CA1301912C - Image input device - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE

An image input device of a portable type, which includes a light source for reading an original document, a photo electric converting element for converting reflected light from the original document into an electrical signal, a memory function section having a solid state memory element for storing output of the photo-electric converting element, an output port for external connection, and operating keys for operating the image input device.

Description

~3~g~2 BACKGROUND OF THE INVENTION
~ he present invention generally relates ~o an image reading arrangement, and more particularly, to an image input device for reading images (including characters) of an original document or the like.
Conventionally, the image input device has been generally of a large scale ih construction reguiring a beam scanning mechanism, an ori~inal document feeding mechanism, etc. as represented by an image scanner, facsimile equipment or the like, thus being difficult to be formed into a portable t~pe. Meanwhile, with the development of the information oriented society, a simple and convenient information collecting means is requested, and as one example which has realized such means, the portable type copying machine now commercially available may be raised.
Although the image input device ~or the portable type copying machine is compact in size and capable of manually scanning over an oriyinal document, since the read image information is arranged to be immediately used for copying, it is impossible to adopt a practice for effecting input and copying of th~ image information at different time periods, and furthermore, the input image in~ormation is mostly used only for copying, and can not be applied to such usage as projection onto a CRT display.
SUMMARY OF THE INVENTION
__ Accordingly, an essential object of the present invention is to provide an improved ima~e input device of a portable type, which is compact in size and light in weight for convenience in handling, and arranged to retain input information therein so as to be outputted at any time depending on necessity.
Another object of the present invention is to provide an image input device of ~he above described type, which is simple in construction and stable in ~unctioning, and can be readily manu~actured at low cost.
In accomplishing these and other objects, accord-ing to one preferred e~bodiment o~ the present invention, there is provided an .image input device of a portable type, which includes a light source for reading an original document, a photo-electric converting element for converting re~lected light from the original document into an electri-cal signal, a memory function section having a solid state memory element for storing output of said photo-electric converting element, an output port for external connection, and operating keys for operating said image input device.
By the arrangement of the present invention as described above, when the operating key, for example, for input is depressed, the light source is illuminated to establish the state ~or reading an original document. The image information read during scanning o~ the original document by manually moving the image input device is outputted ~rom the photo-electric converting element so as to be successively stored in the solid state memory element ~or being retained in this manner.

Subsequently, for outputting the information thus stored, a device such as a printer, CRT display, facsimile equipment or the like is connected to the output port, and upon depression of the operating key for output, the image information is transmitted to such a device so as to be utilized for each application.
In ano~her aspect of the present invention, there is provide an image input device of a portable t~pe, which includes a light source, a photo-electric conver~ing ele-ment, an image forming lens, a diffraction grating means forleading light emitted by said light source and reflected by an information medium, towards said photo-electric convert-ing element, a memory function section having a solid state memory el~ment for storing output of said photo-electric converting element, an output port for external connection, and operating keys for operating said image input device.
In the above construction, however, it is prefera-ble to add a lens effect to said diffraction grating means.
Furthermore, it is also desirable to accommodate the light source and the photo-electric converting element within the same cap or housing for hermetic sealing, and particularly, to commonly use the diffra~tion grating means with the hermetic sealing.
By the above arrangement of the present inven~ion, upon depression of the operating key, for example~ for input, the light source is lit to establish the state for reading an information medium, i.e., original document. In this cas~, light emitted by the light source is imparted to the information medium through the diffraction grating and the image forming lens, and the reflected light therefrom is led to the photo-electric converting element located in a position different from that of said light source through said image forming lens and said diffraction grating. The image information read by scanning the information medium through manual movement of the image input device is output-ted from the photo-electric converting element so as to be successively ~tored in said solid state memory element, and thus, the image information is retained in the device.
For outputting the stored information, upon depression of the operating key for output, with a device such as a printer, CRT display, facsimile equipment or the li~e being connected to the output port, the image informa-tion is transmitted to such external equipment.
In a further aspect of the present invention, there is also provided an image input device of a portable type, which includes a lig~t source, a photo-electric converting element, an ima~e forming optical ~ystem for collec~ing ligh~ emitted by said light source, onto an information medium and also, for directing reflected light ~herefrom onto said photo~electric converting element for image formation thereon~ a memory function section ha~ing a ~L31)~L2 solid state memory element for storing output of said photo-electric converting element, an output poxt for external connection, and operatiny ~eys for operating said image input device, said image forming optical system ~eing provided with a portion capable of interchanging lenses through attaching and detaching thereof.
By the above arrangement of the present invention, upon depression of the operating key, for example for input, the light source is lit to establish the state for reading an information medium, i.e., original document. In this case, light emitted by the light source is im~arted to the information medium in a form as converged by the image forming optical system, and the reflected light therefrom is led to the photo-electric converting element through said 1~ image forming optical system for image formation. The image information read by scanning the information medium through manual movement of the image input device is outputted ~rom the photo-electric converting element so as to be successively stored in said solid state memory element, and thus, the image information is retained in the device.
Sin~e the optical system is arranged to be capable of interchanging the lenses through attaching or detaching, it is possible to alter the size of light converging on the information medium, and image formin~ magnification for the 2~ photo-electric converting element, and consequently, en-largement or contraction of the input image is made possi~
ble.

