JP5361510B2 - Image reading device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily and accurately detect abnormality of a light-emitting element. <P>SOLUTION: An image reading apparatus includes e.g., a light-emitting element for illuminating a document and a feedback circuit for maintaining a current, that flows to the light-emitting element, at a target value. In particular, the image reading apparatus includes a voltage detecting means for detecting a voltage at a connecting point of the feedback circuit and the light-emitting element and an abnormality detecting means for detecting abnormality in the light-emitting element in accordance with whether the voltage detected by the voltage detecting means deviates from a predetermined normal range. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention generally relates to an image reading apparatus, and more particularly to a mechanism for detecting an abnormality of a light source.

  In general, a xenon tube or a cold cathode tube has been used as a light source of an image reading apparatus. However, in recent years, light emitting diodes (LEDs) have attracted attention as light sources. Light emitting diodes are more advantageous than traditional light sources in terms of power consumption and heat generation.

  Incidentally, the light source of the image reading apparatus needs to illuminate the document simultaneously and uniformly over the reading width of the document. However, since the light emitting diode is a point light source, a single light emitting diode is not sufficient as a light source. Therefore, an array light source in which a plurality of light emitting diodes are connected in series or in parallel is advantageous in that the original surface is uniformly illuminated. In the case of an array light source, it is difficult to visually determine a failure to the extent that one of the plurality of light emitting diodes has failed. This is because luminance is interpolated by light from other light emitting diodes adjacent to the failed light emitting diode.

  According to Patent Document 1, an invention for detecting a failure of a white LED by detecting a current flowing through an array light source composed of a plurality of white LEDs driven at a constant voltage is proposed. The invention of Patent Document 1 has an advantage of detecting a failure of a white LED without visual observation.

JP 2004-040669 A

  In general, when a light emitting diode is lit by a constant voltage driving circuit, the driving current is not constant even if the driving voltage of the light emitting diode is constant. In order to make a failure determination using the terminal voltage of the light emitting diode, a large margin is required for the threshold for detecting the abnormal voltage. Therefore, it is desirable to determine the failure without using the terminal voltage of the light emitting diode.

  By the way, the malfunction of the light emitting diode includes, for example, a decrease in luminance caused by electrostatic breakdown or the like, and a lighting failure at a low current. In the invention described in Patent Document 1, it is difficult to detect these minute characteristic deteriorations. Moreover, although the brightness | luminance fall resulting from electrostatic breakdown advances gradually, there exists a possibility that it may become impossible to satisfy | fill the lifetime of the assumed array light source in the long run. When a document is read with a low amount of light, the read image is easily affected by a decrease in the amount of light. Therefore, it is desirable to detect even minute characteristic deterioration of the light emitting element.

  Therefore, an object of the present invention is to solve at least one of such problems and other problems. For example, an object of the present invention is to detect an abnormality of a light emitting element easily and accurately. Other issues can be understood throughout the specification.

The present invention is an image reading apparatus comprising:
A light emitting element for illuminating the document;
A feedback circuit for maintaining the current flowing through the light emitting element at a target value;
Voltage detecting means for detecting a voltage at a connection point between the feedback circuit and the light emitting element;
First comparison means for comparing the voltage detected by the voltage detection means with a first threshold voltage;
Second comparison means for comparing the voltage detected by the voltage detection means with a second threshold voltage higher than the first threshold voltage;
An electrostatic breakdown determining means for determining that the light emitting element is electrostatically destroyed if the voltage detected by the voltage detecting means is not less than the first threshold voltage and not more than the second threshold voltage;
Is further provided .

  In the present invention, the abnormality of the light emitting element is detected according to the voltage in a part of the feedback circuit. Therefore, the present invention can detect abnormality of the light emitting element easily and accurately.

It is a schematic sectional drawing of an image reading apparatus. The outline of the illuminating device using the array light source by a light emitting diode is shown. It is a circuit diagram showing a failure detection circuit. It is the figure which showed the light emitting diode characteristic abnormality which failed by electrostatic breakdown. It is the figure which showed the relationship between the forward current If and the light emission luminance of a light emitting diode. It is the figure which showed the relationship between the reference voltage Vin and the failure detection voltage Vc. It is the figure which showed the relationship between the reference voltage and control voltage Vb when the failure by a disconnection generate | occur | produces. It is a block diagram of the function which CPU302 concerning an embodiment realizes. 5 is a flowchart showing an abnormality detection process executed by a CPU 302 in the constant current drive circuit 301.

