JP2009181297A - Image reader, information processor, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image reading technology for mounting an image reader on an area smaller than that of a face type sensor without need of joining processing of images. <P>SOLUTION: An image reader includes: a rotary body which rotates with a prescribed rotary axis as a center when receiving a force from a detection object; and a plurality of reading means arranged along the rotary direction of the rotary body, and respectively equipped with a reading face fixed to the surface of the rotary body for reading a detection object image facing the reading face, and for outputting an image signal showing the read image. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a technique for acquiring an image such as a fingerprint.

  A technique for performing user authentication using a fingerprint image acquired by a fingerprint sensor is known. There are two types of fingerprint sensors: the surface type (area type) and the line type (line type). A surface-type fingerprint sensor has a larger reading surface than a finger to be inspected, and can obtain a fingerprint image of the entire finger by one imaging. On the other hand, a line-type fingerprint sensor has a reading surface that is smaller than a finger and has a high flatness (for example, 8: 258), and a fingerprint image of a part of the finger can be obtained by one imaging. is there. In order to obtain a fingerprint image of the entire finger using a line type fingerprint sensor, the user can continuously capture the fingerprint while moving the finger in a certain direction on the fingerprint sensor, and collect and further synthesize them. is necessary. In general, since the speed at which the finger is moved on the fingerprint sensor varies depending on the user, the fingerprint sensor continuously acquires fingerprint images at short time intervals. In order to obtain a fingerprint image of the entire finger from here, it is necessary to superimpose the images while determining the same region among the acquired fingerprint images and further determining the moving direction (for example, non-patent document). 1).

  Line-type and surface-type sensors have different characteristics, and are used properly according to the application. The line type fingerprint sensor is suitable for mobile devices such as mobile phones because the sensor area is small. On the other hand, in order to obtain an image of the entire fingerprint, it is necessary to connect strip-shaped data while aligning them. There's a problem. In addition, the surface-type fingerprint sensor can read the entire fingerprint with a single sensing, but has a problem that the area of the sensor is large.

Yoshiki Tatsuki, “Trends in Biometric Authentication and Frequency Analysis Method Fingerprint / Face Pattern Recognition Algorithm”, Interface, CQ Publishing, March 2005, March 2005, p. 64

  The present invention is a technology that combines the features of a line type sensor and a surface type sensor. More specifically, the present invention can be mounted in an area smaller than that of a surface type sensor and requires alignment processing of a plurality of images. Provide image reading technology that does not.

In order to solve the above-described problems, the present invention includes a rotating body that receives a force from a detection target and rotates around a predetermined rotation axis, and a plurality of reading units arranged along the rotation direction of the rotating body. Reading means each having a reading surface fixed to the surface of the rotating body, reading an image to be detected facing the reading surface, and outputting an image signal indicating the read image; An image reading apparatus is provided.
According to this image reading apparatus, the plurality of image reading means are fixed to the surface of the rotating body.

In a preferred aspect, each of the plurality of reading units may read the detection target image at a timing when a rotation angle of the rotating body from a reference position satisfies a predetermined condition.
According to this image reading apparatus, the detection target image is read at a timing when the rotation angle from the reference position satisfies a predetermined condition.

In another preferred embodiment, the image reading apparatus includes power supply means for supplying power, and each of the plurality of reading means supplies the power at a timing when a rotation angle from a reference position satisfies a predetermined condition. You may receive supply of electric power from a means.
According to this image reading apparatus, power is supplied to the image reading means at a timing when the rotation angle of the rotating body from the reference position satisfies a predetermined condition.

In still another preferred aspect, the image reading apparatus includes a speed measuring unit that measures a rotation speed of the rotating body, and the predetermined condition is a reading unit that satisfies the predetermined condition as the rotation speed increases. Conditions may be set so that the number increases.
According to this image reading apparatus, power is supplied to many image reading means as the rotational speed increases.