~3~9~L2 For outputting the stored information, upon depression of the operating key for output, with a device such as a printer, CRT display, facsimile equipment or the like being connected to the output port, the image information is transmitted to such external equipment in the similar manner as in the image input devices described so far.
In accordance with an embodiment of the invention, an image input device of a portable type is comprised of a light source for emitting light onto an information medium;
image forming optical apparatus for collecting the light emitted by the light source when reflected from the information medium and directing the light reflected from the information medium; photo-electric converting apparatus for developing an image signal representative of an image on the information medium as reflected by th~ light and directed by the image forming optical apparatus; a memory ~unction section having a solid state memory element for storing the image signal from the photo-electric converting apparatus; an output port for :removably connecting external devices ~ith the memory function section; and operating keys for operating the image input device; the image forming optical apparatus having a portion for receiving interchangeable lenses by removably attaching and detaching the lenses to the portion.

~.~

~3~i9~2 - 6a -In accordance with another embodiment, an im~ge input device of a portable type, is comprised of a light S source for emitting light onto an original document; photo-electric converting apparatus for developing an electrical signal representative of an image on the original document as reflected by the light from the original document;
exchangeable memory apparatus for storing the electrical signal from the photo-electric converting apparatus; an output port for removahly connecting an external device with the exchangeable memory apparatus; and operating keys for operating the image input device.
In accordance with another embodiment, an image input device of a portable type is comprised of a light source for emitting light towards an information medium;
image forming optical apparatus for converging the light onto the information medium and directing the light reflected from the information medium; photo-electric converting apparatus for developing an image signal representative of an image on the information medium as reflected by the light from the image forming optical apparatus; exchangeable memory apparatus for storing the image signal from the photo-electric converting apparatus;
an output port for removably connecting extPrnal devices with the exchangeable memory apparatus; and operating keys for operating the image input device.

A

~ 3~ L2 - 6b -BRIEF DESCRIPTION OF THE DRAWINGS
These and other objects and features of the present invention will become clear from the following description taken in conjunction with the preferred embodiments thereof with reference to the accompanying drawings, in which:
Fig. l is a schematic longitudinal sectional view of an image input device according to the preferred embodiment of the present invention;
Fig. 2 is a schematic side sectional view showing, on an enlarged scale, a memory function section employed in the image input device of Fig. l;
Fig. 3 is an electrical block diagram showing general construction of the image input device of Fig. l;
Fig. 4 is a schematic longitudinal sectional view showing one construction of a casing to be employed in the image input device of Fig. l;
Fig. 5 is a view similar to Fig. l, which particularly shows a second embodiment thereof;