  An embodiment of the present invention is shown below.

  FIG. 1 is a schematic sectional view of an image reading apparatus. The image reading apparatus 100 is an image reading apparatus equipped with an automatic document feeder. The image reading apparatus 100 may be an image reader used by being connected to a personal computer, a network scanner used by being connected to a network, or mounted on a copying machine or a multifunction machine. It may be an image reading unit.

  A document 102 is loaded on the document tray 101. The document 102 is fed as the paper feed roller 103 and the separation conveyance roller 104 rotate. The separation / conveyance driven roller 105 cooperates with the separation / conveyance roller 104 to feed the original 102 fed by the sheet feeding roller 103 one by one. The leading edge of the document 102 abuts against a nip formed by the stationary registration roller 106 and the registration driven roller 107. As a result, a loop occurs in the document 102 and the skew of the document is corrected. The read roller 108 and the read follower roller 109 flow the document and convey the document 102 toward the reading glass 116. A platen roller 110 is disposed on the opposite side of the flow reading glass 116.

  The CCD line sensor 126 reads image information on the surface of the original 102 that passes on the flow reading glass 116. When the CCD line sensor 126 finishes reading the surface image of the document 102, the lead discharge roller 111 and the lead discharge driven roller 112 convey the document 102 toward the CIS (contact image sensor) 128. The jump table 117 guides the document 102 to the CIS 128 by scooping up the document 102 from the flow reading glass 116. A platen roller 127 is disposed on the opposite side of the CIS 128. The CIS 128 reads image information on the back side of the document 102 passing on the flow reading glass 130. When the CIS 128 finishes reading the back side image of the original 102, the paper discharge roller 113 discharges the original 102 to the paper discharge tray 114.

  The image reading unit 115 includes a first mirror base 123, a second mirror base 124, a lens 125, and a CCD line sensor 126. The LED light source units 514 and 515 and the mirror 120 are attached to the first mirror base 123. The mirrors 121 and 122 are attached to the second mirror base 124. The first mirror table 123 and the second mirror table 124 move in parallel with the document table glass 118. The LED light source units 514 and 515 illuminate the reading target surface of the document. The LED light source units 514 and 515 may also be provided in the CIS 128. Reflected light from the document is guided to the lens 125 via the mirrors 120, 121, and 122, and formed on the CCD line sensor 126 by the lens 125. The CCD line sensor 126 photoelectrically converts the formed reflected light and outputs an electrical signal corresponding to the amount of incident light. Similarly, the CIS 128 photoelectrically converts the reflected light from the original 102 with a light receiving element and outputs an electrical signal corresponding to the amount of incident light.

  The image reading apparatus has a document fixed reading mode and a flow reading mode. The former is a mode for reading a document placed on the document table glass 118 while moving the first mirror table 123 and the second mirror table 124 in the sub-scanning direction (the arrow direction in the figure). The latter is a mode in which the original is read at the position of the flow reading glass 116 while the original 102 is conveyed by the automatic document feeder while the first mirror stand 123 and the second mirror stand 124 are stationary. Further, in the flow reading mode, image information on the back surface of the original 102 can be read by the CIS 128 via the flow reading glass 130.

  FIG. 2 shows an outline of an illuminating device using an array light source of light emitting diodes. Reference numeral 210 denotes an equivalent circuit of the LED light source units 514 and 515 formed of a light emitting diode array. On the substrate 200, a plurality of light emitting diodes 201 are mounted in an array. The light emitting diode 201 is an example of a light emitting element that illuminates a document. The cathode electrode side wiring 202 and the anode electrode side wiring 203 are connected to a constant current drive circuit, which will be described later, via a connector 204 and an inter-substrate connection cable (not shown).

