U.S. patent application number 15/426420 was filed with the patent office on 2017-08-24 for handwriting input/output system, handwriting input sheet, information input system, and information input assistance sheet.
The applicant listed for this patent is Kenji Yoshida. Invention is credited to Kenji Yoshida.
Application Number | 20170242494 15/426420 |
Document ID | / |
Family ID | 41549793 |
Filed Date | 2017-08-24 |
United States Patent
Application |
20170242494 |
Kind Code |
A1 |
Yoshida; Kenji |
August 24, 2017 |
HANDWRITING INPUT/OUTPUT SYSTEM, HANDWRITING INPUT SHEET,
INFORMATION INPUT SYSTEM, AND INFORMATION INPUT ASSISTANCE
SHEET
Abstract
A handwriting input/output system that allows letters,
characters and figures to be input by hand. The handwriting
input/output system includes an imaging device that captures and
transmits the image of a medium provided with a writing area having
a dot pattern that defines coordinate information and code
information, a dot pattern analysis device that calculates
trajectory information by storing the image data of the dot pattern
and analyzing the code of the image data, a trajectory recognition
device recognizes the trajectory information of the letter,
character, and figure traced on the writing area based on a change
in the analyzed coordinate information, and a process instruction
device transmits a process instruction based on the recognized
information together with the trajectory information to an
information processing device, whereby a letter, character, or
figure can be input by hand.
Inventors: |
Yoshida; Kenji; (Tokyo,
JP) |
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Applicant: |
Name |
City |
State |
Country |
Type |
Yoshida; Kenji |
Tokyo |
|
JP |
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|
Family ID: |
41549793 |
Appl. No.: |
15/426420 |
Filed: |
February 7, 2017 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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13131073 |
Jun 8, 2012 |
9594439 |
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PCT/JP2009/006332 |
Nov 25, 2009 |
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15426420 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
G08C 17/00 20130101;
G06F 3/03545 20130101; G06F 3/0321 20130101; G06F 3/038
20130101 |
International
Class: |
G06F 3/03 20060101
G06F003/03 |
Foreign Application Data
Date |
Code |
Application Number |
Nov 25, 2008 |
JP |
2008-300118 |
Claims
1. A handwriting input sheet comprising a medium having a writing
area on which is formed a dot pattern that repeatedly defines
coordinate information and code information at least part of or a
plurality of areas of the medium.
2. The handwriting input sheet according to claim 1, wherein the
medium is formed by further being superimposed with a text, a
graphic, and a photograph relating to the writing area.
3. The handwriting input sheet according to claim 1, wherein the
medium is formed by being further superimposed by an icon
signifying code information over the dot pattern that repeatedly
forms the code information that defines: identification information
that identifies a predetermined medium surface and/or the writing
area surface; and/or an operation instruction (e.g., starting up a
program, inputting a command, inputting and outputting/searching
data, specifying searching information).
4. The handwriting input sheet according to claim 3, wherein the
icon is formed with the dot pattern on a sticker and sticky note
that can be attached somewhere, and other medium surfaces.
5. The handwriting input sheet according to claim 1, further
comprising Braille within and/or around the writing area.
6. The handwriting input sheet according to claim 1, further
comprising a thin convex guide along an external circumference of
the writing area so that the imaging unit does not go over a
boundary when writing in the writing area.
7. An information input system, comprising: an information input
assistance sheet, that is, a grid sheet, laminated with: an
infrared reflection layer that reflects infrared rays yet transmits
visible light coming from one side; a dot pattern layer that is
provided on the one side of the infrared reflection layer and made
of material having a characteristic of diffusely reflecting
infrared rays, and arranged with dots of a dot pattern that
repeatedly defines coordinate information and/or code information
in at least part of or a plurality of areas; and a protection layer
that is provided on a side of the dot pattern layer opposite to the
infrared reflection layer and has a characteristic of transmitting
infrared rays and visible light, a medium at least part of which
surface is formed with dots of the dot pattern with material having
a characteristic of absorbing infrared rays; an imaging unit that
images the dot pattern and transmits image data; a dot pattern
analysis unit that determines by a predetermined determination
method a dot portion imaged with lower brightness than surrounding
area in image data of the dot pattern of the medium surface imaged
and transmitted by the imaging unit or a dot portion imaged with
higher brightness than surrounding area in image data of the dot
pattern of the grid sheet imaged and transmitted by the imaging
unit, stores the image data of the dot pattern into the storage
element, and analyzes a code of the image data to input the
coordinate information and/or code information.
8. The information input system according to claim 7, wherein the
predetermined determination method comprises: a method of
sequentially calculating a difference (.DELTA.BL=BL(i,j+k)-BL(i,j))
in brightness (BL(i,j)) of a captured image that is stored in a
storage element and has m rows and n columns of pixels between
pixels that are apart at a predetermined interval (k) beginning
from a left end shifting in a rightward direction for each row (i)
to determine whether the difference exceeds or falls below a
predetermined positive/negative threshold; for determining a dot
portion imaged with lower brightness than surrounding area, a
method of determining a pixel on right side as a dot when a
difference in the brightness falls below a negative threshold and
that the dot starts from the pixel, and a pixel on right side not
as a dot when a difference in the brightness exceeds a positive
threshold and that the dot ends before the pixel; and for
determining a dot portion imaged with higher brightness than
surrounding area, a method of determining a pixel on right side as
a dot when a difference in the brightness exceeds a positive
threshold and that the dot starts from the pixel, and a pixel on
right side not as a dot when a difference in the brightness falls
below a negative threshold and that the dot ends before the pixel,
wherein the dot pattern analysis unit determines by the
predetermined determination method whether the dot pattern is the
one provided on the medium surface or on the grid sheet and
analyzes a code by the predetermined determination method.
9. The information input system according to claim 8, wherein the
predetermined determination method measures brightness of a
predetermined area of the captured image, then, if the brightness
exceeds a predetermined threshold, the determination method for a
dot portion imaged with lower brightness than surrounding area is
used, and if the brightness falls below a predetermined threshold,
the determination method for a dot portion imaged with higher
brightness than surrounding area is used.
10. An information input assistance sheet laminated with: an
infrared reflection layer that reflects infrared rays yet transmits
visible light coming from one side; a dot pattern layer that is
provided on the one side of the infrared reflection layer and made
of material having a characteristic of diffusely reflecting
infrared rays, and arranged with dots of a dot pattern that defines
coordinate information and/or code information in at least part of
or a plurality of areas; and a protection layer that is provided on
a side of the dot pattern layer opposite to the infrared reflection
layer and has a characteristic of transmitting infrared rays and
visible light.