In still another preferred aspect, the image reading apparatus includes an image storage unit that stores a plurality of images indicated by image signals output from the plurality of reading units, and a plurality of images stored in the image storage unit. An image generation unit that generates an image of the entire detection target by combining them may be included.
According to this image reading apparatus, an image of the entire detection target can be obtained by combining a plurality of images.

In still another preferred embodiment, the image reading device is measured by a rotation angle measuring unit that measures a rotation angle of the rotating body, and by the rotation angle measuring unit when the first image among the plurality of images is stored. A rotation angle storage unit that stores the rotation angle, and an image correction unit that corrects the image generated by the image generation unit based on the rotation angle stored in the rotation angle storage unit. .
According to this image reading apparatus, the image generated by the image generating means is corrected based on the rotation angle of the rotating body.

In still another preferred aspect, the detection target is a living body, and the reading unit may read an image indicating biological information of the living body.
According to this image reading apparatus, an image indicating biological information is read.

Further, the present invention provides the image reading device, a rotation angle measuring unit that measures the rotation angle of the rotating body, a main control unit that controls the image reading device, and the rotation angle having a predetermined size. There is provided an information processing apparatus having power control means for controlling supply of power so as to start supplying power to the main control unit.
According to this image reading apparatus, when the rotation angle reaches a predetermined size, the supply of power to the main control unit is started.

Furthermore, the present invention is a rotating body that rotates about a predetermined rotation axis, and a plurality of reading means arranged along the rotating direction of the rotating body, each fixed to the surface of the rotating body. A computer device having a reading surface, reading an image to be detected facing the reading surface, outputting an image signal indicating the read image, and a storage device; A step of storing a plurality of images indicated by an output image signal in the storage unit and a step of generating an image of the entire detection target by combining the plurality of images stored in the storage unit Provide a program to let
According to this program, an image of the entire detection target can be obtained by combining a plurality of images.

1. Configuration FIG. 1 is a diagram showing a functional configuration of an information processing apparatus 1 according to an embodiment of the present invention. The information processing apparatus 1 includes an image reading device 10, a power source 20, a measuring unit 50 that measures a rotation angle and a rotation speed of a rotating body 11 (described later), a main control unit 40, a main control unit 40, or an image reading device. Power control means 30 for controlling the supply of power so as to start the supply of power to 10.

  The image reading apparatus 10 further has the following configuration. The rotating body 11 receives a force from the detection target (object to be detected) and rotates around a predetermined rotation axis. The plurality of reading means 12 are arranged along the rotation direction of the rotating body 11. Each reading means 12 has a reading surface fixed with respect to the surface of the rotator 11, reads an image to be detected facing the reading surface, and a signal indicating the read image (hereinafter referred to as “image signal”). Output). The storage unit 13 stores a plurality of images indicated by image signals output from the plurality of reading units 12. The image generating unit 14 generates an image of the entire detection target by combining a plurality of images stored in the storage unit 13.

  FIG. 2 is a diagram illustrating a hardware configuration of the information processing apparatus 1. In this example, the information processing apparatus 1 is an information display apparatus called electronic paper or electronic book. A CPU (Central Processing Unit) 101 is a control device that controls components of the information processing apparatus 1. A ROM (Read Only Memory) 102 is a non-volatile storage device that stores programs and data necessary for starting up the information processing apparatus 1. A RAM (Random Access Memory) 103 is a storage device that functions as a work area when the CPU 101 executes a program. A video random access memory (VRAM) 104 is a storage device that stores data indicating an image to be displayed on the display body 107 (hereinafter referred to as “main image”). The VRAM 104 has a main image storage area, and the main image is stored in the storage area. An I / O (Input / Output) 105 is an interface for managing input / output of data and signals. A UI (User Interface) button group 106 is a device that outputs a signal according to a user's operation, such as a button (rewrite button, page feed button, determination button, etc.), keypad, wheel, lever, touch panel, pen device, etc. This is an input device including the operation element. In this example, the UI button group 106 includes a wheel 106 </ b> W that is a rotating body. The auxiliary storage device 115 is a storage device that stores data that can be displayed on the display unit 107. The UI button group 106 is connected to the I / O 105, and a signal output from the UI button group 106 is input to the CPU 101 via the I / O 105.

