JP3963061B2 - Image reading apparatus and drive control method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image reading apparatus and a drive control method thereof, and more particularly, to an image reading apparatus that includes a photosensor array configured by two-dimensionally arranging thin film transistors having a so-called double gate structure and reads a two-dimensional image such as a fingerprint. And a drive control method thereof.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a structure having a photosensor array configured by arranging photoelectric conversion elements (photosensors) in a matrix form as a two-dimensional image reading device that reads a printed matter, a photograph, or the shape of fine irregularities such as fingerprints There are things. In general, a solid-state imaging device such as a CCD (Charge Coupled Device) is used as such a photosensor array.
As is well known, a CCD has a configuration in which photosensors such as photodiodes and thin film transistors (TFTs) are arranged in a matrix, and is generated corresponding to the amount of light irradiated to the light receiving portion of each photosensor. The charge amount of the electron-hole pair is detected by a horizontal scanning circuit and a vertical scanning circuit, and the brightness of the irradiation light is detected.
[0003]
In such a photosensor system using a CCD, it is necessary to individually provide a selection transistor for selecting each scanned photosensor, so that the system itself becomes larger as the number of pixels increases. Have the problem of
Therefore, in recent years, as a configuration for solving such problems, a thin film transistor having a so-called double gate structure (hereinafter referred to as a double gate type photosensor) in which the photosensor itself has a photosense function and a select transistor function. ) Is applied to an image reading apparatus to try to reduce the size of the system and increase the density of pixels.
[0004]
In general, an image reading apparatus using such a photosensor forms a photosensor array by forming a double gate type photosensor having a top gate electrode and a bottom gate electrode on one side of a glass substrate in a matrix. For example, the irradiation light is irradiated from the light source provided on the back side of the glass substrate, and the reflected light corresponding to the image pattern of the two-dimensional image such as a fingerprint placed on the detection surface above the photosensor array is doubled. It is detected as light / dark information by a gate type photosensor and reads a two-dimensional image.
Here, the image reading operation by the photosensor array is performed by the carrier (correction) stored in each double-gate photosensor during the light accumulation period from the end of initialization by applying the reset pulse until the reading pulse is applied. Brightness / darkness information is detected based on the accumulated amount of holes). Note that specific structures and operations of the double gate transistor and the photosensor array will be described later.
[0005]
[Problems to be solved by the invention]
The photo sensor system to which the double gate type photo sensor as described above is applied has the following problems.
That is, in a sensor system to which a double gate type photosensor is applied, an image is read based on the accumulated amount of carriers (holes) for each photosensor during the light accumulation period. In order to read (a two-dimensional image) satisfactorily, it is necessary to appropriately set the light accumulation period (that is, corresponding to reading sensitivity).
[0006]
Here, since the light accumulation period greatly depends on ambient conditions such as environmental illuminance, conventionally, a standard sample or the like is placed on the detection surface before starting the image reading operation of the subject image, and the light accumulation period Is used in a plurality of stages to perform a reading operation (so-called reading sensitivity setting operation), and based on the reading result, a method for obtaining an optimum light accumulation period according to ambient conditions such as environmental illumination is employed.
However, in the photosensor system according to the related art as described above, during the reading sensitivity setting operation and the image reading operation of the subject image subsequently performed, the glass placed on the object placed on the detection surface There is a problem that it is necessary to continuously or continuously irradiate irradiation light from a light source provided on the back side of the substrate, resulting in an increase in power consumption. In particular, such a power consumption problem has become a prominent and serious problem when the image reading apparatus is applied to a portable information terminal or the like that is strongly required to reduce power consumption.
[0007]
Therefore, the present invention solves the above-described problems, and reduces power consumption in the reading sensitivity setting operation for setting the optimum reading sensitivity of the photosensor and the image reading operation of the subject image, so that it can be favorably used for a portable information terminal or the like. An object of the present invention is to provide an image reading apparatus and a drive control method thereof that can be applied.
[0008]
[Means for Solving the Problems]
An image reading apparatus according to a first aspect of the present invention is directed to a photosensor array configured by two-dimensionally arranging a plurality of photosensors, and an object placed on the front side of the photosensor array. A light source that emits irradiation light from the back side of the sensor array, and the light source is turned off. Irradiated from the front side of the photosensor array Based on the environmental illuminance determining means for determining the environmental illuminance, and the lighting state of the light source based on the environmental illuminance. Turns on or off At least one of the lighting state setting means to be set and the ambient illuminance determination or after the lighting state is set, the image reading sensitivity in the photosensor array is set. In multiple stages While changing, read a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors, Different Based on the image pattern of the subject image for each image reading sensitivity, For reading the subject image Reading sensitivity setting means for obtaining an optimum image reading sensitivity; and image reading means for reading a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors based on the optimum image reading sensitivity. It is characterized by doing.
[0009]
Claim 2 The image reading apparatus according to the invention is the image reading apparatus according to claim 1, wherein the ambient illuminance determining means maintains the light source in a light-off state, and the subject is placed on the front side of the photosensor array. In this state, a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors is read, and an optimum image reading sensitivity is obtained based on the image pattern of the subject image for each image reading sensitivity, and the image It is characterized in that the ambient illuminance is determined based on a threshold value set in advance for the reading sensitivity.
[0010]
Claim 3 The image reading apparatus according to claim 1 is the image reading apparatus according to claim 1, wherein the environmental illuminance determination means is provided separately from the photosensor array on which the subject is placed. The ambient illuminance detection unit includes at least one photosensor, and the ambient illuminance is determined based on a threshold value set in advance with respect to the output voltage of the photosensor. Claim 4 An image reading apparatus according to the invention described in claims 1 to 3 In the image reading device according to any one of the above, the image reading device is connected to the first electrode in the photosensor array. A reset pulse is applied to initialize the photosensor, and the first electrode Be applied Of signal voltage Effective voltage It was set according to the sensitivity characteristics of the photosensor Applying a first signal voltage to an optimum value and applying to the second electrode in the photosensor array A read pulse is applied to read the subject image and applied to the second electrode Be applied Of signal voltage Effective voltage It was set according to the sensitivity characteristics of the photosensor The first to optimize 2 It is characterized by comprising effective voltage adjusting means for applying the above signal voltage.
[0011]
Claim 5 An image reading apparatus according to the invention described in claim 4 In the image reading apparatus described above, the photosensor includes a source electrode and a drain electrode formed with a channel region made of a semiconductor layer interposed therebetween, and a top formed at least above and below the channel region via an insulating film, respectively. A double gate structure including a gate electrode and a bottom gate electrode, the top gate electrode as the first electrode, the reset pulse applied, the bottom gate electrode as the second electrode, By applying a read pulse, a voltage corresponding to the charge accumulated in the channel region is output during a charge accumulation period from the end of initialization to the application of the read pulse.
[0012]
Claim 6 The image reading apparatus drive control method according to the invention described above is directed to a photosensor array configured by two-dimensionally arranging a plurality of photosensors, and a subject placed on the front side of the photosensor array. And a light source that emits irradiation light from the back side of the photosensor array, wherein the light source is turned off. Irradiated from the front side of the photosensor array The procedure for executing the environmental illumination determination operation for determining the environmental illumination and the lighting state of the light source based on the environmental illumination Turns on or off At least one of the procedure for executing the lighting state setting operation to be set and the ambient illuminance determination or after the lighting state setting, the image reading sensitivity in the photosensor array is set. In multiple stages While changing, read a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors, Different Based on the image pattern of the subject image for each image reading sensitivity, For reading the subject image A procedure for executing a reading sensitivity setting operation for obtaining an optimum image reading sensitivity, and an image reading operation for reading a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors based on the optimum image reading sensitivity. And a procedure for executing.