  FIG. 3 is a circuit diagram showing a failure detection circuit. The members already described are given the same reference numerals. The light-emitting diode lighting constant current circuit 300 includes a failure detection circuit.

  The constant current drive circuit 301 includes a control CPU 302. The CPU 302 includes a D / A output port 303, a first A / D input port 304, and a second A / D input port 305. The D / A output port 303 is connected to the plus terminal of the operational amplifier OP. The first A / D input port 304 is connected to the cathode side terminals of the LED light source units 514 and 515. The second A / D input port 305 is connected to one end of the capacitor C1, the base terminal of the transistor Tr, and one end of the resistor R1. The other end of the capacitor C1 is connected to the first A / D input port 304, the cathode side terminals of the LED light source units 514 and 515, and the collector terminal of the transistor Tr. The other end of the resistor R1 is connected to the output terminal of the operational amplifier OP. The negative terminal of the operational amplifier OP is connected to the emitter terminal of the transistor Tr and one end of the resistor R2. The resistor R2 functions as a current detection resistor. The other end of the resistor R2 is grounded. As shown in FIG. 3, the constant current drive circuit 301 is configured by such a feedback circuit. The display device 310 is a device that displays various messages and warnings.

  Next, the operation of the feedback circuit for maintaining the light emission amount of the light emitting element (that is, the current flowing through the light emitting element) at the target value will be specifically described. The CPU 302 applies the reference voltage Vin corresponding to the target value to the operational amplifier OP through the D / A output port 303 in order to maintain the light emission amount of the LED light source units 514 and 515 at an arbitrary target value. The operational amplifier OP adjusts the output voltage so that the terminal voltage of the current detection resistor R2 matches the reference voltage. This output voltage is applied to the base terminal of the transistor Tr as a current control element via the resistor R1. The transistor Tr determines the current value If of the current flowing through the LED light source units 514 and 515 in accordance with the output voltage of the operational amplifier OP. Of the output voltage of the operational amplifier OP, the remaining voltage dropped by the resistor R1 is applied to the second A / D input port 305 as the control voltage Vb. A failure detection voltage Vc that is a terminal voltage of the LED light source units 514 and 515 is applied to the first A / D input port 304.

  As described above, the feedback circuit flows to the light emitting diode 201 according to the comparison result between the terminal voltage of the resistor R2 which is a constant current detecting element connected in series with the light emitting diode 201 and the reference voltage Vin corresponding to the target value. It is a constant current circuit that maintains the current at a target value. Note that the feedback circuit includes a resistor R2 as an abnormal current detection element for detecting an abnormality of the light emitting element. The CPU 302 detects the voltage (failure detection voltage Vc) at the connection point between the light emitting diode 201 and the feedback circuit. In the present embodiment, the constant current detection element and the abnormal current detection element are realized by the same resistor R2. Thereby, a part of the drive current for driving the light emitting diode 201 does not flow out of the constant current drive circuit 301, and a decrease in the detection accuracy of the drive current value can be suppressed. The resistor R2 may be a fixed resistor, a variable resistor, or a semiconductor element.

[Failure judgment method]
FIG. 4 is a diagram showing a light emitting diode characteristic abnormality that has failed due to electrostatic breakdown. The horizontal axis indicates the forward voltage (hereinafter referred to as forward voltage) Vf of the light emitting diode 201. The vertical axis represents the forward current (hereinafter, forward current) If of the light emitting diode 201. L1 indicates the characteristics of a normal light emitting diode. L2 indicates the characteristics of the electrostatically broken light emitting diode.

  As indicated by the characteristic L1, in a normal light emitting diode, the forward current If does not flow until the forward voltage Vf exceeds a certain value. However, as indicated by the characteristic L2, the forward current If starts to flow even in a state where the forward voltage Vf is low in the electrostatically broken light emitting diode. This is because the current passing through the electrostatic breakdown portion of the semiconductor increases.

  FIG. 5 is a diagram showing the relationship between the forward current If and the light emission luminance of the light emitting diode. The horizontal axis represents the forward current If of the light emitting diode 201. The vertical axis represents the light emission luminance. L3 indicates the characteristics of a normal light emitting diode. L4 indicates the characteristics of the electrostatically broken light emitting diode.

