus according to claim 1, further comprising means for externally inputting a clock signal serving as a reference for the lamp lighting pulse generation timing. An inverter circuit for lighting the exposure lamp;
A control circuit for controlling an exposure lamp lighting signal input to the inverter circuit and a pulse for lighting the exposure lamp;
In an image reading apparatus that irradiates an original with an exposure lamp, receives reflected light with a photoelectric conversion element, and reads an electric signal for the original image in units of lines,
A frequency changing means for changing the light quantity of the exposure lamp by changing the frequency of the pulse, and changing the output of the photoelectric conversion element;
The frequency changing means makes the frequency of the pulse from the control circuit higher than the lighting pulse frequency with the minimum light amount when the exposure lamp starts to light with the minimum light amount.   8. The image reading apparatus according to claim 7, wherein the light quantity of the exposure lamp is changed by changing a pulse frequency from the control circuit based on data from the photoelectric conversion element.   The image reading apparatus according to claim 7, wherein the pulse frequency is changed so that data from the photoelectric conversion element at a time when the exposure lamp is turned on becomes a constant output.   The image reading apparatus according to claim 7, wherein the pulse frequency is changed through a plurality of stages.   An image forming apparatus comprising the image reading apparatus according to claim 1.

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