[0013]
Claim 7 A drive control method for an image reading apparatus according to the invention described in claim 6 In the drive control method of the image reading apparatus described above, the procedure of executing the environmental illuminance determination operation is performed in a state where the light source is maintained in an extinguished state and the subject is placed on the front side of the photosensor array. A subject image composed of pixels corresponding to a two-dimensionally arranged photosensor is read, an optimum image reading sensitivity is obtained based on the image pattern of the subject image for each image reading sensitivity, and the image reading sensitivity is It is characterized in that the ambient illuminance is determined based on a preset threshold value.
[0014]
Claim 8 A drive control method for an image reading apparatus according to the invention described in claim 6 In the drive control method for the image reading device described above, the procedure for executing the environmental illuminance determination operation is provided in an environmental illuminance detection unit provided independently of the photosensor array on which the subject is placed. It is characterized in that the environmental illuminance is determined based on a threshold value set in advance for the output voltage of the photosensor. Claim 9 A drive control method for an image reading apparatus according to the invention described in claim 6 Thru 8 The drive control method for the image reading device according to any one of the above, wherein the drive control method for the image read device is applied to the first electrode in the photosensor array. A reset pulse is applied to initialize the photosensor, and the first electrode Be applied Of signal voltage Effective voltage It was set according to the sensitivity characteristics of the photosensor Applying a first signal voltage to an optimum value and applying to the second electrode in the photosensor array A read pulse is applied to read the subject image and applied to the second electrode Be applied Of signal voltage Effective voltage It was set according to the sensitivity characteristics of the photosensor The first to optimize 2 The method includes a procedure for executing an effective voltage adjustment operation for applying the signal voltage.
[0015]
Claim 10 A drive control method for an image reading apparatus according to the invention described in claim 9 In the drive control method for an image reading device described above, the photosensor includes a source electrode and a drain electrode that are formed with a channel region made of a semiconductor layer interposed therebetween, and at least above and below the channel region via an insulating film, respectively. A double gate structure including a top gate electrode and a bottom gate electrode formed, the reset pulse is applied using the top gate electrode as the first electrode, and the bottom gate electrode is defined as the second gate electrode. By applying the readout pulse as an electrode, a voltage corresponding to the charge accumulated in the channel region is output during a charge accumulation period from the end of initialization to the application of the readout pulse.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of an image reading apparatus and a drive control method thereof according to the present invention will be described in detail.
First, a double gate transistor applied to an image reading apparatus according to the present invention will be described with reference to the drawings.
FIG. 1 is a schematic cross-sectional view showing the structure of a double gate transistor.
As shown in FIG. 1A, a double-gate photosensor 10 includes a semiconductor layer (channel layer) 11 such as amorphous silicon in which electron-hole pairs are generated when visible light is incident, and a semiconductor layer 11. N provided at both ends of each ⁺ Silicon layers 17, 18 and n ⁺ A source electrode 12 and a drain electrode 13 formed on the silicon layers 17 and 18, and a top gate formed above the semiconductor layer 11 (above the drawing) via a block insulating film 14 and an upper (top) gate insulating film 15. The electrode 21 and a bottom gate electrode 22 formed below the semiconductor layer 11 (downward in the drawing) via a lower (bottom) gate insulating film 16 are configured.
[0017]
In FIG. 1A, the top gate electrode 21, the top gate insulating film 15, the bottom gate insulating film 16, and the protective insulating film 20 provided on the top gate electrode 21 all excite the semiconductor layer 11. The bottom gate electrode 22 is made of a material that blocks the transmission of visible light while being made of a material having a high transmittance with respect to visible light. Have.
That is, the double-gate photosensor 10 uses the semiconductor layer 11 as a common channel region, the upper MOS transistor formed by the semiconductor layer 11, the source electrode 12, the drain electrode 13, and the top gate electrode 21, the semiconductor layer 11, and the source. A combined structure of two MOS transistors including a lower MOS transistor formed by the electrode 12, the drain electrode 13, and the bottom gate electrode 22 is formed on a transparent insulating substrate 19 such as a glass substrate.
Such a double gate type photosensor 10 is generally represented by an equivalent circuit as shown in FIG. Here, TG is a top gate terminal, BG is a bottom gate terminal, S is a source terminal, and D is a drain terminal.
[0018]
Next, a photo sensor system configured by two-dimensionally arranging the above-described double gate type photo sensors will be briefly described with reference to the drawings.
FIG. 2 is a schematic configuration diagram of a photosensor system configured by two-dimensionally arranging double gate type photosensors.
As shown in FIG. 2, the photosensor system is roughly divided into a photosensor array 100 in which a large number of double-gate photosensors 10 are arranged in a matrix of, for example, n rows × m columns, and each double-gate photosensor. 10 top gate terminals TG and bottom gate terminals BG connected in the row direction, respectively, and a top gate driver 111 and a bottom gate connected to the top gate line 101 and the bottom gate line 102, respectively. The driver 112 includes a data line 103 in which the drain terminals D of the double-gate photosensors are connected in the column direction, and an output circuit unit 113 connected to the data line 103. Here, φtg and φbg are control signals for generating reset pulses φT1, φT2,... ΦTi,... ΦTn and read pulses φB1, φB2,. This is a precharge signal for controlling the timing of application.
[0019]
In such a configuration, a photo sensing function is realized by applying a voltage from the top gate driver 111 to the top gate terminal TG, and a voltage is applied from the bottom gate driver 112 to the bottom gate terminal BG, via the data line 103. A selective reading function is realized by taking the detection signal into the output circuit unit 113 and outputting it as serial data (Vout).
[0020]
Next, a drive control method for the above-described photosensor system will be described with reference to the drawings.
FIG. 3 is a timing chart showing an example of a drive control method of the photo sensor system, FIG. 4 is an operation conceptual diagram of a double gate type photo sensor, and FIG. 5 is a light response characteristic of an output voltage of the photo sensor system. FIG.
First, in the reset operation, as shown in FIGS. 3 and 4A, a pulse voltage (reset pulse; for example, a high level of Vtg = + 15V) φTi is applied to the top gate line 101 of the i-th row, Carriers (holes) accumulated in the semiconductor layer of each double-gate photosensor 10 are released (reset period Treset).
[0021]
Next, in the optical storage operation, as shown in FIGS. 3 and 4B, the reset operation is completed by applying a low level (for example, Vtg = −15 V) bias voltage φTi to the top gate line 101. Then, the light accumulation period Ta by the carrier accumulation operation starts. In the light accumulation period Ta, carriers are accumulated in the channel region according to the amount of light incident from the top gate electrode side.
In the precharge operation, a predetermined voltage (precharge voltage) Vpg is applied to the data line 103 based on the precharge signal φpg in parallel with the light accumulation period Ta as shown in FIGS. Is applied to hold the charge in the drain electrode 13 (precharge period Tprch).
[0022]
Next, in the read operation, as shown in FIGS. 3 and 4D, after the precharge period Tprch has elapsed, a high level (for example, Vbg = + 10 V) bias voltage (read selection signal; By applying φBi (hereinafter referred to as a read pulse), the double gate photosensor 10 is turned on (read period Tread).
Here, in the read period Tread, carriers (holes) accumulated in the channel region work in a direction to relax Vtg (−15 V) applied to the reverse polarity top gate terminal TG. An n channel is formed by Vbg, and the data line voltage VD of the data line 103 tends to gradually decrease from the precharge voltage Vpg with time as shown in FIG. 5A in accordance with the drain current.