r~

Fig. 6 is also a view similar to Fig. 5, which particularly shows a modification thereof;
Fi~ 7 is a cross section showing part of the arrangement of FigO 6 on an enlarged scale;
Fig. 8 is a view similar to Fig. 1, which particu-larly shows a third embodiment thereof; and Fig. 9 is a view similar to Fig. 8, which particu-larly shows a modification thexeof.
DETAILED DESCRIPTION OF THE INVENTION
Before the description of the present invention proceeds, it is to be noted that like parts are designated by like reference numerals throughout the accompanying drawings.
Referring now to the drawings r there is shown in Fig. 1, an ima~e input device M1 accordiny to one preferred embodiment of the present invention, which generally in-cludes a casing 1 of a cylindrical pen-like shape made, ~or : examp.le, of a syntheti~ resin and having an opening 2 at its convergent tip, a light source 3 and a photo-electric converting element 4 provided within the casing 1 in posi-tions adjacent to the opening 2, a memory function section 5 provided at the upper portion of the casing 1~ an input operating key 12 and an output operating key 13 disposed at an intermediate portion of the casing 1, an output port 14 2~ for ~onnection with external appliances, and a resilient stopper means or clip H connected at its one end to ~he .

~3al~9~

upper outer surface of the casing 1 for retaining the image input device M1 when it is carried in a pocket of a suit, etc.
The photo-electric converting element 4 is com-posed of a CCD (charge coupled device) having a plurality ofindependent light receiving regions or photodiode arrays, etc., although not particularly shown. As shown in Fig~ 2, the memory function section 5 further includes a solid memory element 6 composed of a RAM (random access memory), a memory refresh circuit 7, a CPU (central processing unit) 8, and a power source 9 which are accommodated in a container 10 having connecting pins 11 extending outwardly therefrom.
Fig. 3 shows a block diagram for an electrical circuit construction in the arrangement of Figs. 1 and 2 described above, in which the photo-electric converting element 4, the memory element 6, and the opexating keys 12 and 13 are coupled with the CPU 8, which is connected to the output port 14 as shown.
Now, in the state whexe the ima~e input device M1 is placed on the original document or information medium O
as shown in Fig. 1, when the device M1 is slid in one direction, with the input operating key 12 depressed, li~ht emitted by the light source 3 through the opening 2 and reflected by the original document O is incident upon the photo-electric converting element 4, which conver~s the information into an electrical signal to be applied to the ~3~ 2 CPU 8 throu~h a signal line (not shown). The CPU 8 converts the output signal of the photo-electric converting element 4 into a digital value, and also, causes the converted data to be stored in the solid state memory element 6. Therefore, the inputted image information is memorized and retained.
For output of the memorized image information, upon depression of the outpu~ operating key 13, with an external appliance (not shown) being connected to the output port 14, the image information successively read out from the solid ~tate memory element 6 is transmitted to the external appliance through the output port 14~ As the external ap~liance, a printerr CRT display, facsimile equipment or the like may be connected to the image input device M1.
In the above embodiment, since the memory refresh circuit 7, the CPU 8, the solid state memory element 6 and the power source 9 are integrally formed as the memory function section 5, memory retaining function may be contin-uously maintained, even when the memory ~unction section 5 is taken out of the image input device M1. Accordingly, by exchanging the memory function section 5 as a aartridge, the device Ml may cope with various applications without being restricted ~y the memory capacity. For making the memory function section 5 to be exchangeable as described above, it 25 may be, for example, so axranged that the casing 1 is divided into upper and lower portions respectively provided ~3~