11. An information input assistance sheet laminated with: an
infrared reflection layer that reflects infrared rays coming from
both sides and transmits visible light; dot pattern layers that are
provided on both sides of the infrared reflection layer, made of
material having a characteristic of absorbing infrared rays, and
arranged with dots of the dot pattern; and protection layers that
are provided on further outer sides of the dot pattern layers and
have a characteristic of transmitting infrared rays and visible
light coming from both directions, wherein coordinate information
and/or code information that is made into a pattern in the dot
pattern arranged on each of the dot pattern layers is identical or
different from each other.
12. The handwriting input sheet according to claim 1, wherein the
writing area is of an arbitrary shape.
13. The handwriting input sheet according to claim 1, wherein the
medium comprises a writing area formed with a dot pattern in which:
a plurality of reference points are provided so as to form a size
and direction of a block within an area of the block for arranging
an information dot; a plurality of virtual reference points that
are defined with reference to the reference points are arranged;
the information dot that defines coordinate information or
coordinate information and code information by a distance and
direction from the virtual reference point is arranged; and,
coordinate information or coordinate information and code
information is repeatedly defined at least part of or a plurality
of areas in a predetermined combination of arrangement directions
of the information dot among a plurality of combinations of
arrangement directions of the information dot with reference to the
plurality of virtual reference points, and the dot pattern analysis
unit determines the writing area based on the predetermined
combination of arrangement directions of the information dot and
processes handwriting input.
14. The handwriting input sheet according to claim 13, wherein the
predetermined combination of arrangement directions of the
information dot is a predetermined combination of arrangement
directions of the information dot among combinations of arrangement
directions where the information dot is arranged in any one of
upward, downward, leftward, rightward directions and diagonal
directions from each of the plurality of virtual reference points.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application is a Divisional of U.S. application Ser.
No. 13/131,073, filed on Jun. 8, 2012 and wherein U.S. application
Ser. No. 13/131,073 is a national stage application filed under 35
U.S.C. .sctn.371 of International Application No.
PCT/JP2009/006332, filed on Nov. 25, 2009, which is based upon and
claims the benefit of priority of the prior Japanese Patent
Application No. 2008-300118, filed on Nov. 25, 2008, the entire
contents of which are incorporated herein by reference.
FIELD OF THE INVENTION
[0002] The present invention relates to a handwriting input/output
system and hand writing input sheet for inputting handwritten
information including letters, characters, and figures into a
computer system.
[0003] The invention relates to an information input system and
information input assistance sheet for assisting input into a
computer system.
BACKGROUND OF THE INVENTION
[0004] Computers have come to be used widely in every situation of
our lives. In addition to traditional usages such as preparing
documents and performing calculations, the functions and usages of
the computer are dramatically increasing including drawing pictures
and drawing architecture and machines.
[0005] To draw pictures, architecture, and machines, it is
conventionally required to use a keyboard, mouse, tablet, CAD
system, and the like to perform operations, such as inputting of
letters and characters and drawing designs.
[0006] However, there are a lot of cumbersome operations to input
letters and characters via a keyboard and to draw designs using a
tablet and CAD system, requiring time to get used to. Particularly
there is a problem in which, for those who have trouble in
operating devices, such as elderly people, such operations are
difficult. Further, "digital divide" is now becoming a problem in
which a gap is generated in terms of information and opportunities
between those who can use a keyboard, mouse, and the like to handle
computers and those who cannot use a keyboard, mouse, or the like
and cannot handle computers.
[0007] To solve such problems, a system for inputting handwritten
information into a computer had been proposed. Such a system
comprises a base and a drawing device. Moving the drawing device in
relation to the base generates graphical information (handwritten
information). The base is equipped with fine dot patterns of
position-coding pattern that registers position information on the
base. If drawing is performed on the base using the drawing device,
the drawing device reads out the position-coding pattern. The
computer system stores the position information on the base from
the drawing device as a graphical input. In this way, the drawn
content can be input into the computer system, output to the
display, or stored to the memory (for example, Japanese Unexamined
Patent Application Publication No. 2003-528387).
SUMMARY OF THE INVENTION
Problems that the Invention is to Solve
[0008] However, the position-coding pattern used in the system of
Japanese Unexamined Patent Application Publication No. 2003-528387
registers only position information. As the result, the computer
system can only input the graphical information drawn by the
drawing device, and a different area from the area for drawing has
to be separately provided to input/record a variety of information
related with the graphical information including the page number of
a booklet, which arises a problem in which the handwriting
input/output system becomes complicated requiring a user to operate
over a plurality of areas. Further, a reference table must be
provided for inputting and recording a variety of information
related with the graphical information to all the position
information corresponding to the graphical information drawn by the
drawing device. Particularly, if the drawing area is not a
rectangle and is an area surrounded by a polygon or curved lines, a
reference table for all the position information within the area is
required.
[0009] The present invention was devised in consideration of such
problems, and has a technical subject to easily provide, with low
cost, a handwriting input/output system that allows inputting of
letters, characters, figures, and the like by hand. Further, the
present invention also has a technical subject to provide a
handwriting input/output system that allows collectively inputting
information, such as letters, characters, and figures, as well as
relating information thereto.
Means to Solve the Problems
[0010] <Handwriting Input/Output System>
[0011] The handwriting input/output system comprises: a medium that
comprises a writing area, on at least part of or a plurality of
areas of the medium, formed with a dot pattern that repeatedly
defines coordinate information and code information; an imaging
unit that images the dot pattern of the writing area and transmits
image data thereof; a dot pattern analysis unit that stores the
image data of the dot pattern imaged and transmitted from the
imaging unit into a storage element and analyzes a code of the
image data to obtain trajectory information including the
coordinate information and the code information; a trajectory
recognition unit that recognizes the trajectory information of a
letter, a character, and/or a figure that is traced on a surface of
the writing area based on a change in the analyzed coordinate
information; and a process instruction unit that transmits a
process instruction and the trajectory information according to a
recognized recognition information to an information processing
unit.
[0012] According to the above feature, in the handwriting
input/output system of the invention, as the dot pattern formed on
the medium defines code information as well as coordinate
information, the process instruction unit can collectively transmit
trajectory information and a process instruction based on the
trajectory information to the information processing unit.
[0013] The medium is preferably further formed with a text,
graphic, and photograph related with the writing area on at least
part of or a plurality of areas of the medium.
[0014] According to the above feature, with the handwriting
input/output system of the invention, a user can easily know the
position of the writing area and what to write in the writing
area.