  The display body 107 is a display body having a memory display element, for example, a cholesteric liquid crystal display or an EPD (Electrophoretic Display). The display control unit 108 is a device that outputs a signal for performing drawing control of the display body 107. Hereinafter, the display body 107 and the display control unit 108 are collectively referred to as “main display” as necessary. The power on / off circuit 111 is a circuit for supplying and stopping power supply to elements such as the display control unit 108 and the CPU 101. Hereinafter, supplying power to a certain component is referred to as “turning on the power”, and stopping supplying power is referred to as “turning off the power”. The power control unit 112 is a device that performs power management of the information processing apparatus 1. Specifically, the power control unit 112 controls the power on / off circuit 111 to turn on or off the power of the display control unit 108 and the CPU 101. Further, the power control unit 112 monitors the remaining amount of the battery 113. The battery 113 supplies power to the components of the information processing apparatus 1, such as the display control unit 108, the CPU 101, and the RAM 103. The bus 114 is a transmission path used for signal transmission between components.

  The fingerprint sensor 117 is a device that electrostatically reads a user's fingerprint and outputs a signal (image signal) indicating an image of the read fingerprint. The fingerprint sensor 117 is connected to the I / O 105, and a signal output from the fingerprint sensor 117 is input to the CPU 101 via the I / O 105. In this example, the information processing apparatus 1 has a plurality of fingerprint sensors 117 (only one is shown in FIG. 2).

  The rotation sensor 118 is a device that measures a rotation angle of the wheel 106W (a rotation angle from a predetermined reference position) and outputs a signal indicating the measured rotation angle. The rotation sensor 118 is connected to the I / O 105, and a signal output from the rotation sensor 118 is input to the CPU 101 via the I / O 105. Since the rotation speed can be obtained by recording the rotation angle measured by the rotation sensor 118 at a constant time interval, the rotation sensor 118 can also be used as a speed measurement means.

  The ROM 102 stores a control program for performing processing described below. When the CPU 101 executes this control program, the functions shown in FIG.

  FIG. 3 is a diagram illustrating an appearance of the information processing apparatus 1. In this example, a plurality of fingerprint sensors 117 are used as the image reading device 10. That is, the detection target is the user's finger F. The information processing apparatus 1 has a display surface of the display body 107 on the front surface of the housing, and has a wheel 106W (a part of the UI button group 106) and a fingerprint sensor 117 on the side surface. Each fingerprint sensor 117 is a so-called line type sensor and has a rectangular reading surface. The plurality of fingerprint sensors 117 are arranged along the rotation direction of the wheel 106W.

  FIG. 4 is a diagram showing the positional relationship between the wheel 106W and the fingerprint sensor 117. As shown in FIG. The wheel 106 </ b> W is a rotating body that receives a force from the finger F moving in the arrow A direction and rotates about the axis P in the arrow B direction, and is an example of the rotating body 11. The wheel 106W has a cylindrical shape. That is, the shape of the cross section perpendicular to the axis P of the wheel 106W is a circle centered on the axis P. The rotating shaft P has a double structure of a core portion that rotates together with the wheel 106W and an outer peripheral portion that does not rotate, and an electrode pattern E (described later) is provided on the outer peripheral portion.