[0023]
That is, when the light accumulation state in the light accumulation period Ta is dark and carriers (holes) are not accumulated in the channel region, as shown in FIGS. 4 (e) and 5 (a), the top gate By applying a negative bias to TG, the positive bias of the bottom gate BG is canceled, the double-gate photosensor 10 is turned off, and the drain voltage, that is, the voltage VD of the data line 103 is held almost as it is. Become.
On the other hand, when the light accumulation state is a bright state, as shown in FIGS. 4D and 5A, carriers (holes) corresponding to the amount of incident light are trapped in the channel region. The double gate type photosensor 10 is turned on by the positive bias of the bottom gate BG by acting to cancel the negative bias of the gate TG. Then, the voltage VD of the data line 103 decreases according to the ON resistance corresponding to the incident light quantity.
[0024]
Therefore, as shown in FIG. 5A, the change tendency of the voltage VD of the data line 103 is that the read pulse φBi is applied to the bottom gate BG from the end of the reset operation by applying the reset pulse φTi to the top gate TG. It is deeply related to the amount of light received in the time until application (light accumulation period Ta), and shows a tendency to gradually decrease when the number of accumulated carriers is small, and steep when there are many accumulated carriers. Shows a tendency to decrease. Therefore, by detecting the voltage VD of the data line 103 after the elapse of a predetermined time from the start of the read period Tread or by using the predetermined threshold voltage as a reference, the time until the voltage is detected is detected. By doing so, the amount of irradiation light is converted.
[0025]
The above-described series of image reading operations is set as one cycle, and the double gate photosensor 10 is operated as a two-dimensional sensor system by repeating the same processing procedure for the i + 1th row double gate photosensor 10. Can do.
In the timing chart shown in FIG. 3, a low level (for example, Vbg = 0 V) is applied to the bottom gate line 102 after the precharge period Tprch has elapsed, as shown in FIGS. Is continued, the double-gate photosensor 10 continues to be in the OFF state, and the voltage VD of the data line 103 holds the precharge voltage Vpg as shown in FIG. 5B. As described above, the selection function of selecting the readout state of the double gate type photosensor 10 is realized by the application state of the voltage to the bottom gate line 102.
[0026]
FIG. 6 is a cross-sectional view of a main part of a two-dimensional image reading apparatus to which the above-described photosensor system is applied.
As shown in FIG. 6, in an image reading apparatus that reads a two-dimensional image such as a fingerprint, light emitted from a backlight 30 including a light guide plate 31 and a light source 32 provided below the glass substrate 19 of the double gate transistor 10. R1 is incident, and the irradiation light R1 passes through the transparent insulating substrate 19 and the insulating films 15, 16, and 20 excluding the formation region of the double gate transistor 10, and the object (finger) on the protective insulating film 20 40 is irradiated.
Then, the reflected light R2 corresponding to the reflectance determined by the image pattern (or uneven pattern) of the subject 40 passes through the transparent insulating films 20, 15, 14 and the top gate electrode 21 and enters the semiconductor layer 11. Thus, carriers corresponding to the image pattern of the subject 40 are accumulated, and the image pattern of the subject 40 can be read as light and dark information according to the series of drive control methods described above.
[0027]
<First Embodiment>
Next, a first embodiment of an image reading apparatus according to the present invention will be described with reference to the drawings. In the embodiment described below, the photogate function is realized by applying the above-described double-gate photosensor as a photosensor, and applying a voltage using the top gate electrode as the first electrode. A description will be given assuming that the function of reading the amount of charge accumulated in the channel region is realized by applying a voltage using the gate electrode as the second electrode.
FIG. 7 is a schematic configuration diagram showing the first embodiment of the image reading apparatus according to the present invention. Here, description will be made with reference to the configurations shown in FIGS. 1, 2, and 6 as appropriate. Further, the same components as those in the photosensor system shown in FIG. 2 will be described with the same reference numerals.
[0028]
As shown in FIG. 7, the image reading apparatus according to the present embodiment includes a photosensor array 100 configured by two-dimensionally arranging the double gate type photosensors 10 shown in FIG. 1, and a double gate type photosensor 10. A top gate driver 111 that applies a predetermined top gate voltage (reset pulse) to the top gate terminal TG at a predetermined timing, and a predetermined bottom gate voltage to the bottom gate terminal BG of the double gate photosensor 10 at a predetermined timing. An output circuit unit including a bottom gate driver 112 for applying a (read pulse), a column switch 114 for applying a precharge voltage to the double gate photosensor 10 and reading a data line voltage, a precharge switch 115, and an amplifier 116. 113 and the read data voltage (analog) Signal) is converted to image data composed of digital signals, and is disposed on the back side of the glass substrate on which the photosensor array 100 is formed, and is applied to the subject. The backlight (light source) 118 that irradiates the irradiation light of the object, the subject image reading operation control (image reading operation) by the photosensor array 100, the exchange of data with the external function unit 200, and the like, and the ambient illuminance in the present invention Related to controller 120 with function to execute and control judgment operation, lighting state setting operation, reading sensitivity setting operation, effective voltage adjustment operation, setting of read image data and reading sensitivity, judgment of environmental illuminance, adjustment of effective voltage, etc. And a RAM 130 for storing data to be stored.
[0029]
Here, the configuration including the photosensor array 100, the top gate driver 111, the bottom gate driver 112, and the output circuit unit 113 (the column switch 114, the precharge switch 115, and the amplifier 116) is substantially the same as the photosensor system shown in FIG. Since it has the same configuration and function, detailed description thereof is omitted. The backlight 118 is composed of a light source that emits monochromatic light having a predetermined wavelength and a synthetic resin plate such as transparent acrylic. The backlight 118 uniformly scatters the incident light emitted from the light source within the plate. This is a surface light source configured to include a light guide plate that irradiates the detection target placed on the detection surface above the sensor array 100 substantially uniformly.
[0030]
The controller 120 outputs control signals φtg and φbg to the top gate driver 111 and the bottom gate driver 112, so that each double gate type photo constituting the photosensor array 100 is formed from each of the top gate driver 111 and the bottom gate driver 112. A predetermined signal voltage (reset pulse φTi, readout pulse φBi) is applied to the top gate terminal TG and the bottom gate terminal BG of the sensor, and a control signal φpg is output to the precharge switch 115, whereby a precharge voltage is applied to the data line. Vpg is applied to control the execution of the subject image reading operation.
[0031]
Further, the controller 120 converts the data line voltage VD read from the double gate type photosensor 10 via the column switch 114 into a digital signal via the amplifier 116 and the A / D converter 117, and as image data. Entered. The controller 120 performs predetermined image processing on the image data, writes to and reads out from the RAM 130, and performs external processing on the external function unit 200 that executes predetermined processing such as image data collation and processing. It also has a function as an interface.
[0032]
Further, the controller 120 can read the subject image optimally according to the ambient illuminance such as external light by setting and controlling the control signals φtg and φbg output to the top gate driver 111 and the bottom gate driver 112. Sensitivity, that is, a function for setting the optimum light accumulation period Ta of the double-gate photosensor 10, a function for determining the environmental illuminance based on the optimum light accumulation period, and a subject image reading operation based on the environmental illuminance It has a function of setting and controlling the lighting state of the backlight and a function of adjusting the bias of the effective voltage applied to the top gate TG and the bottom gate BG of the double gate type photosensor 10 to an optimum value. Therefore, the controller 120 constitutes environmental illuminance determination means, lighting state setting means, reading sensitivity setting means, image reading means, and effective voltage adjustment means.