[0015] The medium is preferably formed by being additionally
superimposed with the dot pattern at least over the trajectory
information drawn on the surface of the writing area or the edited
information of the trajectory information and/or print information
on the surface of the medium.
[0016] According to the above feature, in the handwriting
input/output system of the invention, a medium that is once
handwritten input can be superimposed and printed with a new dot
pattern, then, the medium can be further written in/edited.
[0017] On a predetermined medium surface and/or the writing area
surface of the medium, the dot pattern that repeatedly forms code
information that defines identification information identifying the
writing area and/or an operation instruction (e.g., starting up a
program, inputting a command, inputting and outputting/searching
data, specifying searching information) is preferably formed by
being superimposed with an icon signifying the code
information.
[0018] According to the above feature, in the handwriting
input/output system of the invention, a user can easily know what
the code information means (what kind of process instruction is
transmitted) by seeing the icon.
[0019] The icon is preferably formed by superimposing on the dot
pattern on the surface of a medium including a sticker and sticky
note that can be attached somewhere.
[0020] According to the above feature, in the handwriting
input/output system of the invention, the icons can be freely laid
out on the medium surface, enhancing flexibility of the layout.
[0021] By defining the medium provided with the writing area as the
first medium, the medium preferably further comprises the second
medium on which is formed a dot pattern that repeatedly defines
code information for identifying the surface of the first medium
and/or the surface of the writing area, wherein, by scanning the
code information formed on the second medium with the imaging unit,
print information on the first medium surface and/or the trajectory
information drawn on the writing area surface and/or information
related with the trajectory information is output.
[0022] According to the above feature, in the handwriting
input/output system of the invention, by printing the code
information identifying a medium surface on other media (e.g., an
organizer), information handwritten input on the medium surface can
be searched and output by touching on the medium surface with the
imaging unit. Further, the space for the writing area of the medium
can be widely retained.
[0023] The second medium is preferably in a form of a sticker,
sticky note, and the like that can be attached somewhere, or a
card.
[0024] According to the above feature, with the handwriting
input/output system of the invention, flexibility of the layout of
the writing area is further enhanced, allowing searching and
outputting of information handwritten input on the writing area at
will in accordance with convenience and preference of a user.
[0025] The medium is preferably a grid sheet that is a transparent
medium used by being placed on a monitor surface that displays the
writing area of the handwriting input/output system and the grid
sheet is formed with a dot pattern that repeatedly defines
coordinate information and/or code information.
[0026] According to the above feature, the handwriting input/output
system of the invention can provide a manageable touch panel.
[0027] The medium is preferably a grid sheet that is a transparent
medium used by being placed on a medium printed with the writing
area of the handwriting input/output system and the grid sheet is
formed with a dot pattern that repeatedly defines coordinate
information and/or code information.
[0028] According to the above feature, in the handwriting
input/output system of the invention, a grid sheet can be placed
over a medium surface to input by handwriting even if the grid
sheet is not placed on the monitor surface.
[0029] The imaging unit preferably further comprises: an
irradiation unit that irradiates a predetermined wavelength light
to the medium surface through an imaging opening; and an imaging
element that images reflection of the predetermined wavelength
light and transmits as image data to the dot pattern analysis unit,
and the dot pattern analysis unit further comprises: a light
control unit that controls the irradiation unit by causing the
irradiation unit to emit a predetermined strength light during a
first predetermined time, then to emit the predetermined strength
light again after a second predetermined time has elapsed that is
longer than analysis time required by the dot pattern analysis unit
for analyzing a code of the image data, so that the image data can
remain in the imaging element as an afterimage longer than time
during which the dot pattern analysis unit stores the image data
imaged and transmitted by the imaging element, and the first
predetermined time and the second predetermined time are
consecutive.
[0030] According to the above feature, at writing in the
handwriting input/output system of the invention, the dot pattern
can be clearly burned on the imaging element when the imaging unit
moves on the medium surface. Therefore, handwriting input can be
realized by analyzing the afterimage even if the frame rate
(imaging speed) of the imaging unit is low.
[0031] It is preferable that the light control unit instructs the
irradiation unit to immediately emit light after analyzing of a
code of the image data by the dot pattern analysis unit before the
second predetermined time, the irradiation unit emits the
predetermined strength light during the first predetermined time,
and the dot pattern analysis unit stores image data that is newly
imaged and transmitted by the imaging unit into a storage element
to analyze a code.
[0032] According to the above feature, in the handwriting
input/output system of the invention, if the code analysis ends
before the second predetermined time due to ideal dot pattern
imaging/analysis, an error, or the like, by immediately moving to
the next code analysis, imaging interval is shortened and smooth
trajectory information can be obtained.
[0033] It is preferable that the light control unit instructs the
irradiation unit to immediately emit light while the dot pattern
analysis unit is analyzing the dot pattern before the second
predetermined time, the irradiation unit emits the predetermined
strength light during the first predetermined time, and the dot
pattern analysis unit stores image data that is newly imaged and
transmitted by the imaging unit into a storage element during the
analysis time, then, analyzes a code of the image data immediately
after the analysis time.
[0034] According to the above feature, in the handwriting
input/output system of the invention, as the dot pattern analysis
unit stores next image data while still analyzing a code, and moves
on to analyzing the next image data immediately after analyzing the
code, imaging interval is shortened and smooth trajectory
information can be obtained.
[0035] It is preferable that the imaging unit further comprises a
projection for instruction and images the dot pattern on a
trajectory near the projection for instruction when tracing a
letter, a character and/or a figure traced by the projection for
instruction onto the writing area surface, and the dot pattern
analysis unit stores image data of the dot pattern transmitted from
the imaging unit into a storage element and analyzes a code of the
dot pattern to obtain trajectory information including the
coordinate information and the code information.
[0036] According to the above feature, with the handwriting
input/output system of the invention, the position traced by the
imaging unit on the writing area can be easily viewed.
[0037] It is preferable that the imaging unit further comprises at
least a pen tip, and images and transmits the dot pattern on a
trajectory near the pen tip when tracing a letter, a character,
and/or a figure drawn by the pen tip onto the writing area surface,
and the dot pattern analysis unit stores image data of the dot
pattern imaged and transmitted from the imaging unit into a storage
element and analyzes a code of the dot pattern to obtain trajectory
information including the coordinate information and the code
information.
[0038] According to the above feature, with the handwriting
input/output system of the invention, a trajectory near the imaging
unit can be left on the writing area surface.