  The reading surface of each fingerprint sensor 117 is fixed to the surface of the wheel 106W and faces outward. The area of the reading surface is smaller than the area of the finger F to be inspected (more specifically, the portion of the abdomen of the finger before the first joint). The plurality of fingerprint sensors 117 are arranged at equal intervals for each angle θ along the rotation direction of the wheel 106W on the surface of the wheel 106W. The angle θ is an angle in which the length of the outer periphery of the wheel 106 </ b> W cut at the angle θ corresponds to the length x of the short side of the reading surface of the fingerprint sensor 117. Hereinafter, when it is necessary to distinguish each of the plurality of fingerprint sensors 117, they are distinguished by using subscripts such as a fingerprint sensor 117-1, a fingerprint sensor 117-2,. The shape of the reading surface of the fingerprint sensor 117 is a rectangle, and the short sides are arranged in parallel to the rotation direction of the wheel 106W. When the user places the finger F on the wheel 106W, a part (a fingerprint sensor 117-1 in the example of FIG. 4) of the plurality of fingerprint sensors 117 faces the finger F. When the user moves the finger F in the direction of arrow A, the wheel 106W rotates in the direction of arrow B, and the fingerprint sensor 117-2 faces the finger F instead of the fingerprint sensor 117-1.

  FIG. 5 is a diagram illustrating wiring of the fingerprint sensor 117. The fingerprint sensor 117 has a signal line 117W including a signal line used for supplying power and a signal line for transmitting an image signal. The axis P has an electrode pattern E on its surface. The axis P itself does not rotate, and the electrode pattern E is provided on a part of the surface of the axis P. Only some signal lines 117W of the plurality of fingerprint sensors 117 (in the example of FIG. 5, fingerprint sensors 117-1, 2 and 3) are in contact with the electrode pattern E. Thereby, electric power is supplied to the three fingerprint sensors of the fingerprint sensors 117-1, 11-2 and 3. The electrode pattern E can output only the image signal from the fingerprint sensor (fingerprint sensor 117-1 in the example of FIG. 5) at the position facing the finger F out of the three fingerprint sensors to the outside of the wheel 106W. Designed to have position and shape. When the wheel 106W rotates, the fingerprint sensor to which power is supplied and the fingerprint sensor that can output an image signal are sequentially switched.

2. Operation FIG. 6 is a flowchart showing the operation of the information processing apparatus 1. The flow in FIG. 6 is started when, for example, power supply to the CPU 101 is stopped and the information processing apparatus 1 shifts to a sleep state. Here, in particular, starting the power supply to the CPU 101 is referred to as “turning on the main power supply”, and stopping the power supply to the CPU 101 is referred to as “turning off the main power supply” or “transitioning to the sleep state”. .

  In step S100, power supply control unit 112 determines whether rotation of wheel 106W has been detected. Specifically, it is as follows. The power supply control unit 112 monitors the signal output from the rotation sensor 118, and determines that the rotation is detected when the rotation angle indicated by this signal exceeds the threshold value (S100: YES), If the rotation angle does not exceed the threshold value, it is determined that rotation is not detected (S100: NO).

  In step S110, the power supply control unit 112 turns on the main power supply. When power is supplied, the CPU 101 performs initialization processing necessary for the following processing, such as securing a storage area for storing a fingerprint image on the RAM 103. By the initialization process, the RAM 103 has a storage area for storing a predetermined number of fingerprint images. Here, the “fingerprint image” means an image indicated by an image signal output from each fingerprint sensor 117, that is, an image showing a part of the finger F. The “predetermined number” is the number of fingerprint sensors 117.

  In step S120, the CPU 101 performs fingerprint authentication. Details are as follows.

  FIG. 7 is a flowchart showing details of the fingerprint authentication process. In step S121, the CPU 101 determines whether the rotation angle of the wheel 106W has become a predetermined magnitude. In this example, the “predetermined size” is the angle θ in FIG. When it is determined that the rotation angle has reached a predetermined size (S121: YES), the CPU 101 proceeds to step S122. When it is determined that the rotation angle is less than the predetermined size (S121: NO), the CPU 101 waits until the rotation angle reaches the predetermined size.

  In step S122, the CPU 101 stores the fingerprint image indicated by the image signal in the RAM 103. That is, the CPU 101 stores a fingerprint image every time the rotation angle of the wheel 106W becomes θ. At this time, the fingerprint image is output by the sensor facing the finger F among the plurality of fingerprint sensors 117 as described above.