[0033]
Next, a drive control method for the image reading apparatus according to the present embodiment will be described with reference to the drawings.
FIG. 8 is a flowchart illustrating a processing procedure of the drive control method for the image reading apparatus according to the present embodiment. FIG. 9 is a timing chart illustrating an example of the drive control method for the image reading apparatus according to the present embodiment. FIG. 10 is a conceptual diagram showing the situation of external light passing through the subject, and FIG. 11 is measurement data showing the correspondence between the ambient illuminance and the light accumulation period. Here, the drive control procedure and method will be described with reference to the configuration of the image reading apparatus shown in FIGS. 2 and 7 as appropriate.
As shown in FIGS. 8 and 9, the drive control method of the image reading apparatus according to the present embodiment includes an environment illuminance determination operation, a lighting state setting operation, a reading sensitivity setting operation, an image reading operation, and an effective voltage adjustment operation. Each operation control is performed by the controller 120.
Each processing operation will be specifically described below.
[0034]
<Environmental illumination judgment operation / lighting state setting operation>
As shown in FIGS. 8 and 9, the ambient illuminance determination operation according to the present embodiment first sets the backlight 118 to the off state with a subject such as a finger placed on the detection surface above the photosensor array 100. After the control (procedure S11), the reset pulses φT1 and φT2 are sequentially applied to each of the top gate lines 101 connecting the top gate terminals TG of the double gate type photosensor 10 in the row direction at a predetermined delay time Tdly. ... ΦTn is applied to start the reset period Trst, and the double-gate photosensor 10 for each row is initialized.
Here, the reset pulses φT1, φT2,... ΦTn are pulse signals whose high level is the signal voltage Vtgh and low level is the signal voltage Vtgl, and other than the timing at which the high level Vtgh reset pulses φT1, φT2,. In this state, a low level signal voltage Vtgl is applied.
[0035]
Next, the reset pulses φT1, φT2,... ΦTn fall, and the reset period Trst ends. ₁ , TA ₂ ... TA _n Are sequentially started, and charges (holes) are generated and accumulated in the channel region in accordance with the amount of light incident from the top gate electrode side of the double-gate photosensor 10 for each row.
The light accumulation period TA set for each row ₁ , TA ₂ ... TA _n As shown in FIG. 9, after the last reset pulse φTn falls, the precharge signal φpg and the read pulses φBn,... ΦB2 are changed stepwise by a predetermined delay time Tdly for each row. φB1 is sequentially applied to start the readout period Trd, and the voltage change VD corresponding to the electric charge accumulated in the double gate type photosensor 10 is read out via the data line 103 by the output circuit unit 113, and sequentially in the RAM 130. Is remembered.
[0036]
Here, the read pulses φB1, φB2,... ΦBn are pulse signals whose high level is the signal voltage Vbgh and low level is the signal voltage Vbgl, and other than the timing at which the high level Vbgh read pulses φB1, φB2,. Then, the low level signal voltage Vbgh is applied.
Note that, in the same way as the photo sensor system described above, the method for detecting the amount of irradiation light is to detect the voltage value after a predetermined time has elapsed from the start of the reading period Trd when the voltage VD of each data line 103 decreases. Or by detecting the time until the voltage value is reached with reference to a predetermined threshold voltage, it is converted into the amount of irradiation light.
Therefore, according to such an environment illumination determination operation, the light accumulation period TA set for each row is set. ₁ , TA ₂ ... TA _n Since the mutual increases at a time interval twice as long as the predetermined delay time Tdly, image data read with a read sensitivity set with a sensitivity adjustment width equal to or more than the number of rows can be obtained by the reading operation of one screen. Then, based on this image data, the controller 120 extracts a light accumulation period in which the contrast of the light and dark pattern is maximized, and determines an optimum light accumulation period Ta used for determination of the environmental illuminance.
[0037]
Here, when the backlight 118 is turned off, as shown in FIG. 10, external light (white light) irradiated from above the subject, for example, the finger 40 a placed on the detection surface on the photosensor array 100. R1 causes light transmission in the thin part of the finger 40a, and the light R2 incident on the skin surface layer 40b repeats propagation and scattering in the red pigment contained in the skin, thereby producing white light. Since the red visible light R3 having a long wavelength is mainly emitted from the surface of the finger 40a to the photosensor array 100, the light accumulation period Ta obtained by the above series of image reading procedures is transmitted through the subject and transmitted to the photosensor. This can be attributed to the contribution of external light (environmental illuminance) such as natural light or artificial light reaching the array 100.
Therefore, as a result of intensive studies on the relationship between the ambient illuminance and the optimum light accumulation period during which the subject image can be satisfactorily read based on such an idea, as shown in FIG. 11, approximately 1000 lux (Lx) or more is obtained. When the ambient illuminance is reduced, the light accumulation period is shortened, and the contribution of the ambient illuminance to the reading of the subject image is increased (dominated).
[0038]
That is, in an environment where the ambient illuminance is 1000 lux or more, the external light transmitted through the subject is larger in the image reading operation by the photosensor array 100 than the reflected light on the subject surface with respect to the light irradiated from the backlight. Therefore, even if the backlight is set to the off state, the subject image can be satisfactorily read only with outside light.
Therefore, the optical storage period determined by the above-described environmental illuminance determination operation by holding the reference table and the approximate expression having the correspondence relationship between the environmental illuminance and the optical storage period shown in FIG. 11 in the controller 120 and the RAM 130. Based on Ta, the ambient illuminance can be extracted or calculated backward (step S12).
[0039]
Next, it is determined whether or not the calculated environmental illuminance is equal to or higher than a predetermined threshold level (step S13). If the environmental illuminance is equal to or higher than the threshold level, in all operations for reading the subject image thereafter, The backlight is set and controlled to be turned off.
On the other hand, if the ambient illuminance is less than or equal to the threshold level, the backlight is set and controlled to be lit in all subsequent operations for reading the subject image (step S14). Here, for example, the above-mentioned 1000 lux can be applied as the threshold level serving as a criterion for determining the ambient illuminance.
Note that the reading sensitivity set in the above-described series of image reading procedures, that is, the light accumulation period TA set for each row. ₁ , TA ₂ ... TA _n The delay time interval may be longer than the light accumulation time set in the read sensitivity setting operation described later, or the set number may be small. As shown in FIG. 11, the relationship (change tendency) between the ambient illuminance and the optimum light accumulation period is extremely gradual, so it is only necessary to roughly determine whether or not it is approximately 1000 lux or more. It is.
[0040]
<Reading sensitivity setting operation>
As shown in FIGS. 8 and 9, the reading sensitivity setting operation (procedure S15) in the present embodiment has a processing procedure equivalent to a series of image reading procedures executed in the above-described environmental illuminance determination operation.
First, in a state where a subject such as a finger is placed on the detection surface above the photosensor array 100, the backlight 118 is set to a lighting state, and then a predetermined amount is set with respect to the top gate line 101 of the photosensor array 100. Reset pulses φT1, φT2,... ΦTn are applied at time intervals of the delay time Tdly to initialize the double gate photosensor 10 for each row.
Next, when the reset period Trst ends, the light accumulation period TB ₁ , TB ₂ ... TB _n Are sequentially started, and charges (holes) are generated and accumulated in the channel region in accordance with the amount of light incident on the double-gate photosensor 10 for each row.