[0039] The projection for instruction preferably further comprises:
at least a pen tip; a retraction space for retracting the pen tip
inside the projection for instruction; and a button for controlling
retraction/extension of the pen tip.
[0040] According to the above feature, the handwriting input/output
system of the invention can be used differently depending on when a
trajectory near the imaging unit drawn on the writing area surface
is desired to be left and desired not to be left.
[0041] It is preferable that the imaging unit further comprises an
erasing unit, in the projection for instruction, that erases a
letter, a character, and/or a figure drawn on the writing area
surface, and, while erasing an area traced by the erasing unit,
simultaneously images a dot pattern on a trajectory near the
erasing unit on the writing area surface, and the process
instruction unit transmits a process instruction for erasing the
trajectory information of the letter, the character, and/or the
figure and the trajectory information to an information processing
unit.
[0042] According to the above feature, the handwriting input/output
system of the invention can not only relate inputs of the written
information between the writing area surface and the information
processing unit but also relate erasures of the written information
therebetween.
[0043] It is preferable that the trajectory recognition unit
calibrates the coordinate information obtained by code analysis by
the dot pattern analysis unit, so that the coordinate information
becomes identical or approximate to the trajectory of a letter, a
character, and/or a figure either traced or drawn on the writing
area surface.
[0044] According to the above feature, even when the trajectory
information recognized by the trajectory recognition unit differs
from the trajectory on the medium, the handwriting input/output
system of the invention can make the trajectory information the
same as the actual trajectory or approximate the trajectory
information to the actual trajectory as far as there is no problem
for real use by calibrating the trajectory information.
[0045] It is preferable that the trajectory recognition unit
further comprises a timer for keeping times when the imaging unit
touches on and separates from the writing area surface, recording a
sequence of a trajectory touched and drawn by the imaging unit on
the writing area surface and time during which the imaging unit is
in contact with the writing area surface, and transmitting them to
the information processing unit.
[0046] According to the above feature, with the handwriting
input/output system of the invention, a variety of researches
including the writer's character, age, and sex, can be carried out
by recognizing the time required by the information processing unit
for inputting and comparing that with normal time.
[0047] The timer preferably records times when the imaging unit
becomes in contact with the writing area surface and when the dot
pattern analysis unit calculates the trajectory information, and
transmits the times to the information processing unit.
[0048] According to the above feature, in the handwriting
input/output system of the invention, by recognizing the moving
rate of the pen, brushstroke of a letter or difficulty of writing
the letter can be analyzed, further, mental state and physical
state of the writer can be anticipated.
[0049] It is preferable that the process instruction unit is
capable of uniquely inputting identification information that
identifies the writing area and/or an operation instruction (e.g.,
starting up a program, inputting a command, inputting and
outputting/searching data, specifying searching information) based
on the code information and/or the recognition information.
[0050] According to the above feature, in the handwriting
input/output system of the invention, process instruction unit can
make unique instruction to information processing unit based on the
code information and/or recognition information. This is the most
important function of the invention, which makes possible
identification of which writing area is written in and what kind of
operation instruction is performed to which writing area.
[0051] It is preferable that the trajectory recognition unit
further refers to a letter, character, and/or figure information
pattern table categorized in advance and relating to a content to
be written in the writing area based on the code information to
recognize the trajectory information with high accuracy.
[0052] According to the above feature, in the handwriting
input/output system of the invention, as a letter, character,
and/or figure information pattern table categorized in advance is
referred to based on the code information, trajectory information
can be recognized with high accuracy.
[0053] It is preferable that, after recognizing the trajectory
information, based on an analyzed change in the coordinate
information, the trajectory recognition unit further refers to a
predefined semantic information code table (a dictionary)
corresponding to the code information, in search of semantic
information of the letter, the character, and/or the figure or a
word comprising one or a plurality of the letters and the
characters, and converts the code information into a semantic
information code, and the process instruction unit transmits the
semantic information code and the process instruction based on the
semantic information to the information processing unit.
[0054] According to the above feature, by referring to the semantic
information code table when recognizing the trajectory, the
handwriting input/output system of the invention can recognize the
trajectory information with high accuracy, and, by converting into
a semantic information code, transmit the process instruction of
that meaning.
[0055] The process instruction unit preferably instructs the
information processing unit to execute the first operation, that
is, to input the recognition result of the trajectory information
by the trajectory recognition unit as a text and/or a figure.
[0056] According to the above feature, the handwriting input/output
system of the invention can write a text or a picture by
handwriting input.
[0057] The process instruction unit preferably instructs the
information processing unit to execute the second operation, that
is, to input the recognition result of the trajectory information
by the trajectory recognition unit as a comment.
[0058] According to the above feature, the handwriting input/output
system of the invention can input a comment text, in addition to a
text and a picture input by handwriting.
[0059] The process instruction unit preferably instructs the
information processing unit to execute the third operation, that
is, by defining the recognition result of the trajectory
information by the trajectory recognition unit as an edit mark for
editing a text and/or a figure and/or a comment, to edit a text
and/or a figure and/or a comment based on the edit mark.
[0060] According to the above feature, the handwriting input/output
system of the invention can edit a text or an image (including the
one not input by the handwriting input/output system) by
handwriting input.
[0061] Preferably, the handwriting input/output system of the
invention further comprising: an angle measuring unit that at least
measures the inclination and the inclination direction of an
imaging light axis of the imaging unit in contact with the medium
surface when the imaging unit is tilted with reference to a
perpendicular line to the medium surface; and an angle change
recognition unit that analyzes a predetermined change in the
inclination and/or the direction by a grid tilt operation, that is,
a motion of tilting the imaging unit with reference to the
inclination and the direction measured when the imaging unit
becomes in contact with the medium surface, wherein the process
instruction unit transmits a predefined process instruction to the
information processing unit based on the result of the
analysis.
[0062] According to the above feature, the handwriting input/output
system of the invention can instruct operations by the grid tilt
operation of the imaging unit.
[0063] It is preferable that the dot pattern arranged with a
predetermined angle with reference to the direction of the writing
area is formed on the writing area on the medium, and the angle
measuring unit and the angle change recognition unit analyze a
predetermined change in the inclination direction and/or the
inclination of the imaging unit tilted toward the writing area with
reference to the direction of the dot pattern read out when the
imaging unit became in contact with the writing area surface.
[0064] According to the above feature, the handwriting input/output
system of the invention can recognize an inclination and a change
therein with reference to the direction of the dot pattern, in
addition to a change in the angle.