  FIG. 8 is a diagram illustrating an acquired fingerprint image. In this example, ten fingerprint images are shown. A single fingerprint image includes a portion of the entire finger F that faces the reading surface of each fingerprint sensor 117.

  A description will be given with reference to FIG. 7 again. In step S123, the CPU 101 determines whether a predetermined number of fingerprint images have been acquired. When it is determined that a predetermined number of fingerprint images have not yet been acquired (S123: NO), the CPU 101 repeatedly executes the processes of steps S121 to S123. If it is determined that a predetermined number of fingerprint images have been acquired (S123: YES), the CPU 101 proceeds to step S124.

  In step S124, the CPU 101 combines a predetermined number of fingerprint images to generate an image of the entire finger. Here, a plurality of fingerprint images are combined by a simple combination that does not align adjacent fingerprint images. There is no need for relative alignment of a plurality of fingerprint images, which is necessary in the prior art. This is because the relative position between the finger F and the reading surface of each fingerprint sensor 117 is constant as long as the finger F moves while touching the wheel 106W (more precisely, the fingerprint sensor 117).

  FIG. 9 is a diagram illustrating an image of the entire generated finger. The plurality of fingerprint images shown in FIG. 9 are acquired at the timing when the finger F moves by the distance x, and during this time, the relative position between the finger F and the reading surface of the fingerprint sensor 117 is constant. Even if a plurality of fingerprint images are superimposed, an image of the entire finger can be obtained.

  This will be described with reference to FIG. In step S125, the CPU 101 performs an authentication process using the generated image. Since the authentication process is performed using a known technique, the description thereof is omitted here.

3. Other Embodiments The present invention is not limited to the above-described embodiments, and various modifications can be made. Hereinafter, some modifications will be described. In the following, description of matters common to the embodiment is omitted. In addition, common reference numerals are used for components common to the embodiment. Two or more of the following modifications may be used in combination.

3-1. Modification 1
In the above-described embodiment, the rotating body 11 is also assigned a function as a main power switch. However, the function as a switch of the main power supply may be assigned to an operator other than the rotating body 11. In this case, the rotator 11 may have a function of controlling the power on / off of the image reading apparatus 10.

  For example, in this case, the flow in FIG. 6 is started when the information processing apparatus 1 is activated and the power supply to the CPU 101 is started. When power is supplied, the CPU 101 performs initialization processing necessary for the following processing, such as securing a storage area for storing a fingerprint image on the RAM 103. By the initialization process, the RAM 103 has a storage area for storing a predetermined number of fingerprint images. In step S110, a process for starting the supply of power to the fingerprint sensor 117 is performed instead of the process of turning on the main power supply. According to this example, since power is supplied to the fingerprint sensor 117 only when fingerprint authentication is performed, the power consumption can be further reduced as compared with the case without this configuration.

3-2. Modification 2
FIG. 10 is a diagram illustrating an image of the entire generated finger according to the second modification. As described in the embodiment, while the fingerprint image is acquired, the relative position between the reading surface of the fingerprint sensor 117 and the finger F is fixed, so that it is not necessary to align the plurality of fingerprint images. However, since the rotation angle of the wheel 106W at the start of fingerprint reading is not always constant, the origin of the finger image (which depends on the absolute rotation angle of the wheel 106W) does not necessarily match the origin of the combined image. FIG. 10 shows an image generated by simple superposition when fingerprint reading is started from a state in which the wheel 106W is rotated by an angle corresponding to the circumference L. In this example, the origin (O _F ) of the finger image does not match the origin (O _S ) of the combined image. And acquired image, by the algorithm of matching images for matching stored in advance, since the origin O _F and the origin O _S is sometimes it do not match the matching is difficult, in which case the following it may be the image processing so as to match the origin O _F and the origin O _S in the.