  In a light-emitting diode that is electrostatically damaged, leakage current increases. Therefore, even if the forward current If same as the normal light emitting diode flows in the electrostatically broken light emitting diode, the light emitting luminance of the electrostatic broken light emitting diode is smaller than the light emitting luminance of the normal light emitting diode. If a circuit that maintains the forward current If constant as in the present invention is employed, the forward voltage Vf decreases when the light emission luminance of the light emitting diode 201 decreases.

  Incidentally, problems that may occur in the light emitting diode include short circuit between the two terminals of the light emitting diode and open (disconnection) in addition to electrostatic breakdown. When both terminals of the light emitting diode 201 are short-circuited due to dust or the like on the substrate, the failure detection voltage Vc increases.

  FIG. 6 is a diagram showing the relationship between the reference voltage Vin and the failure detection voltage Vc. The horizontal axis represents the reference voltage Vin. The vertical axis represents the failure detection voltage Vc. L5 indicates the characteristics of the normal light-emitting diode 201. L6 shows the characteristic of the light-emitting diode 201 electrostatically destroyed. L8 indicates the characteristic of the light emitting diode 201 in which both terminals are short-circuited.

  The CPU 302 uses the threshold voltages Vm1 and Vm3 to detect a failure related to electrostatic breakdown and a failure related to short circuit. As can be seen from FIG. 6, if the failure detection voltage Vc is equal to or higher than the threshold voltage Vm1 for determining abnormality and is equal to or lower than the threshold voltage Vm3, the CPU 302 can determine that electrostatic breakdown has occurred in the light emitting diode 201. . Further, the CPU 302 can determine that a short circuit has occurred if the failure detection voltage Vc exceeds Vm3. Note that the CPU 302 can determine that the failure is normal if the failure detection voltage Vc is less than Vm1.

  FIG. 7 is a diagram illustrating the relationship between the reference voltage and the control voltage Vb when a failure due to disconnection occurs. The horizontal axis represents the reference voltage Vin. The vertical axis represents the control voltage Vb. L9 indicates the characteristics of the normal light-emitting diode 201. L10 indicates the characteristics of the light emitting diode 201 in which the disconnection has occurred. Vm2 is a threshold voltage for determining disconnection.

  When a disconnection occurs in the light emitting diode 201, no current flows through the current detection resistor R2 and the transistor Tr included in the constant current drive circuit 301. Therefore, the control voltage Vb rises to a voltage that is the upper limit of the capability of the operational amplifier OP with respect to the reference voltage Vin. The CPU 302 compares the control voltage Vb with the threshold voltage Vm2 for determining abnormality, and determines that a disconnection has occurred if Vb exceeds Vm2.

  FIG. 8 is a block diagram of functions realized by the CPU 302 according to the embodiment. The CPU 302 implements the following functions by executing a computer program.

  The failure voltage detector 801 detects a failure detection voltage Vc that is a voltage in a part of the feedback circuit described above. The control voltage detector 802 detects a control voltage Vb that is a voltage in another part of the feedback circuit. The fault voltage detection unit 801 and the control voltage detection unit 802 are realized by an A / D converter built in the CPU 302. The abnormality detection unit 803 detects an abnormality of the light emitting diode 201 according to whether or not the voltage detected by the failure voltage detection unit 801 and the control voltage detection unit 802 deviates from a predetermined normal range.

  The abnormality detection unit 803 includes, for example, a first comparison unit 804, a second comparison unit 805, an electrostatic breakdown determination unit 806, a short determination unit 807, a third comparison unit 808, a disconnection determination unit 809, and a message creation unit 810. Yes. The first comparison unit 804 compares the failure detection voltage Vc detected by the failure voltage detection unit 801 with the first threshold voltage Vm1. The second comparison unit 805 compares the failure detection voltage Vc detected by the failure voltage detection unit 801 with a second threshold voltage Vm3 that is higher than the first threshold voltage Vm1. The electrostatic breakdown determination unit 806 determines that the light emitting diode 201 is normal if the failure detection voltage Vc is lower than the first threshold voltage Vm1. The electrostatic breakdown determination unit 806 determines that the light emitting diode 201 is electrostatically damaged when the failure detection voltage Vc is equal to or higher than the first threshold voltage Vm1 and equal to or lower than the second threshold voltage Vm3. If the failure detection voltage Vc exceeds the second threshold voltage Vm3, the short determination unit 807 determines that a short circuit has occurred in the light emitting diode 201. The first threshold voltage Vm1 is a voltage at which the original 102 can be read although the light-emitting diode 201 has failed. The second threshold voltage Vm3 is a voltage indicating that a failure requiring replacement of the light emitting diode 201 has occurred. The first threshold voltage Vm1 and the second threshold voltage Vm3 are determined empirically.