[0041]
Then, by applying the precharge signal φpg and the readout pulses φBn,... ΦB2, φB1, the light accumulation period TB set for each row. ₁ , TB ₂ ... TB _n The voltage change VD corresponding to the electric charge accumulated in is read through the output circuit unit 113 and stored in the RAM 130 sequentially.
Therefore, according to such a reading sensitivity setting operation, the light accumulation period TB set for each row is set. ₁ , TB ₂ ... TB _n Since the mutual increases at a time interval twice as long as the predetermined delay time Tdly, image data read with a read sensitivity set with a sensitivity adjustment width equal to or more than the number of rows can be obtained by the reading operation of one screen. Then, based on the image data, the controller 120 extracts a light accumulation period in which the contrast of the light and dark pattern is maximized, and an optimum light accumulation period (that is, optimum reading sensitivity) in an image reading operation of a subject image described later. Tb is determined.
[0042]
In the present embodiment, the backlight 118 arranged on the back side of the photosensor array 100 is turned on (that is, when the ambient illuminance is equal to or lower than the threshold level in step S13) and is placed on the detection surface. In the above description, the subject image is read in advance using the reflected light reflected from the surface of the subject, but the backlight 118 is turned off (that is, when the ambient illuminance is equal to or higher than the threshold level in step S13). The reading sensitivity setting process may be performed. In this case, the light accumulation period TA in the environmental illuminance determination operation described above. ₁ , TA ₂ ... TA _n Is equivalent to the reading sensitivity setting operation, the optimal light accumulation period Ta determined in the environmental illuminance determination operation may be set as it is as the light accumulation period in the image reading operation of the subject image described later. The reading sensitivity setting operation can be omitted.
Further, in the reading sensitivity setting operation, the light accumulation period TB set for each row ₁ , TB ₂ ... TB _n Since it sets the reading sensitivity in the image reading operation described later and affects the accuracy of the read image, it is desirable to shorten the delay time interval and increase the number of settings.
[0043]
<Image reading operation>
Next, using the optimum light accumulation time Tb (or Ta) determined by the above-described reading sensitivity setting operation (or environmental illuminance determination operation), an object image reading operation (step S16) is executed.
That is, as shown in FIGS. 8 and 9, reset pulses φT1, φT2,... ΦTn are sequentially applied to each of the top gate lines 101 that connect the top gate terminals TG of the double-gate photosensor 10 in the row direction. The reset period Trst is started, and the double-gate photosensor 10 for each row is initialized.
Here, the reset pulses φT1, φT2,... ΦTn are pulse signals whose high level is the signal voltage Vtgh and low level is the signal voltage Vtgl, and other than the timing at which the high level Vtgh reset pulses φT1, φT2,. Then, a low level signal voltage Vtgl is applied.
[0044]
Next, when the reset pulses φT1, φT2,... ΦTn fall and the reset period Trst ends, the optimum light accumulation period Tb starts sequentially for each row, and the top gate electrode of the double-gate photosensor 10 Charges (holes) are generated and accumulated in the channel region in accordance with the amount of light incident from the side. Here, as shown in FIG. 9, by applying the precharge signal φpg in parallel within the light accumulation period Tb, the precharge period Tprch is started, and the precharge voltage Vprch is applied to the data line 103. A precharge operation for holding a predetermined voltage on the drain electrode of the double gate type photosensor 10 is performed.
[0045]
Then, the readout pulses φB1, φB2,... ΦBn are sequentially applied to the bottom gate line 102 for each row with respect to the double gate type photosensor 10 in which the optimum light accumulation period Ta and the precharge period Tprch have ended. The period Trd is started, and the voltage change VD corresponding to the electric charge accumulated in the double gate type photosensor 10 is read out via the data line 103 by the column switch 113. Here, the read pulses φB1, φB2,... ΦBn are pulse signals whose high level is the signal voltage Vbgh and low level is the signal voltage Vbgl, and at the timing when the high level Vbgh read pulses φB1, φB2,. The low level signal voltage Vbgh is applied.
[0046]
<Effective voltage adjustment operation>
Next, when the above-described image reading operation is completed in all rows (n), the bias of the effective voltage of the signal applied to each gate electrode in a series of environmental illumination determination operation, reading sensitivity setting operation, and image reading operation is performed. An effective voltage adjustment operation (procedure S17) for adjusting and optimizing is performed.
That is, as shown in FIG. 9, in each operation described above, the average value of the signal voltage applied to the top gate line 101 (top gate terminal TG) of the double gate type photosensor 10 by the reset pulse, that is, the effective voltage is obtained. A signal (first signal voltage) having a predetermined effective voltage that can be adjusted to an optimum value set in advance according to the sensitivity characteristic of the double gate photosensor 10 is applied to the top gate line 101 of each row. .
Similarly, the average value of the signal voltage applied to the bottom gate line 102 (bottom gate terminal BG) of the double-gate photosensor 10 by the readout pulse, that is, the effective voltage, is the sensitivity characteristic of the double-gate photosensor 10 in advance. A signal (second signal voltage) having a predetermined effective voltage that can be adjusted to an optimal value set in accordance with is applied to the bottom gate line 102 of each row.
[0047]
Here, the effective voltage of the signal applied to the top gate TG and the bottom gate BG of the double gate type photosensor 10 will be briefly described.
As is clear from FIG. 9, in each reset operation in the ambient illuminance determination operation, the reading sensitivity setting operation, and the image reading operation, the high-level signal voltage Vtgh is applied to the top gate TG only for a very short time (Trst). And a low level signal voltage Vtgl is applied for a relatively long period. Therefore, the effective voltage applied to the top gate TG is greatly biased to the low level side during the ambient illuminance determination operation, the reading sensitivity setting operation, and the image reading operation. Furthermore, since the optimum light accumulation period Tb set for the image reading operation is changed and set each time according to the environmental illuminance or the like by the reading sensitivity setting operation, the effective voltage applied to the top gate TG is Naturally fluctuates.
[0048]
On the other hand, also in the reading operation in the ambient illuminance determination operation, the reading sensitivity setting operation, and the image reading operation, the high level signal voltage Vbgh is applied to the bottom gate BG only for a very short time (Trd). In a relatively long period, the low level signal voltage Vtgl is applied. Therefore, the effective voltage applied to the bottom gate BG is greatly biased to the low level side during the ambient illuminance determination operation, the reading sensitivity setting operation, and the image reading operation. Furthermore, since the optimum light accumulation period Ta set for the image reading operation is changed and set each time according to the environmental illuminance or the like by the reading sensitivity setting operation, the effective voltage applied to the bottom gate TG is Naturally fluctuates.
[0049]
For this reason, if a voltage biased toward the voltage side of a specific polarity continues to be applied to the gate electrode, holes are trapped in the gate electrode, degrading the device characteristics of the double-gate photosensor and increasing the sensitivity. There arises a problem that the characteristics change.
Therefore, in the present embodiment, for example, a double waveform is applied to the voltage waveform applied in the processing cycle of the environmental illuminance determination operation, the reading sensitivity setting operation, and the image reading operation, and the processing cycle of the effective voltage adjustment operation to be executed in the future. Based on the optimum value of the effective voltage on the top gate side and the optimum value of the effective voltage on the bottom gate side set according to the sensitivity characteristics of the gate type photosensor, the time integration value on the high level side of the voltage waveform is used as a reference. In order to make the absolute value equal to the absolute value of the time integration value on the low level side, an adjustment pulse having predetermined signal widths Ttp and Tbp is applied to the top gate line of the double-gate type photosensor during the effective voltage adjustment operation, and By applying to the bottom gate line, the change of the sensitivity characteristic due to the deterioration of the element characteristic is suppressed, and the photo sensor system Reliability can be improved.