The CPU 101 acquires the rotation angle of the wheel 106 </ b> W when reading of the fingerprint is started by the rotation sensor 118 and stores it in the RAM 103. After the image is generated as shown in FIG. 10, CPU 101 has a length sentence origin O _F corresponding to the rotation angle stored in the RAM103 shifts the image to move. As described above, the rotation angle storage unit that stores the rotation angle measured by the measurement unit 50 when the first image among the plurality of fingerprint images is stored, and the image generated by the image generation unit 14 are rotated. by having the image correcting means for correcting, based on the corner, the information processing apparatus 1 obtains the origin O _F and image and the origin O _S matches, as shown in FIG.

Alternatively, CPU 101 by performing the edge detection processing for the first to the obtained fingerprint image from the start of the reading of the fingerprint, may acquire the position of the origin O _F. Further alternatively, by using a spring or the like, in a state where no force is applied to the wheel 106W configured to be positioned at the home position, the origin O _F and the origin O _S may be mechanically matched.

3-3. Modification 3
In the above-described embodiment, an example in which power supply and image signal output are mechanically controlled, specifically, a specific arrangement with respect to the axis P by appropriately designing the position and shape of the electrode pattern E. The example in which the power source is turned on only for the fingerprint sensor 117 and the image signal can be output has been described. However, regardless of the arrangement with respect to the axis P, the power supply and the image signal output may be configured for all of the plurality of fingerprint sensors 117, and the power supply and the image signal output may be controlled by software. In this case, for example, each fingerprint sensor 117 outputs an image signal including its own identifier. The CPU 101 selects and stores one to be stored from a plurality of images indicated by a plurality of image signals.

3-4. Other Modifications In the above-described embodiment, the example in which the CPU 101 that is the main control unit of the information processing apparatus 1 executes the process illustrated in FIG. 6 has been described. However, a processor other than the CPU 101 executes the process in FIG. Also good. For example, the fingerprint sensor 117 itself may have a processor and a memory that execute part or all of the processing of FIG.

  In the above-described embodiment, an example in which the image reading apparatus is the fingerprint sensor 117, that is, an example in which the acquired information is a fingerprint has been described. However, the acquired information is not limited to a fingerprint. Any other biological information may be used as long as it can be acquired as an image, such as a fingerprint, an iris, or a vein. Alternatively, information other than biological information may be acquired. For example, the inspection target may be a non-biological body such as a card or a seal.

  In the above-described embodiment, the example in which the fingerprint sensor 117 is a capacitance type sensor has been described. However, other types of sensors such as an optical type, a thermal type, and a mechanical type may be used. In addition, the “line type” sensor here is not limited to one in which image pickup elements are arranged one-dimensionally. Even if the image sensor is two-dimensionally arranged, any sensor can be used as long as the short side of the circumscribed rectangle of the reading surface is shorter than the length of the inspection target. Good.

  In the above-described embodiment, an example in which the shape of the reading surface of the fingerprint sensor 117 is a rectangle has been described, but the shape of the reading surface is not limited to a rectangle. The shape may be other than a rectangle such as an ellipse or an octagon. In short, it is sufficient that the circumscribed rectangle is a rectangle.

  In the above-described embodiment, the example in which the measurement unit 50 measures the rotation angle and the rotation speed of the rotating body 11 has been described. However, the measurement unit 50 may measure only one of the rotation angle and the rotation speed. .

  The hardware configuration of the information processing apparatus 1 is not limited to that shown in FIG. An apparatus having any hardware configuration may be used as long as the necessary functional configuration can be realized. In the above-described embodiment, an example in which the information processing apparatus 1 is electronic paper has been described. However, the information processing apparatus 1 may be an apparatus other than electronic paper.

  As used herein, the terms “parallel” and “vertical” do not mean mathematically completely parallel and vertical, and may include a certain amount of error as long as the effects of the present invention are achieved. .

  In the above-described embodiment, the program executed by the CPU 101 includes a magnetic recording medium (magnetic tape, magnetic disk (HDD (Hard Disk Drive), FD (Flexible Disk)), etc.), optical recording medium (optical disk (CD (Compact Disk)). , DVD (Digital Versatile Disk), etc.), magneto-optical recording medium, semiconductor memory (flash ROM, etc.) and the like. The program may be downloaded via a network such as the Internet.