[0065] It is preferable that, when the angle change recognition
unit recognizes that the imaging unit is tilted to the first
predetermined direction with reference to the upward direction of
the imaging unit or the writing area by the grid tilt operation,
the process instruction unit instructs the information processing
unit to execute the first operation, that is, to input the
recognition result of trajectory information by the trajectory
recognition unit as a text and/or a figure.
[0066] According to the above feature, the handwriting input/output
system of the invention can switch to the first operation by the
grid tilt operation.
[0067] It is preferable that, when the angle change recognition
unit recognizes that the imaging unit is tilted to the second
predetermined direction with reference to the upward direction of
the imaging unit or the writing area by the grid tilt operation,
the process instruction unit instructs the information processing
unit to execute the second operation, that is, to input the
recognition result of trajectory information by the trajectory
recognition unit as a comment.
[0068] According to the above feature, the handwriting input/output
system of the invention can switch to the second operation by the
grid tilt operation.
[0069] It is preferable that, when the angle change recognition
unit recognizes that the imaging unit is tilted to the third
predetermined direction with reference to the upward direction of
the imaging unit or the writing area by the grid tilt operation,
the process instruction unit instructs the information processing
unit to execute the third operation, that is, by defining the
recognition result of trajectory information by the trajectory
recognition unit as an edit mark for editing a text and/or a
comment, to edit a text and/or a figure and/or a comment based on
the edit mark.
[0070] According to the above feature, the handwriting input/output
system of the invention can switch to the third operation by the
grid tilt operation.
[0071] It is preferable that, when the angle change recognition
unit recognizes that the imaging unit is tilted to the fourth
predetermined direction with reference to the upward direction of
the imaging unit or the writing area by the grid tilt operation,
the process instruction unit instructs the information processing
unit to terminate the third operation.
[0072] According to the above feature, the handwriting input/output
system of the invention can terminate the third operation by the
grid tilt operation and switch to the first or second operation or
execute the third operation again.
[0073] It is preferable that, when the information processing unit
determines whether to execute a predetermined process or not and
when the dot pattern analysis unit recognizes that the imaging unit
touches the medium surface only once during a predetermined time
period, the process instruction unit instructs the information
processing unit to determine not to execute the predetermined
process, and when the dot pattern analysis unit recognizes that the
imaging unit touches the medium surface once and touches again
during a predetermined time period, the process instruction unit
instructs the information processing unit to determine to execute
the predetermined process.
[0074] According to the above feature, the handwriting input/output
system of the invention can instruct determination or refusal of a
process only by touching on the medium surface by the imaging
unit.
[0075] It is preferable that the handwriting input/output system of
the invention further comprises: a rotation angle reading unit that
reads out a rotation angle between the direction of the dot pattern
read out when the imaging unit became in contact with the writing
area surface by standing imaging light axis of the imaging unit
generally perpendicular to the writing area surface and the angle
of the imaging unit; and a rotation angle change recognition unit
that, when the imaging light axis is rotated in a predetermined
rotation direction by a grid turn operation, that is, a motion that
rotates the imaging unit, analyzes a predetermined change in the
rotation angle with reference to the rotation angle measured when
the imaging unit became in contact with the writing area surface,
wherein the process instruction unit transmits a predetermined
process instruction to the information processing unit based on the
result of the analysis.
[0076] According to the above feature, the handwriting input/output
system of the invention can make instruction by the grid turn
operation.
[0077] It is preferable that, when the rotation angle change
recognition unit recognizes that the imaging unit is rotated in the
first predetermined direction, the process instruction unit
instructs the information processing unit to store the change
result of the file content of a running application, and when the
rotation angle change recognition unit recognizes that the imaging
unit is rotated in the second predetermined direction that is the
opposite direction to the first predetermined direction, the
process instruction unit instructs the information processing unit
to cancel the change of the file content of the running
application.
[0078] According to the above feature, the handwriting input/output
system of the invention can make instruction of storing or
canceling of the change in the file content by the grid turn
operation.
[0079] It is preferable that, when the rotation angle change
recognition unit recognizes that the imaging unit is rotated in the
first predetermined direction and further rotated in the second
predetermined direction that is the opposite direction to the first
predetermined direction during a predetermined time period, the
process instruction unit instructs the information processing unit
to start up an application for handwriting input/output, and when
the rotation angle change recognition unit recognizes that the
imaging unit is rotated in the second predetermined direction and
further rotated in the first predetermined direction during a
predetermined time period, the process instruction unit instructs
the information processing unit to terminate the application for
handwriting input/output.
[0080] According to the above feature, the handwriting input/output
system of the invention can start up/terminate the application for
handwriting input/output by the grid turn operation.
[0081] It is preferable that the handwriting input/output system of
the invention further comprises: a sound recording unit that, after
imaging of the writing area by the imaging unit and obtaining of
coordinate information and code information by the dot pattern
analysis unit, records a sound, instead of tracing or drawing a
letter or a character on the writing area by a predetermined
operation with the imaging unit; and a sound recognition unit that
refers to a predefined sound recognition information table (a
dictionary) corresponding to the code information, recognizes the
recorded sound, converts it to text information, and transmits the
text information to the information processing unit.
[0082] According to the above feature, the handwriting input/output
system of the invention allows sound input instead of handwriting
input.
[0083] The predetermined operation is preferably performed either
by tracing or drawing a symbol signifying a sound input on the
writing area using the imaging unit.
[0084] According to the above feature, the handwriting input/output
system of the invention can easily switch to sound input as the
extension of a series of handwriting input operations, and leave
the log of starting the sound input in the writing area or the
computer.
[0085] It is preferable that the predetermined operation is
performed by touching the writing area with imaging unit and
flicking the imaging unit.
[0086] According to the above feature, the handwriting input/output
system of the invention can easily switch to sound input by even
easier operation, and use the sound input without leaving the log
of starting the sound input in the writing area.
[0087] The predetermined operation is preferably performed by
recording a predetermined word in the sound recording unit and
recognizing the predetermined word by the sound recognition
unit.
[0088] According to the above feature, with the handwriting
input/output system of the invention, the operation of starting the
sound input can be intuitively performed without remembering
cumbersome operations.
[0089] It is preferable that instruction information of voice
guidance is defined in advance in the code information of the
medium, and the handwriting input/output system further comprises a
sound output unit that explains a content to be written on the
writing area by the voice guidance.
<Handwriting Input Sheet>
[0090] The handwriting input sheet of the invention comprises a
medium having a writing area on which is formed a dot pattern that
repeatedly defines coordinate information and code information at
least part of or a plurality of areas of the medium.