[0050]
As described above, according to the image reading apparatus and the drive control method thereof according to the present embodiment, prior to the image reading operation of the subject image, the backlight is set to be turned off and the ambient illuminance is detected and determined. When the ambient illuminance is equal to or higher than a predetermined threshold level (1000 lux), the image reading operation of the subject image can be executed with the backlight set to the off state. Power consumption can be reduced and it can be favorably applied to a portable information terminal or the like. In this case, the subject image can be satisfactorily read even when the backlight is set to the off state.
Furthermore, since the ambient illuminance determination operation and the reading sensitivity setting operation are executed using signals with the same pulse waveform at the same timing, operation control can be easily performed.
[0051]
<Second Embodiment>
Next, a second embodiment of the image reading apparatus according to the present invention will be described with reference to the drawings.
FIG. 12 is a schematic configuration diagram showing the first embodiment of the image reading apparatus according to the present invention. Here, description will be made with reference to the configurations shown in FIGS. 1, 2, and 6 as appropriate. Moreover, about the structure equivalent to embodiment mentioned above (FIG. 7), the same code | symbol is attached | subjected and description is abbreviate | omitted.
In addition to the configuration of the first embodiment described above, the image reading apparatus according to the present embodiment includes an environmental illuminance detection unit that determines environmental illuminance.
That is, in the first embodiment described above, the ambient illuminance determination operation is performed on the subject using the photosensor array that performs the reading sensitivity setting operation and the image reading operation. In addition, a photosensor area (environmental illuminance detection unit) where no subject is placed is provided, and environmental illuminance is detected in the photosensor area.
[0052]
Specifically, as shown in FIG. 12, the image reading apparatus according to the present embodiment is near the detection surface SP above (on the front side of the paper) the photosensor array 100 on which the subject 40 such as a finger is placed, or The environmental illuminance detection unit 300 is provided adjacently. Here, since the ambient illuminance detection unit 300 sets the lighting state of the backlight when the subject image is read, it needs to be provided in the vicinity of the photosensor array 100 on which the subject is placed. For the convenience of illustration, FIG. 12 shows the environment illuminance detection unit 300 as having a relatively wide area. However, as long as at least the environment illuminance can be accurately determined, a single double gate type can be used. It may be a minute region having only a photosensor.
The environmental illuminance detection unit 300 is controlled by the controller 120 and detects the environmental illuminance based on a procedure described later prior to the reading sensitivity setting operation and the pixel reading operation.
[0053]
Next, a drive control method for the image reading apparatus according to the present embodiment will be described with reference to the drawings.
FIG. 13 is a flowchart illustrating a processing procedure of the drive control method for the image reading apparatus according to the present embodiment. FIG. 14 is a timing chart illustrating an example of the drive control method for the image reading apparatus according to the present embodiment. FIG. 15 is a characteristic diagram showing the correspondence between the output voltage of the photosensor and the ambient illuminance. Here, the drive control procedure and method will be described with reference to the configuration of the image reading apparatus shown in FIGS. 2, 7, and 12 as appropriate.
As shown in FIGS. 13 and 14, the drive control method of the image reading apparatus according to the present embodiment is the same as in the first embodiment described above, the environment illuminance determination operation, the reading sensitivity setting operation, and the image reading operation. And each procedure of the effective voltage adjustment operation, each of which is controlled by the controller 120. Since each procedure of the reading sensitivity setting operation, the image reading operation, and the effective voltage adjustment operation is the same as that in the above-described embodiment, the description thereof will be omitted, and the environment illuminance determination operation that is a feature of this embodiment will be described below. This will be explained in detail.
[0054]
<Environmental illumination judgment operation>
As shown in FIGS. 13 and 14, the ambient illuminance determination operation according to the present embodiment detects, for example, that the subject is placed on the detection surface SP above the photosensor array 100 and detects the ambient illuminance detection unit 300. The ambient illuminance is detected by a double gate type photosensor provided in the system. Specifically, the reset pulse φT1, φT2,... ΦTn is applied to the top gate line of the double gate type photosensor constituting the ambient illuminance detection unit 300 at a predetermined time interval, so that the double gate type for each row is applied. Initialize the photo sensor. When the reset period Trst ends, a preset predetermined light accumulation period TL starts sequentially, and charges (holes) are generated in the channel region according to the amount of light incident on the double-gate photosensor for each row. Accumulated.
Then, by applying the precharge signal φpg and the read pulses φB1, φB2,... ΦBn, voltage changes corresponding to the charges accumulated in the light accumulation period TL set for each row are read and sequentially stored in the RAM 130 (step S21). ).
[0055]
Here, as shown in FIG. 15, the output voltage output from the double-gate photosensor constituting the ambient illuminance detection unit 300 is similar to the output voltage of a normal double-gate photosensor when the detection target is dark. When the environmental illuminance is low, the voltage level is high, and when the detection target is bright (when the environmental illuminance is high), the voltage level tends to be low.
Therefore, as shown in FIG. 11, by setting the environmental illuminance that contributes to the reading of the subject image to increase (dominates) as the determination illuminance Lj for determining whether the backlight is used or not, Based on the output voltage from the environmental illuminance detection unit 300, the environmental illuminance can be determined.
[0056]
Specifically, by extracting the determination output voltage Vj corresponding to the determination illuminance Lj from the correspondence relationship between the output voltage and the environmental illuminance shown in FIG. The environmental illuminance can be determined based on the magnitude relationship between the output voltage detected by the determination operation and the determination output voltage Vj.
It should be noted that the light accumulation period TL set for each row in the environmental illuminance determination operation is based on the correspondence relationship between the output voltage and the environmental illuminance shown in FIG. It is set to have a sensitivity region (change range of the light accumulation period TL) TW.
In the environmental illuminance determination operation, it is determined whether or not the output voltage from the environmental illuminance detection unit 300 is equal to or higher than the determination voltage Vj (step S22), and the output voltage is equal to or lower than the determination voltage Vj (that is, the output voltage). If the ambient illuminance corresponding to is greater than or equal to the determination illuminance Lj), it is determined that the image reading operation can be performed only with the ambient illuminance, and the backlight is turned off in the subsequent reading sensitivity setting operation and image reading operation (not Set to use state).
[0057]
On the other hand, when the output voltage is equal to or higher than the determination voltage Vj (that is, when the environmental illuminance corresponding to the output voltage is equal to or lower than the determination illuminance Lj), it is determined that the image reading operation using only the environmental illuminance is impossible. In the reading sensitivity setting operation and the image reading operation, the backlight is set to a lighting state (use state) (step S23). Here, for example, 1000 lux described above can be applied to the determination illuminance Lj.
Subsequently, as in the above-described embodiment, the reading sensitivity setting operation (procedure S24), the subject image reading operation (procedure S25), and the effective voltage adjustment operation (procedure S26) are sequentially executed. In the present embodiment, the reading sensitivity setting operation (step S24) is always executed regardless of the lighting state of the backlight set by the environmental illumination determination operation. This is because the ambient illuminance determination operation is performed by the ambient illuminance detection unit provided independently of the detection surface SP, and thus it is necessary to set an optimal light accumulation time Tb used in the image reading operation of the subject image. Because there is.
[0058]
As described above, according to the image reading apparatus and the drive control method thereof according to the present embodiment, the ambient illuminance detection unit is provided separately from the photosensor array that reads the subject image, and the reading sensitivity setting operation and the image reading operation are performed. Since a light accumulation period having an ambient illuminance near the determined illuminance is set and the ambient illuminance determination operation is executed by a separate control, it is necessary to determine the ambient illuminance performed prior to the image reading operation of the subject image Time can be further reduced.