with fitting means la and lb a~ corresponding edges ~hereof as shown in Fig. 4 for engagement or disengagement therebetween. It is to be noted here that the above embodi-ment may, for example, be so modified that, apart from the 5 power source 9 within the memory ~unction section 5, anothex power source (not shown) is provided also in the casing 1.
As is seen from the foregoing description, accord-ing to the first embodiment of the present invention, it is very convenient, since the image input is memorized when necessary by carrying about only the image input device, and the memorized information may be outputted as required, while the device can be formed compact in size and light in weight. Furthermore, since the external appliance is not limited to one kind for a specific use, the output of the lS device may be directed to various applications.
Referring also to Fig. 5, there is shown an image input device M2 according to a second embodiment o~ the present invention.
The image input device M2 also includes a casing 21 of a cylindrical shape made, for example, of a synth~tic resin and having an opening 22 at the convergent forward end thereof, which is slid over an informa~ion medium or origi-nal document O ~uring input of an image information, a resilient stopper means or clip H fixed at its one end to the upper outer face of the casing 21, an output port 26 having connecting pins ~7 for external connection, and ~3~ 2 provided in a first recess ~8 formPd at the upper portion of the casing 21 to receive a connector (not shown) for connec-tion with an external appliance to achieve a stable electri-cal coupling therewith, and input and output operating keys 29 and 30 provided in a second recess 31 formed on the casing 21 at a position below the fir~t recess 28.
Within the casing 21, there are disposed a power source 32, a memory function section 33, a photo-electric converting element 34, a light source 35, a diffraction grating 36 and an image forming lens 37, etc. in that order from the upper portion of said casing 21. The memory function section 33 includes a solid state memory element 39 such as a RUu~ (random access memory) or the like, and a CPU
38, etc. The photo-electric converting element 34 is composed of a CCD having a plurality of independent light receiving regions or photo-diode arrays as in the first embodiment. The light source 3~ may be constructed by a semiconductor laser and the like.
Since the electrical circuit construction of the image input device M2 of Fig. S is generally the same as in the first embodiment (Fig. 3~, detailed description thereof is abbreviated here for brevity.
~ n Fig. 5, zero order light (non-di~fracted light) by the diffraction grating 36, in the light emitted from the light source 35, is converged into a predetermined size onto the information medium o through the imagP forming lens 37 ~3~

so as to irradiate the reading region on the information medium 0. The light reflected therefrom is converged by the image forming lens 37, and thereafter, is diffracted by the diffraction grating 36, thereby to form an image on the photo-electric converting element 34.
Now, in the state where the image input device M2 is placed on the information medium O as shown in Fig. 5, when the device M2 is slid in one direction, with the input operating key 29 depressed, the image information in the form of light led to the photo-electric con~erting element 34 as described above is converted into an electrical signal by the converting element 34 so as to be applied to the CPU
38 through a signal line ~not shown). The CPV 38 converts the output signal of the photo-electric converting element 34 into a digital value, and also, causes the converted data to be stoxed in the solid state memory element 39, and thus, the inputted image informati~n is memorized and retaine~.
For output of the memorized image information, upon depression of the output operating key 30, with an externa]. appliance (not shown) being connected to the output port 26, the image information successively read out from the solid state memory element 39 is transmitted to the external appliance through the output port 26. As the external appliance, a printer, CRT display, ~acsimile equipment or the like may be connected to the image input device M2 as in the first embodiment described earlier.