[0091] According to the above feature, by defining code information
as well as coordinate information in the dot pattern formed on the
medium, the handwriting input sheet of the invention can
collectively input coordinate information and unique information by
handwriting input.
[0092] It is preferable that the medium is formed by further being
superimposed with a text, a graphic, and a photograph relating to
the writing area.
[0093] According to the above feature, in the handwriting input
sheet of the invention, a user can easily recognize the content of
the writing area when performing the handwriting input.
[0094] It is preferable that the medium is formed by being further
superimposed by an icon signifying code information over the dot
pattern that repeatedly forms the code information that defines:
identification information that identifies a predetermined medium
surface and/or the writing area surface; and/or an operation
instruction (e.g., starting up a program, inputting a command,
inputting and outputting/searching data, specifying searching
information).
[0095] According to the above feature, with the handwriting input
sheet of the invention, a user can further recognize the content of
unique information or instruction input based on the code
information.
[0096] The icon is preferably formed with the dot pattern on a
sticker and sticky note that can be attached somewhere, and other
medium surfaces.
[0097] According to the above feature, the handwriting input sheet
of the invention can enhance flexibility of layout on a medium,
allowing searching and outputting of information input by
handwriting on the writing area to be flexibly executed according
to a user's convenience and preference.
[0098] The handwriting input sheet preferably further comprises
Braille within and/or around the writing area.
[0099] According to the above feature, when visually impaired
people perform handwriting input, the handwriting input sheet of
the invention contributes to maintain input efficiency close to
equivalent to physically unimpaired people.
[0100] The handwriting input sheet of the invention preferably
further comprises a thin convex guide along the external
circumference of the writing area so that the imaging unit does not
go over the boundary when writing in the writing area.
[0101] According to the above feature, when visually impaired
people perform handwriting input, the handwriting input sheet of
the invention contributes to maintain input efficiency close to
equivalent to physically unimpaired people by providing a guide for
accurate tracing or drawing within the writing area.
<Information Input System>
[0102] The information input system of the invention comprising: an
information input assistance sheet, that is, a grid sheet,
laminated with: an infrared reflection layer that reflects infrared
rays yet transmits visible light coming from one side; a dot
pattern layer that is provided on the one side of the infrared
reflection layer and made of material having a characteristic of
diffusely reflecting infrared rays, and arranged with the dots of a
dot pattern that repeatedly defines coordinate information and/or
code information in at least part of or a plurality of areas; and a
protection layer that is provided on a side of the dot pattern
layer opposite to the infrared reflection layer and has a
characteristic of transmitting infrared rays and visible light, a
medium at least part of which surface is formed with the dots of
the dot pattern with material having a characteristic of absorbing
infrared rays; an imaging unit that images the dot pattern and
transmits image data; a dot pattern analysis unit that determines
by a predetermined determination method a dot portion imaged with
lower brightness than surrounding area in image data of the dot
pattern of the medium surface imaged and transmitted by the imaging
unit or a dot portion imaged with higher brightness than
surrounding area in image data of the dot pattern of the grid sheet
imaged and transmitted by the imaging unit, stores the image data
of the dot pattern into the storage element, and analyzes the code
of the image data to input the coordinate information and/or code
information.
[0103] According to the above feature, the information input system
of the invention can avoid the eyeball phenomenon without providing
a diffuse reflection layer on the grid sheet.
[0104] It is preferable that the predetermined determination method
comprises: a method of sequentially calculating a difference
(+.DELTA.BL=BL(i, j+k)-BL(i, j)) of brightness (BL(i, j)) of a
captured image that is stored in a storage element and has m rows
and n columns of pixels between pixels that are apart at a
predetermined interval (k) beginning from a left end shifting in a
rightward direction for each row (i) to determine whether the
difference exceeds or falls below a predetermined positive/negative
threshold; for determining a dot portion imaged with lower
brightness than surrounding area, a method of determining a pixel
on right side as a dot when a difference in the brightness falls
below a negative threshold and that the dot starts from the pixel,
and a pixel on right side not as a dot when a difference in the
brightness exceeds a positive threshold and that the dot ends
before the pixel; and for determining a dot portion imaged with
higher brightness than surrounding area, a method of determining a
pixel on right side as a dot when a difference in the brightness
exceeds a positive threshold and that the dot starts from the
pixel, and a pixel on right side not as a dot when a difference in
the brightness falls below a negative threshold and that the dot
ends before the pixel, wherein the dot pattern analysis unit
determines by the predetermined determination method whether the
dot pattern is the one provided on the medium surface or on the
grid sheet and analyzes a code by the predetermined determination
method.
[0105] It is preferable that the predetermined determination method
measures brightness of a predetermined area of the captured image,
then, if the brightness exceeds a predetermined threshold, a
determination method for a dot portion imaged with lower brightness
than surrounding area is used, and if the brightness falls below a
predetermined threshold, a determination method for a dot portion
imaged with higher brightness than surrounding area is used.
<Information Input Assistance Sheet>
[0106] The information input assistance sheet of the invention is
laminated with: an infrared reflection layer that reflects infrared
rays yet transmits visible light coming from one side; a dot
pattern layer that is provided on the one side of the infrared
reflection layer and made of material having a characteristic of
diffusely reflecting infrared rays, and arranged with dots of a dot
pattern that defines coordinate information and/or code information
in at least part of or a plurality of areas; and a protection layer
that is provided on the side of the dot pattern layer opposite to
the infrared reflection layer and has a characteristic of
transmitting infrared rays and visible light.
[0107] According to the above feature, the information input
assistance sheet of the invention can avoid the eyeball phenomenon
without providing a diffuse reflection layer thereon.
[0108] The information input assistance sheet of the invention is
laminated with: an infrared reflection layer that reflects infrared
rays coming from both sides and transmits visible light; dot
pattern layers that are provided on both sides of the infrared
reflection layer, made of material having a characteristic of
absorbing infrared rays, and arranged with dots of the dot pattern;
and protection layers that are provided on further outer sides of
the dot pattern layers and have a characteristic of transmitting
infrared rays and visible light coming from both directions,
wherein coordinate information and/or code information that is made
into a pattern in the dot pattern and arranged on each of the dot
pattern layers is identical or different from each other.
[0109] According to the above feature, the information input
assistance sheet of the invention can avoid the eyeball phenomenon
without providing a diffuse reflection layer thereon.
[0110] It is preferable that, in the handwriting input/output
system of the invention, the writing area is of an arbitrary
shape.