  The third comparison unit 808 compares the control voltage Vb detected by the control voltage detection unit 802 with the third threshold voltage Vm2. The disconnection determination unit 809 determines whether or not a disconnection relating to the light emitting diode 201 has occurred, depending on whether or not the control voltage Vb deviates from a predetermined relationship with respect to the reference voltage Vin. For example, if the control voltage Vb exceeds the third threshold voltage Vm2, the disconnection determination unit 809 determines that a disconnection related to the light emitting diode 201 has occurred. If the control voltage Vb is equal to or lower than the third threshold voltage Vm2, the disconnection determination unit 809 determines that no disconnection related to the light emitting diode 201 has occurred.

  The message creation unit 810 creates or selects a message according to the determination results of the electrostatic breakdown determination unit 806, the short determination unit 807, and the disconnection determination unit 809, and outputs the message to the display device 310. When electrostatic breakdown is detected, the message creation unit 810 creates a message indicating that the original can be read but the light source array unit needs to be replaced. When a short is detected, the message creation unit 810 creates a message indicating that the document cannot be read and the light source array unit needs to be replaced. Even when the disconnection is detected, the message creation unit 810 creates a message indicating that the document cannot be read and the light source array unit needs to be replaced. When no malfunction is detected, the message creation unit 810 displays a message indicating that the document can be read. When no malfunction is detected, the message creation unit 810 does not have to create a special message.

  FIG. 9 is a flowchart showing an abnormality detection process executed by the CPU 302 in the constant current drive circuit 301. The CPU 302 starts an abnormality detection process when the LED light source units 514 and 515 are turned on.

  In step S <b> 901, the CPU 302 lights and turns on the LED light source units 514 and 515, acquires the failure detection voltage Vc from the first A / D input port 304, and controls from the second A / D input port 305. The voltage Vb is acquired.

  In step S902, the CPU 302 compares the failure detection voltage Vc with the first threshold voltage Vm1, and determines whether the failure detection voltage Vc is less than the first threshold voltage Vm1. If the failure detection voltage Vc is less than the first threshold voltage Vm1, the process proceeds to step S903.

  In step S903, the CPU 302 compares the control voltage Vb with the third threshold voltage Vm2, and determines whether or not the control voltage Vb is equal to or lower than the third threshold voltage Vm2. If the control voltage Vb is equal to or lower than the third threshold voltage Vm2, the process proceeds to step S904.

  In step S904, the CPU 302 determines that any of the light emitting diodes 201 included in the LED light source units 514 and 515 is normal, and creates a message indicating that scanning is possible.

  In step S905, the CPU 302 causes the display device 310 to display a message indicating that scanning is possible. Further, the CPU 302 activates a motor for rotating each roller in order to start reading the document 102.

  On the other hand, if it is determined in step S903 that the control voltage Vb exceeds the third threshold voltage Vm2, the process proceeds to step S906. In step S <b> 906, the CPU 302 determines that a disconnection has occurred in any of the light emitting diodes 201 included in the LED light source units 514 and 515. Then, the CPU 302 creates a message indicating that scanning is impossible and the light source array unit needs to be replaced.

  In step S907, the CPU 302 causes the display device 310 to display a message indicating that scanning is impossible and the LED light source unit needs to be replaced. In addition, the CPU 302 turns off the LED light source units 514 and 515 and stops scanning the document 102. Further, the CPU 302 does not perform a scanning operation even when there is a scanning request from a user.