Further, since the determination of the environmental illuminance can be executed only by comparing the magnitude relationship between the output voltage from the environmental illuminance detection unit and the predetermined determination output voltage, the operation control can be performed very easily.
[0059]
<Other examples>
Next, another specific example of the image reading operation that can be applied to the environmental illumination determination operation and the reading sensitivity setting operation in the drive control method of the image reading apparatus according to the present invention will be described with reference to the drawings.
FIG. 16 shows another embodiment of the image reading operation applicable to the ambient illuminance determination operation (particularly, the first embodiment) and the reading sensitivity setting operation in the drive control method of the image reading device according to the present invention. It is a timing chart which shows. Here, description will be made with reference to the configurations shown in FIGS. 2 and 7 as appropriate.
As shown in FIG. 16, in the image reading operation according to this embodiment, first, a reset pulse is simultaneously applied to each of the top gate lines 101 connecting the top gate terminals TG of the double gate type photosensor 10 in the row direction. .phi.T1, .phi.T2,..., .phi.Tn are applied to simultaneously start the reset period Trst, and the double gate photosensor 10 for each row is initialized.
[0060]
Next, the reset pulses φT1, φT2,... ΦTn fall simultaneously, and the reset period Trst ends, whereby the light accumulation period TC of the double-gate photosensor 10 in all rows. ₁ , TC ₂ ... TC _n Starts simultaneously, and charges (holes) are generated and accumulated in the channel region in accordance with the amount of light incident from the top gate electrode side of the double-gate photosensor 10 for each row.
Here, the light accumulation period TC set for each row ₁ , TC ₂ ... TC _n As shown in FIG. 9, a precharge signal φpg and read pulses φB1, φB2,... ΦBn are applied so as to change stepwise by a predetermined delay time Tdly for each row. Therefore, in the ambient illuminance determination operation or the reading sensitivity setting operation that is performed prior to the image reading operation of the subject image as described in the above-described embodiment, different reading sensitivities (that is, the number of rows) for each row constituting the subject image. Image data read with different reading sensitivities can be acquired by reading a single subject image (one screen).
[0061]
Here, the method of the ambient illuminance determination operation and the read sensitivity setting operation applied to the drive control method of the image reading apparatus according to the present invention is not limited to the above-described embodiments and examples, and different subject images are used. If image data can be acquired with reading sensitivity, for example, a series of processing cycles of reset operation → light storage operation → precharge operation → reading operation are sequentially changed a plurality of times with different reading sensitivities. Needless to say, the image data may be acquired or another method may be used.
In each of the above-described embodiments, the case where a double gate type photosensor is applied as the photosensor constituting the photosensor array has been described. However, the present invention is not limited to this. In short, as long as the photosensors constituting the photosensor array have a configuration in which the backlight is turned on regardless of the environmental illuminance during the reading sensitivity setting operation and the image reading operation, the image according to the present invention. The configuration of the reading device and the drive control method can be applied satisfactorily, and power consumption can be reduced.
[0062]
【The invention's effect】
Claim 1 Or 6 According to the described invention, the light source is turned off. Irradiated from the front side of the photo sensor array Environmental illumination determination means for performing an operation for determining ambient illumination, lighting state setting means for performing an operation for setting the light source to be turned on or off based on the ambient illumination, and a photosensor array Image reading sensitivity In multiple stages While changing, read the subject image, Different Reading sensitivity setting means for performing an operation for obtaining an optimum image reading sensitivity based on an image pattern of the subject image for each image reading sensitivity; For reading subject images And an image reading unit that executes an operation of reading the subject image based on the optimum image reading sensitivity. Therefore, prior to the image reading operation of the subject image, the light source is turned on / off according to the ambient illuminance. Can be set to an optimum reading sensitivity that can execute appropriate image reading, and while reading the subject image well, it can suppress unnecessary lighting of the light source and reduce power consumption. Reduction can be achieved.
[0063]
Claim 2 Or 7 According to the described invention, the ambient illuminance determination operation reads the subject image in a state in which the light source is kept off, the subject is placed on the front side of the photosensor array, and the subject image for each image reading sensitivity is read. The optimum image reading sensitivity is obtained based on the image pattern, and the environmental illuminance is determined based on a preset threshold for the image reading sensitivity, so that the image can be easily read without performing complicated determination processing. The degree of contribution of environmental illuminance to the operation can be determined, and when the degree of contribution of environmental illuminance is large (the environmental illuminance is high), the image reading sensitivity determined in the environmental illuminance determination operation is used as it is. The image reading sensitivity can be set in the image reading operation of the image, and the reading sensitivity setting operation can be omitted to simplify the processing operation.
[0064]
Claim 3 Or 8 According to the described invention, the ambient illuminance determination operation is preset with respect to the output voltage of the photosensor provided in the ambient illuminance detector provided independently of the photosensor array on which the subject is placed. Since the ambient illuminance is determined based on the threshold value, the time required to determine the ambient illuminance executed prior to the image reading operation of the subject image can be further reduced, and the output voltage from the ambient illuminance detection unit can be used. The determination can be made by the comparison process with the threshold value, and the processing operation can be greatly simplified. Claim 4 Or 9 According to the described invention, the first electrode in the photosensor array Apply a reset pulse to initialize the photosensor and apply it to the first electrode. Be applied Of signal voltage Effective voltage Set according to the sensitivity characteristics of the photo sensor A first signal voltage for applying an optimum value is applied to the second electrode of the photosensor array. Apply a readout pulse to read the subject image and apply it to the second electrode Be applied Of signal voltage Effective voltage Set according to the sensitivity characteristics of the photo sensor The first to optimize 2 The effective voltage adjustment means for applying the signal voltage is optimized so that the bias of the effective voltage due to the signal voltage applied to the photosensor can be optimized in the environmental illumination determination operation, the reading sensitivity setting operation, and the image reading operation. In addition, it is possible to provide a highly reliable image reading device by suppressing deterioration of element characteristics of the photosensor and changes in sensitivity characteristics.
[0065]
Claim 5 Or 10 According to the described invention, the photosensor includes a source electrode and a drain electrode formed with a channel region made of a semiconductor layer interposed therebetween, and a top gate formed at least above and below the channel region via an insulating film, respectively. A voltage corresponding to the charge accumulated in the channel region during the charge accumulation period by applying a reset pulse to the top gate electrode at a predetermined timing and applying a read pulse to the bottom gate electrode at a predetermined timing. Because it is composed of a so-called double gate type photo sensor that outputs a light source, the element characteristics due to the deviation of the effective voltage applied to the top gate electrode and the bottom gate electrode during the environmental illumination determination operation, reading sensitivity setting operation and image reading operation Degradation and changes in sensitivity characteristics can be suppressed, and reliability It is possible to provide an image reading device are. In addition, the photo sensor device that constitutes the photo sensor array can be thinned and miniaturized, the reading pixels can be densified to read a subject image with high definition, and the power consumption can be reduced, so It can be applied favorably to information terminals.
[Brief description of the drawings]
FIG. 1 is a schematic cross-sectional view showing the structure of a double gate photosensor applied to an image reading apparatus according to the present invention.
FIG. 2 is a schematic configuration diagram of a photosensor system configured by two-dimensionally arranging double gate type photosensors.
FIG. 3 is a timing chart showing a general drive control method of the photosensor system.
FIG. 4 is an operation conceptual diagram of a double gate type photosensor.