It is a figure which shows the function structure of the information processing apparatus 1 which concerns on one Embodiment. 2 is a diagram illustrating a hardware configuration of the information processing apparatus 1. FIG. 1 is a diagram illustrating an external appearance of an information processing apparatus 1. FIG. It is a figure which shows the positional relationship of the wheel 106W and the fingerprint sensor 117. FIG. It is a figure which illustrates the wiring of the fingerprint sensor. 3 is a flowchart showing the operation of the information processing apparatus 1. It is a flowchart which shows the detail of a fingerprint authentication process. It is a figure which illustrates the fingerprint image acquired. It is a figure which illustrates the image of the whole finger | toe produced | generated. It is a figure which illustrates the image of the whole produced | generated finger based on the modification 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Information processing apparatus, 10 ... Image reading apparatus, 11 ... Rotating body, 12 ... Reading means, 13 ... Storage means, 14 ... Image generation means, 20 ... Power supply, 30 ... Power control means, 40 ... Main control part, 50 ... Measurement means 101 ... CPU 102 ... ROM 103 ... RAM 104 ... VRAM 105 ... I / O 106 ... UI button group 107 ... Display body 108 ... Display control unit 111 ... Power on / off circuit , 112 ... power supply control unit, 113 ... battery, 114 ... bus, 115 ... auxiliary storage device, 117 ... fingerprint sensor, 118 ... rotation sensor

Claims (9)

A rotating body that rotates around a predetermined rotation axis;
A plurality of reading means arranged along the rotation direction of the rotating body, each having a reading surface fixed to the surface of the rotating body, and an image of a detection target facing the reading surface An image reading apparatus comprising: reading means for reading and outputting an image signal indicating the read image. 2. The image reading apparatus according to claim 1, wherein each of the plurality of reading units reads the image to be detected at a timing when a rotation angle of the rotating body from a reference position satisfies a predetermined condition. Power supply means for supplying power;
2. The image according to claim 1, wherein each of the plurality of reading units receives power supply from the power supply unit at a timing when a rotation angle of the rotating body from a reference position satisfies a predetermined condition. Reading device. Having a speed measuring means for measuring the rotational speed of the rotating body;
The image reading apparatus according to claim 3, wherein the predetermined condition is a condition that is set such that the number of reading units that satisfy the predetermined condition increases as the rotational speed increases. Image storage means for storing a plurality of images indicated by image signals output from the plurality of reading means;
The image reading apparatus according to claim 1, further comprising: an image generation unit configured to generate an image of the entire detection target by combining a plurality of images stored in the image storage unit. Rotation angle measuring means for measuring the rotation angle of the rotating body;
Rotation angle storage means for storing the rotation angle measured by the rotation angle measurement means when the first image of the plurality of images is stored;
The image reading apparatus according to claim 5, further comprising: an image correction unit that corrects the image generated by the image generation unit based on the rotation angle stored in the rotation angle storage unit. The detection target is a living body;
The image reading apparatus according to claim 1, wherein the reading unit reads an image indicating biological information of the living body. An image reading apparatus according to claim 1;
Rotation angle measuring means for measuring the rotation angle of the rotating body;
A main control unit for controlling the image reading device;
An information processing apparatus comprising: a power control unit configured to control power supply so that power supply to the main control unit is started when the rotation angle reaches a predetermined magnitude. A rotating body that rotates around a predetermined rotation axis, and a plurality of reading means arranged along the rotation direction of the rotating body, each having a reading surface fixed to the surface of the rotating body; In a computer apparatus having a reading unit that reads an image of a detection target facing the reading surface and outputs an image signal indicating the read image, and a storage unit,
Storing a plurality of images indicated by image signals output from the plurality of reading means in the storage means;
Generating a whole image to be detected by combining a plurality of images stored in the storage means.

Images