[0111] Conventionally, to identify a writing area using only
coordinate information, the coordinates indicating the boundary of
the writing area should be defined in advance using a table or a
function, and each input coordinate value should be determined
whether it is within the scope of the table or the function. As the
result, the analysis becomes complicated and to identify the
writing area using only coordinate information, the writing area
has to be of a generally rectangle shape to maintain analysis
efficiency of used memory and calculation speed. Using code
information to identify the writing area, the present invention can
exhibit similar analysis efficiency whatever the shape of the
writing area may be.
[0112] In the handwriting input/output system and the handwriting
input sheet of the invention, it is preferable that the medium
comprises: a writing area formed with a dot pattern in which a
plurality of reference points are provided so as to form the size
and direction of a block within the area of the block for arranging
an information dot, a plurality of virtual reference points that
are defined with reference to the reference points are arranged,
the information dot that defines coordinate information or
coordinate information and code information by a distance and
direction from the virtual reference point is arranged, the
coordinate information or the coordinate information and code
information is repeatedly defined at least part of or a plurality
of areas in a predetermined combination of arrangement directions
of the information dot among a plurality of combinations of
arrangement directions of the information dot with reference to the
plurality of virtual reference points, and the dot pattern analysis
unit determines the writing area based on the predetermined
combination of arrangement directions of the information dot and
processes handwriting input.
[0113] According to the above feature, when inputting by
handwriting, without operation to a button separately provided to
the handwriting input/output system or reading a dot pattern that
defines a predetermined operation direction of handwriting input by
the imaging unit, the writing area is determined only by analyzing
the code of a predetermined combination of arrangement directions
of the information dot by the dot pattern analysis unit and, if it
is a writing area, the process of handwriting input is executed. If
it is not a writing area, information output and/or instruction
process that is associated to the code information and/or
coordinate information is executed.
[0114] In the handwriting input/output system and handwriting input
sheet of the invention, it is preferable that the predetermined
combination of arrangement directions of the information dot is a
predetermined combination of arrangement directions of the
information dot among combinations of arrangement directions where
the information dot is arranged in any one of upward, downward,
leftward, rightward directions and diagonal directions from each of
the plurality of virtual reference points.
[0115] According to the above feature, as the arrangement direction
of the information dot is restricted to upward, downward, leftward,
rightward, and diagonal directions, the dot pattern analysis unit
can accurately recognize the predetermined combination of
arrangement directions of the information dot, then, determine
whether or not the target is a writing area, and, if it is a
writing area, performs a process of handwriting input. If it is not
a writing area, information output and/or instruction process that
is associated to the code information and/or coordinate information
is executed.
[0116] It is preferable that the code information defines a writing
flag indicating that there is a writing area, and the dot pattern
analysis unit processes handwriting input by identifying that there
is the writing area based on the writing flag.
[0117] According to the above feature, when the imaging unit reads
out the dot pattern formed on the medium surface, the dot pattern
analysis unit immediately determines whether or not the target area
is a writing area, and, if it is a writing area, performs a process
of handwriting input. If it is not a writing area, information
output and/or instruction process that is associated to the code
information and/or coordinate information is executed.
[0118] It is preferable that the code information defines
identification information that identifies the writing area and/or
an operation instruction meaning a writing process, and the dot
pattern analysis unit processes handwriting input/output by
identifying the identification information and/or the operation
instruction.
[0119] According to the above feature, when the imaging unit reads
out the dot pattern formed on the medium surface, the imaging unit
can immediately identify which writing area is to be written in. If
a content to be input by handwriting in this writing area belongs
to a predetermined category, the recognition rate significantly
increases by referring to the dictionary of that category. Further,
appropriate process can be performed by determining how to process
the written content.
[0120] It is preferable that the trajectory information comprises:
coordinate information of the center of the imaging area of the
imaging unit, or coordinate information of a position where the
projection for instruction or the pen tip provided near the imaging
unit is in contact with the writing area surface; and the code
information, and the dot pattern analysis unit calculates the
trajectory information by interpolation based on the coordinate
information defined in the dot pattern.
[0121] According to the above feature, in the coordinate
information defined by the dot pattern, as one unit increments for
each block that defines one pair of XY coordinate values, a
predetermined precision of smaller than one unit required for
accurately reproducing trajectory information can be calculated by
interpolation based on the coordinate information. For example, if
the size of a block is 2 mm, XY coordinate values may be calculated
with the precision of approximately 0.1-0.2 mm, tenth to twentieth
of 2 mm, to recognize trajectory information for accurately
reproducing a letter or a character.
Advantageous Effect of the Invention
[0122] Having the above-described variety of features, the present
invention can provide a handwriting input/output system that can
provide users new and diversified additional values and
convenience, which is a new level of technique absolutely different
from conventional techniques.
BRIEF DESCRIPTION OF THE DRAWINGS
[0123] FIG. 1 is an external view showing a use situation of the
handwriting input/output system of the invention.
[0124] FIG. 2 is a block diagram showing the configuration of the
first embodiment of the handwriting input/output system of the
invention.
[0125] FIG. 3 is a block diagram showing the configuration of the
second embodiment of the handwriting input/output system of the
invention.
[0126] FIG. 4 is a block diagram showing the configuration of the
third embodiment of the handwriting input/output system of the
invention.
[0127] FIG. 5 is a block diagram showing the configuration of the
fourth embodiment of the handwriting input/output system of the
invention.
[0128] FIG. 6 is a block diagram showing the configuration of the
fifth embodiment of the handwriting input/output system of the
invention.
[0129] FIG. 7 is a block diagram showing the configuration of the
sixth embodiment of the handwriting input/output system of the
invention.
[0130] FIG. 8 is a diagram illustrating a dot pattern used for the
handwriting input/output system of the invention (1).
[0131] FIGS. 9A and 9B are diagrams illustrating a dot pattern used
for the handwriting input/output system of the invention (2).
[0132] FIG. 10 is a diagram illustrating a dot pattern used for the
handwriting input/output system of the invention (3).
[0133] FIG. 11 is a diagram illustrating a dot pattern used for the
handwriting input/output system of the invention (4).
[0134] FIGS. 12A to 12C are diagrams illustrating a dot pattern
used for the handwriting input/output system of the invention
(5).
[0135] FIGS. 13A to 13D are diagrams illustrating a dot pattern
used for the handwriting input/output system of the invention
(6).
[0136] FIGS. 14A to 14C are diagrams illustrating a direction dot
used for the handwriting input/output system of the invention.
[0137] FIGS. 15A to 15D are diagrams illustrating a dot pattern
used for the handwriting input/output system of the invention
(7).