In the arrangement of Fig. 5, the light source 35 and the point on the information medium o are not in a conjugate relation. on the other hand, owing to the neces-sity for forming the image information of the information medium O, on the photo-electric converting element 34, it is required that the point on the information medium O and the light receiving surface of the photo-electric converting element 34 should naturally be in the conjugate relation, and the light source 35 and the photo-electric converting element 34 must be disposed in different positions with respect to the direction of optical axis, which arrangement, however, undesirably complicates the construction o~ the casing 21, thus being disadvantageQus to the compact si~e o~
the casing 1.
Accordingly, in a modified image input device M2B
as shown in Fig. 6, by imparting a lens effect (power) to the diffraction grating 36, the light source 35 and the photo-electric converting element 34 are arranged to be disposed at the same position wi~h respect to the direction of optical axis. By such arrangement as described above~
not only simplification of the casing structure and compact size of the image input device are achieved, but also, the light source 35 and the photo-electric converting element 34 can be mounted within one housing as shown in Fig. 7.
As described earlier, semiconductor devices are normally employed for the light source 35 and ~he photo-electric converting element 34, and since such semiconductor devices tend to be deteriorated in the characteristics thereof due to influence of the atmosphere such as moisture, oxygen, etc., hermetic sealing is required therefor.
However, in the construction in which the light source 35 and the photo-electric converting element 34 are consider-ably deviated in positions with respect to the direction o~
optical axis as shown in Fig. 5, the light source 35 and the photo-electric converting element 34 must be sealed sepa-rately, but in the arrangement of Fig. 6, since the lightsource 35 and the photo-electric converting element 34 are located at the same position with respect to the optical axis direction, they may be accommodated in one hermetically sealed housing as shown in Fig. 7.
In the arrangement of Fig. 7, the housin~ includes a stem 40 having terminal pins 41 extending downwardly therefrom, a cap 42 mounted on said stem 40 and having an opening 43 formed at its upper portion, and the dif~raction grating 36 is attached to the cap 42 so as to close the ~0 opening 43. The light souxce 35 and the photo-electric converting element 34 are disposed side by side on a flat surface 40a of the stem 40, while an optical detector 44 ~or monitori~g, which outputs a correction signal ~or making the light amount constant by dire~tly receiving light o~ the light source 35, is provided on a stepped portion ~Ob lower in height than the flat surface 40a of the stem 40 by one step.

13C~

~ 15 -In Fig. 7, although there is shown the example in which the diffraction grating is employed as a window for the hermetic sealing for simplification of the device, this may be replaced by an ordinary glass plate, with the diffraction grating 36 being provided at the inner side or outer side of the sealing.
It is to be noted that the arrangement in Fig. 5 may be so modified that the photo-electric converting element 34 is disposed on the optical axis, and the light source 35 is provided outside the optical aæis, with respec-tive positions thereof in the direction of optical axis for the image forming lens 37 being maintained.
Meanwhile, in the arrangement of Fig. 6, the positions of the light source 35 and the photo-electric element 34 may be exchanged to each other, and by imparting light dif~using effect to the diffraction grating 36, similar effect may be obtained.
As is also referred to earlier, by arranging the memory function section 33 replaceable in the form of a cartridge, it is possible to cause the image input device to correspond to various applications without restriction by the memory capacity. For allowing the memory ~unction section to be replaceable as referred to above, the casing 21 may, for example, be divided into upper and lower por-tions, with fitting means being provided therevn for selec-tive engagement or disengagement kherebetween.