FIG. 5 is a diagram showing a light response characteristic of an output voltage of the photosensor system.
FIG. 6 is a cross-sectional view of a main part of an image reading apparatus for two-dimensional images to which a photosensor system is applied.
FIG. 7 is a schematic configuration diagram showing a first embodiment of an image reading apparatus according to the present invention.
FIG. 8 is a flowchart illustrating a processing procedure of a drive control method of the image reading apparatus according to the first embodiment.
FIG. 9 is a timing chart illustrating an example of a drive control method of the image reading apparatus according to the first embodiment.
FIG. 10 is a conceptual diagram illustrating a situation of external light transmitted through a subject.
FIG. 11 is measurement data showing a correspondence relationship between ambient illuminance and a light accumulation period.
FIG. 12 is a schematic configuration diagram illustrating a first embodiment of an image reading apparatus according to the present invention.
FIG. 13 is a flowchart illustrating a processing procedure of a drive control method for the image reading apparatus according to the second embodiment;
FIG. 14 is a timing chart showing an example of a drive control method for the image reading apparatus according to the second embodiment;
FIG. 15 is a characteristic diagram showing a correspondence relationship between the output voltage of the photosensor and ambient illuminance.
FIG. 16 is a timing chart showing another embodiment of the image reading operation that can be applied to the environmental illumination determination operation and the reading sensitivity setting operation in the drive control method for the image reading apparatus according to the present invention.
[Explanation of symbols]
10 Double gate type photo sensor
11 Semiconductor layer
21 Top gate electrode
22 Bottom gate electrode
30 Backlight
40 subjects
100 Photosensor array
101 Top gate line
102 Bottom gate line
103 data lines
111 Top address decoder
112 row address decoder
113 Output circuit section
118 Backlight
120 controller
130 RAM

Claims (10)

A photosensor array configured by two-dimensionally arranging a plurality of photosensors;
A light source that irradiates the subject placed on the front side of the photosensor array with irradiation light from the back side of the photosensor array;
And have you in a state of being turned off the light source, the environmental illuminance determination unit for determining environmental illuminance emitted from the front surface side of the photosensor array,
Based on the ambient illuminance, lighting state setting means for setting the lighting state of the light source to either one of lighting or extinguishing ,
At least one of the ambient illuminance determination and after the lighting state is set, the image reading sensitivity in the photosensor array is changed in a plurality of stages, and the pixels corresponding to the two-dimensionally arranged photosensors are used. A reading sensitivity setting unit that reads a configured subject image and obtains an optimal image reading sensitivity for reading the subject image based on an image pattern of the subject image for each of the different image reading sensitivities;
Image reading means for reading a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors based on the optimum image reading sensitivity;
An image reading apparatus comprising:   The ambient illuminance determining means is configured by pixels corresponding to the two-dimensionally arranged photosensors in a state where the light source is kept off and the subject is placed on the front side of the photosensor array. A subject image is read, an optimum image reading sensitivity is obtained based on an image pattern of the subject image for each image reading sensitivity, and an ambient illuminance is determined based on a threshold value set in advance for the image reading sensitivity. The image reading apparatus according to claim 1.   The environmental illuminance determination means includes an environmental illuminance detector provided separately and independently from the photosensor array on which the subject is placed, and the environmental illuminance detector includes at least one photosensor, 2. The image reading apparatus according to claim 1, wherein the ambient illuminance is determined based on a threshold value set in advance with respect to the output voltage of the sensor. The image reading device initializes the photosensor by applying a reset pulse to a first electrode in the photosensor array, and determines an effective voltage of a signal voltage applied to the first electrode as a sensitivity characteristic of the photosensor. A first signal voltage for applying an optimum value set in accordance with the first sensor voltage is applied, and a reading pulse is applied to the second electrode of the photosensor array to read the subject image. An effective voltage adjusting means for applying a second signal voltage for setting an effective voltage of the signal voltage applied to the electrode to an optimum value set in accordance with a sensitivity characteristic of the photosensor is provided. Item 4. The image reading apparatus according to any one of Items 1 to 3 . The photosensor includes a source electrode and a drain electrode formed across a channel region made of a semiconductor layer, and a top gate electrode and a bottom gate electrode formed at least above and below the channel region via an insulating film, respectively. Having a double gate structure with
By applying the reset pulse using the top gate electrode as the first electrode and applying the read pulse using the bottom gate electrode as the second electrode, the read pulse is applied from the end of the initialization. 5. The image reading apparatus according to claim 4 , wherein a voltage corresponding to the charge accumulated in the channel region is output during the charge accumulation period up to. A photosensor array configured by two-dimensionally arranging a plurality of photosensors, and a light source for irradiating an object placed on the front side of the photosensor array with irradiation light from the back side of the photosensor array; In the drive control method of the image reading apparatus comprising
And have you in a state of being turned off the light source, the procedure for executing the determining environmental illuminance determination operation environmental illuminance emitted from the front surface side of the photosensor array, based on the environmental illuminance, lights the lighting state of the light source Or a procedure for executing a lighting state setting operation for setting one of the states to off, or
At least one of the ambient illuminance determination and after the lighting state is set, the image reading sensitivity in the photosensor array is changed in a plurality of stages, and the pixels corresponding to the two-dimensionally arranged photosensors are used. A procedure for reading a configured subject image and executing a reading sensitivity setting operation for obtaining an optimum image reading sensitivity for reading the subject image based on an image pattern of the subject image for each of the different image reading sensitivities;
An image reading operation for reading a subject image composed of pixels corresponding to the two-dimensionally arranged photosensors based on the optimum image reading sensitivity. Drive control method. The procedure for executing the ambient illuminance determination operation is to maintain the light source in a light-off state, and the pixels corresponding to the two-dimensionally arranged photosensors with the subject placed on the front side of the photosensor array. An image based on a threshold value set in advance for the image reading sensitivity, and reading an optimum image reading sensitivity based on an image pattern of the subject image for each image reading sensitivity. The drive control method for an image reading apparatus according to claim 6 , wherein the illuminance is determined. The procedure for executing the environmental illuminance determination operation is set in advance with respect to the output voltage of the photosensor provided in the environmental illuminance detector provided independently of the photosensor array on which the subject is placed. 7. The drive control method for an image reading apparatus according to claim 6, wherein the ambient illuminance is determined based on the threshold value. In the drive control method of the image reading apparatus, a reset pulse is applied to a first electrode in the photosensor array to initialize the photosensor, and an effective voltage of a signal voltage applied to the first electrode is set to the photosensor. Applying a first signal voltage to an optimum value set according to the sensitivity characteristic of the sensor, applying a readout pulse to the second electrode in the photosensor array to read the subject image, A procedure for executing an effective voltage adjustment operation for applying a second signal voltage for setting the effective voltage of the signal voltage applied to the second electrode to an optimum value set in accordance with the sensitivity characteristic of the photosensor ; drive control method for an image reading apparatus according to any one of claims 6 to 8, characterized in that it comprises. The photosensor includes a source electrode and a drain electrode formed across a channel region made of a semiconductor layer, and a top gate electrode and a bottom gate electrode formed at least above and below the channel region via an insulating film, respectively. Having a double gate structure with
By applying the reset pulse using the top gate electrode as the first electrode and applying the read pulse using the bottom gate electrode as the second electrode, the read pulse is applied from the end of the initialization. 10. The drive control method for an image reading apparatus according to claim 9 , wherein a voltage corresponding to the charge accumulated in the channel region is output during the charge accumulation period up to.

Images