  On the other hand, if it is determined in step S902 that the failure detection voltage Vc is equal to or higher than the first threshold voltage Vm1, the process proceeds to step S908. In step S908, the CPU 302 compares the failure detection voltage Vc with the second threshold voltage Vm3, and determines whether the failure detection voltage Vc is equal to or lower than the second threshold voltage Vm3. If the failure detection voltage Vc is equal to or lower than the second threshold voltage Vm3, the process proceeds to step S909.

  In step S909, the CPU 302 determines that damage to the light emitting diode 201 is slight although electrostatic breakdown has occurred, and the document 102 can be scanned, but the light source array unit needs to be replaced. Create a message to indicate.

  In step S910, the CPU 302 causes the display device 310 to display a message indicating that the document 102 can be scanned but the light source array unit needs to be replaced.

  On the other hand, if it is determined in step S908 that the failure detection voltage Vc exceeds the second threshold voltage Vm3, the process proceeds to step S911. In step S911, the CPU 302 determines that a short circuit has occurred in the LED light source units 514 and 515, and creates a message indicating that scanning is impossible and the LED light source unit needs to be replaced.

  In step S912, the CPU 302 causes the display device 310 to display a message indicating that scanning is impossible and the LED light source unit needs to be replaced.

  As described above, the abnormality of the light emitting element can be detected easily and accurately by detecting the abnormality of the light emitting element according to the voltage in a part of the feedback circuit. If the failure detection voltage Vc is lower than the first threshold voltage Vm1, it is determined that the light emitting element is normal with respect to electrostatic breakdown or short circuit. On the other hand, if the failure detection voltage Vc is equal to or higher than the first threshold voltage and equal to or lower than the second threshold voltage, it is determined that the light emitting element is electrostatically destroyed. Therefore, electrostatic breakdown can be detected with high accuracy with a relatively simple configuration.

  Further, if the failure detection voltage Vc exceeds the second threshold voltage Vm3, it is determined that the light emitting element has a short circuit. Therefore, not only electrostatic breakdown but also short circuit can be detected with high accuracy.

  Note that the first threshold voltage Vm1 may be set to a voltage at which a document can be read although the light emitting element is faulty. The second threshold voltage Vm3 may be set to a voltage indicating that a failure requiring replacement of the light emitting element has occurred. This is because the light emission amount of the light emitting element does not decrease so that the LED light source unit needs to be replaced as soon as electrostatic breakdown occurs. However, in the long term, it is desirable to prompt the user to replace the LED light source unit because the amount of light emitted from the light emitting element decreases as the image quality is affected. For this reason, it is desirable to set the threshold voltage as described above.

  Furthermore, in the present embodiment, depending on whether or not the control voltage Vb, which is a voltage in another part of the feedback circuit, deviates from a predetermined relationship with respect to the reference voltage Vin set in the feedback circuit. The disconnection of the light emitting element can be detected. As described above, in the present embodiment, in addition to electrostatic breakdown and short circuit, disconnection (open) can be detected with high accuracy.

  Note that the feedback circuit compares the terminal voltage (control voltage Vb) of the constant current detecting element connected in series with the light emitting element with the reference voltage Vin corresponding to the target value, thereby making the current flowing through the light emitting element constant. This is a constant current drive circuit that maintains a constant current. In the constant voltage drive circuit, since the drive current is not constant, a large margin is required for the threshold for detecting a voltage indicating abnormality. On the other hand, in the constant current drive circuit, since the drive current can be made constant, a large margin can be reduced in the threshold value for detecting a voltage indicating abnormality.

  Furthermore, in this embodiment, the constant current detection element and the abnormal current detection element are realized by the same element. Thereby, a part of the drive current for driving the light emitting element does not flow out of the constant current control circuit, and a decrease in detection accuracy of the drive current value can be suppressed.