~ ccording to the second embodiment of the present invention as described so far, the image input is conveniently memorized when necessary by carrying about only the image inpu~ device, and the memorized information may be outputted as required, while the device can be formed compact in size and light in weight. Moreover, since the external appliance is not limited to one kind for a specific use, the output of the device may be directed to various applications as in the first embodiment.
Referring further to Fig. 8, there is shown an image input device M3 according to a third embodiment of ~he present invention.
The image input device M3 similarly includes a casing 51 of a cylindrical shape made, for ex~mple, of a synthetic resin and having an opening 52 at the convergent forward end thereof which is slid over an information medium or original document O during input of an image information, with the casing 51 being composed o~ a main body portion 51a and a forward end portion 51b which is detachably mounted onto the main body portion 51a for exchanging through a - fitting construction 54, and with a detachable spare forward end portion 51c fox replacement being held on the other end (i.e., the upper end in Fig. 83 of the casing 51, a resil-ient stopper mean~ or clip H fixed at its one end to the upper outer face of the casing 21, an output port 56 having connecting pins 57 for external connection, and provided in a ~irst recess 58 formed at the upper portion of the casing 51 to receive a connector (not shown) for connection with an external appliance to achieve a stable electric coupling therewith, and input and output operating keys 59 and 60 provided in a second recess 61,formed on the casing 51 at a position below the first recess 58~
Within the casing 51, there are disposed a power source 62, a memory function section 63, a photo-electric converting element 64, a light source 65, a diffraction ~rating 66 and a first condenser lens 67 and a second condenser lens 68, etc., in that order from the upper portion o~ said casing 51. The memory function section 63 includes a solid state memory element 71 such as a RAM
(random access memory) or the like, and a CPU 70, etcO The photo-electric converting element 64 is composed of a CCD
having a plurality of independent light receiving regions or photo-diode arrays as in the previous embodiments. The light source 6$ may be constructed by a semiconductor laser and the like.
The diffraction grating 66, and the first and second condenser lenses 67 and 68 constitute the image forming optical system 69 for converging light emitted from the light source 65 onto the information medium O and also, for leading the reflected light to the photo-electric converting element 64 to form the image, and in the optical system~ the second condenser lens 68 is mounted at ~he ~30~2 forward end portion 51b of the casing 51 as referred to earlier. Accordlngly, by replacing this forward end portion 51b with the spare forward end portion 51c, the second condenser lens 68 may be replaced by another second condens-er lens 68' having a dif~erent focal length.
Since the electric circuit construction of the image input device M3 of Fig. 8 is the same as in the first embodiment (Fig~ 3), detailed description thereof is abbre-viated here for brevity.
In Fig. 8, zero order light (non-diffracted light) by the diffraction grating 66, in the light emitted from the light source 65, is converged into a predetermined size onto the inEormation medium O through the first and second condenser lenses 67 and 68 so as to irradiate the re~ding region on the information medium 0. The light re~lected therefrom is converged by the first and second condenser lenses 68 and 67, and thereafter, if diffracted by the diffraction grating 66, thereby ~o form an image on the photo-electric converting element 64.
2n Now, in the state where the image input device M3 is placed on the information medium O as shown in Fig. 8, when the device M3 is slid in one direction, with the input operating key 5g depressed, the image information in the form o~ light led to the photo-electric convexting element ~4 as described above is converted into an electrical signal by the converting element 64 so as to be applied ~3~

to the CPU 70 through a signal line (not shown). The CPU 70 converts the output signal of the photo-electric converting element 64 into a digi~al value, and also, causes the converted data to be stored in the solid state memory element 71, and thus, the inputted image information is memorized and retained.
For output of the memorized image infcrmation, upon depression of the outpu~ operating key 60, with an external appliance (not shown) being connected to the output port 56, the image information successively read out ~rom the solid state memory element 71 is transmitted to the external appliance through the output port 56. As the external app~iance, a prin~er, CRT display, facsimile equipment or the like may be connected to the image input device M3 as in the previous embodiments described earlier.
Referring also to Fig. 9, in a modi~ication M3B o~
the image input device M3 for the third embodiment o~ Fig~
8, the forward end of the main body 51a for the casing 51 is formed into a reduced diameter portion T for constituting a completed casi~g for the image input device M3B even ~y the main body 51a alone so as to be used as it is, with the second condenser lens 68 being also provided in the main body 51a ~or the purpose. However~ in order to meet the requirement ~or variable magnifications, interchangeable or exchangeable first and second units 74 and 75 having condense lenses 72 and 73 respectively are arranged to be ~3~L93~:
- 2~ -detachably mounted onto the reduced diameter portion T in a piled-up state as shown. The condenser lenses 72 and 73 of the first and second units 74 and 75 and the second condens-er lens 68 acc~mmodated in the main body 51a respectively have different focal lengths, and various magnifications may be achieved according to combinations thereof. Needless to say, the first and second units 7~ and 75 may be used in the state where only either one of them is mounted on the main body ~la.
In the third embodiment as shown in Fig. 8, although enlargement or contraction of the input image may be selected according to exchange or combination of the condenser lenses, variation in the brightness according thereto is anticipated. It is to he noted, however, that such variation in the brightness with respect to the input image can be readily corrected in terms of a circuit ar~
rangement, by imparting an automatic gain control function or a ~unction to control slice level during conversion of a ana~og value of the light amount into a digital value, to a circuit for treating the input signal.
As is clear ~rom the foregoing description, in the third embodiment as described so far also, since only the image input device can be carried about for memorizing the image input when necessary, and also for outputting the image lnformation as required, it is extremely convenient to use, while the input device can be made compact in size and ~3~L912 -- ')1 --light in weight. Moreover, the output of the device can be applied to various applications, since the external appli-ance is not limited to a specific one.
Although the present in~ention has been fully descxibed in connection with the preferred embodiments thereof with re~erence to the accompanying drawings, it is to be noted that various changes and modi~ications are apparent to those skilled in the art. Such changes and modi~ications are to be understood as included within the scope of the present invention as defîned by the appended claims unless they depart therefrom.

Claims (14)

1. An image input device of a portable type, comprising:
a light source for emitting light onto an information medium;
image forming optical means for collecting said light emitted by said light source when reflected from said information medium and directing said light reflected from said information medium;
photo-electric converting means for developing an image signal representative of an image on said information medium as reflected by said light and directed by said image forming optical means;
a memory function section having a solid state memory element for storing said image signal from said photo-electric converting means;
an output port for removably connecting external devices with said memory function section; and operating keys for operating said image input device;
said image forming optical means having a portion for receiving interchangeable lenses by removably attaching and detaching said lenses to said portion for receiving interchangeable lenses by removably attaching and detaching said lenses to said portion.

2. An image input device as claimed in claim 1, wherein said light source comprises a semiconductor laser.

3. An image input device as claimed in claim 1, wherein said photo-electric converting means comprises a CCD.

4. An image input device as claimed in claim 1, wherein said image forming optical means comprises at least one image forming lens for converging said light reflected from said information medium and a diffraction grating for directing said light.

5. An image input device as claimed in claim 1, wherein said memory function section comprises connecting means for removably attaching and detaching said exchangeable memory means with said photo-electric converging means.

6. An image input device of a portable type, comprising:
a light source for emitting light onto an original document;
photo-electric converting means for developing an electrical signal representative of an image on said original document as reflected by said light from said original document;
exchangeable memory means for storing said electrical signal from said photo-electric converting means;

an output port for removably connecting an external device with said exchangeable memory means; and operating keys for operating said image input device.

7. An image input device as claimed in claim 6, wherein said exchangeable memory means comprises a RAM, memory refresh means, a CPU, and a power source.

8. An image input device as claimed in claim 7, wherein said electrical signal is converted to a digital signal by said CPU and said digital signal is stored in said RAM.

9. An image input device as claimed in claim 6, wherein said exchangeable memory means comprises connecting means for attaching and detaching said exchangeable memory means with said photo-electric converting means.

10. An image input device of a portable type, comprising:
a light source for emitting light towards an information medium;
image forming optical means for converging said light onto said information medium and directing said light reflected from said information medium;
photo electric converting means for developing an image signal representative of an image on said information medium as reflected by said light from said image forming optical means;
exchangeable memory means for storing said image signal from said photo-electric converting means;
an output port for removably connecting external devices with said exchangeable memory means; and operating keys for operating said image input device.

11. An image input device as claimed in claim 10, wherein said image forming optical means comprises diffraction grating means and a lens.

12. An image input device as claimed in claim 10, wherein said light source comprises a semiconductor laser.

13. An image input device as claimed in claim 11, wherein said light source, said photo-electric converting means and said diffraction grating means are hermetically sealed in a unit.

14. An image input device as claimed in claim 13, wherein said unit further comprises connecting means for removably attaching and detaching said unit with said exchangeable means.