DESCRIPTION OF SYMBOLS 100 Image reading apparatus 101 Document stand 102 Document 120, 121, 122 Reflection mirror 125 Condensing lens 126 Photoelectric conversion element 200 Printed circuit board 201 Light emitting diode 202 Cathode electrode wiring 203 Anode electrode wiring 300 Fault detection circuit 301 Constant current drive circuit 302 CPU
303 D / A output port 304 First A / D input port 305 Second A / D input port 514, 515 LED light source unit

Claims (8)

An image reading device,
A light emitting element for illuminating the document;
A feedback circuit for maintaining the current flowing through the light emitting element at a target value;
Voltage detecting means for detecting a voltage at a connection point between the feedback circuit and the light emitting element;
First comparison means for comparing the voltage detected by the voltage detection means with a first threshold voltage;
Second comparison means for comparing the voltage detected by the voltage detection means with a second threshold voltage higher than the first threshold voltage;
And an electrostatic breakdown determination unit that determines that the light emitting element is electrostatically destroyed if the voltage detected by the voltage detection unit is not less than the first threshold voltage and not more than the second threshold voltage. images reader for. If exceeded is detected voltage and the second threshold voltage by the voltage detection means, according to claim 1, further comprising a short determining means for determining a short circuit occurs in the light emitting element Image reading apparatus. An image reading device,
A light emitting element for illuminating the document;
A feedback circuit for maintaining the current flowing through the light emitting element at a target value;
Voltage detecting means for detecting a voltage at a connection point between the feedback circuit and the light emitting element;
First comparison means for comparing the voltage detected by the voltage detection means with a first threshold voltage;
Second comparison means for comparing the voltage detected by the voltage detection means with a second threshold voltage higher than the first threshold voltage;
If the voltage detected by the voltage detection means is not less than the first threshold voltage and not more than the second threshold voltage, a display that displays a message indicating that the document can be read but the light emitting element needs to be replaced. images reader, characterized by further comprising a means. The display means, according to claim 3, characterized in that the voltage detected by said voltage detecting means if more than the second threshold voltage, and displays a message indicating that reading of the document is impossible Image reading apparatus. The feedback circuit is
A circuit that maintains a constant current flowing through the light emitting element by comparing a terminal voltage of a constant current detecting element connected in series with the light emitting element and a reference voltage corresponding to the target value. It claims 1 to an image reading apparatus according to any one of 4. An image reading device,
A light emitting element for illuminating the document;
A feedback circuit for maintaining the current flowing through the light emitting element at a target value;
Voltage detecting means for detecting a voltage at a connection point between the feedback circuit and the light emitting element;
An abnormality detecting means for detecting an abnormality of the light emitting element;
With
The feedback circuit is
A circuit that maintains a constant current flowing in the light emitting element by comparing a terminal voltage of a constant current detecting element connected in series with the light emitting element and a reference voltage corresponding to the target value;
Further, the feedback circuit includes a current control element that controls a current flowing through the light emitting element by a control voltage according to a comparison result between a terminal voltage of the constant current detecting element and the reference voltage,
The image reading apparatus includes a control voltage detection unit that detects a control voltage according to a comparison result in the feedback circuit,
The abnormality detecting means relates to the light emitting element depending on whether or not the voltage detected by the control voltage detecting means deviates from a predetermined relationship with respect to a reference voltage set in the feedback circuit. images reader, characterized in that it comprises the disconnection determination means for determining whether disconnection is occurring.   The abnormality detection means includes
  First comparison means for comparing the voltage detected by the voltage detection means with a first threshold voltage;
  Second comparison means for comparing the voltage detected by the voltage detection means with a second threshold voltage higher than the first threshold voltage;
  An electrostatic breakdown determining means for determining that the light emitting element is electrostatically destroyed if the voltage detected by the voltage detecting means is not less than the first threshold voltage and not more than the second threshold voltage;
The image reading apparatus according to claim 6, further comprising: The abnormality detection means includes
First comparison means for comparing the voltage detected by the voltage detection means with a first threshold voltage;
Second comparison means for comparing the voltage detected by the voltage detection means with a second threshold voltage higher than the first threshold voltage;
If the voltage detected by the voltage detection means is not less than the first threshold voltage and not more than the second threshold voltage, a display that displays a message indicating that the document can be read but the light emitting element needs to be replaced. Means and
The image reading apparatus according to claim 6, further comprising:

Images