[0138] FIGS. 16A to 16D are external views showing the entire
configuration of the imaging unit used for the handwriting
input/output system of the invention.
[0139] FIGS. 17A to 17E are diagrams illustrating the function of
the imaging unit used for the handwriting input/output system of
the invention (1).
[0140] FIGS. 18A to 18C are diagrams illustrating the function of
the imaging unit used for the handwriting input/output system of
the invention (2).
[0141] FIG. 19 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (3).
[0142] FIG. 20 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (4).
[0143] FIG. 21 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (5).
[0144] FIG. 22 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (6).
[0145] FIG. 23 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (7).
[0146] FIG. 24 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (8).
[0147] FIG. 25 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (9).
[0148] FIG. 26 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (10).
[0149] FIG. 27 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (11).
[0150] FIG. 28 is a diagram illustrating the function of the
imaging unit used for the handwriting input/output system of the
invention (12).
[0151] FIG. 29 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (1).
[0152] FIG. 30 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (2).
[0153] FIG. 31 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (3).
[0154] FIGS. 32A and 32B are diagrams illustrating the function of
the medium on which is formed the writing area used for the
handwriting input/output system of the invention (4).
[0155] FIG. 33 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (5).
[0156] FIG. 34 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (6).
[0157] FIG. 35 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (7).
[0158] FIG. 36 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (8).
[0159] FIG. 37 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (9).
[0160] FIG. 38 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (10).
[0161] FIGS. 39A and 39B are diagrams illustrating the function of
the medium on which is formed the writing area used for the
handwriting input/output system of the invention (11).
[0162] FIGS. 40A and 40B are diagrams illustrating the function of
the medium on which is formed the writing area used for the
handwriting input/output system of the invention (12).
[0163] FIGS. 41A and 41B are diagrams illustrating the function of
the medium on which is formed the writing area used for the
handwriting input/output system of the invention (13).
[0164] FIG. 42 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (14).
[0165] FIG. 43 is a diagram illustrating the method for calculating
the direction and angle of the inclination of the imaging unit used
for the handwriting input/output system of the invention (1).
[0166] FIGS. 44A and 44B are diagrams illustrating the method for
calculating the direction and angle of the inclination of the
imaging unit used for the handwriting input/output system of the
invention (2).
[0167] FIG. 45 is a diagram illustrating the method for calculating
the direction and angle of the inclination of the imaging unit used
for the handwriting input/output system of the invention (3).
[0168] FIGS. 46A and 46B are diagrams illustrating the method for
calculating the direction and angle of the inclination of the
imaging unit used for the handwriting input/output system of the
invention (4).
[0169] FIG. 47 is a diagram illustrating the method for calculating
the direction and angle of the inclination of the imaging unit used
for the handwriting input/output system of the invention (5).
[0170] FIGS. 48A to 48E are diagrams illustrating a method of
determining the touching motion and flicking motion of the imaging
unit used for the handwriting input/output system of the
invention.
[0171] FIG. 49A to 49E are diagrams illustrating the first
operation in the handwriting input/output system of the
invention.
[0172] FIG. 50 is a diagram illustrating the second operation in
the handwriting input/output system of the invention (1).
[0173] FIG. 51 is a diagram illustrating the second operation in
the handwriting input/output system of the invention (2).
[0174] FIG. 52 is a diagram illustrating the second operation in
the handwriting input/output system of the invention (3).
[0175] FIG. 53 is a diagram illustrating the third operation in the
handwriting input/output system of the invention (1).
[0176] FIG. 54 is a diagram illustrating the third operation in the
handwriting input/output system of the invention (2).
[0177] FIG. 55 is a diagram illustrating the third operation in the
handwriting input/output system of the invention (3).
[0178] FIG. 56 is a diagram illustrating the third operation in the
handwriting input/output system of the invention (4).
[0179] FIG. 57 is a diagram illustrating the third operation in the
handwriting input/output system of the invention (5).
[0180] FIG. 58 is a diagram illustrating the third operation in the
handwriting input/output system of the invention (6).
[0181] FIG. 59 is a diagram illustrating a method of storing the
changed result of a file by rotating motion of the imaging unit in
the handwriting input/output system of the invention.
[0182] FIG. 60 is a diagram illustrating a method of canceling the
changed content of a file by rotating motion of the imaging unit in
the handwriting input/output system of the invention.
[0183] FIG. 61 is a diagram illustrating a method of starting up
the application by rotating motion of the imaging unit in the
handwriting input/output system of the invention.
[0184] FIG. 62 is a diagram illustrating a method of terminating
the application by rotating motion of the imaging unit in the
handwriting input/output system of the invention.
[0185] FIGS. 63A to 63D are diagrams illustrating a method of
switching operations by tilting motion of the imaging unit in four
directions in the handwriting input/output system of the invention
(1).
[0186] FIG. 64 is a diagram illustrating a method of switching
operations by tilting motion of the imaging unit in four directions
in the handwriting input/output system of the invention (2).
[0187] FIGS. 65A and 65B are diagrams illustrating touch motion of
the imaging unit in the handwriting input/output system of the
invention.
[0188] FIG. 66 is a block diagram illustrating the configuration of
the sound recording unit and sound output unit in the handwriting
input/output system of the invention.
[0189] FIG. 67 is a diagram illustrating flicking motion of the
imaging unit in the handwriting input/output system of the
invention.
[0190] FIG. 68 is a diagram illustrating a grid sheet that is an
embodiment of the medium used for the handwriting input/output
system of the invention (1).
[0191] FIGS. 69A and 69B are diagrams illustrating the grid sheet
that is an embodiment of the medium used for the handwriting
input/output system of the invention (2).
[0192] FIGS. 70A and 70B are diagrams illustrating the grid sheet
that is an embodiment of the medium used for the handwriting
input/output system of the invention (3).
[0193] FIGS. 71A to 71G are diagrams illustrating the grid sheet
that is an embodiment of the medium used for the handwriting
input/output system of the invention (4).
[0194] FIGS. 72A to 72F are diagrams illustrating the grid sheet
that is an embodiment of the medium used for the handwriting
input/output system of the invention (5).
[0195] FIGS. 73A and 73B are diagrams illustrating the grid sheet
used for the information input system of the invention (1).
[0196] FIGS. 74A and 74B are diagrams illustrating the grid sheet
used for the information input system of the invention (2).
[0197] FIG. 75 is a diagram illustrating the grid sheet used for
the information input system of the invention (3).
[0198] FIG. 76 is a diagram illustrating the grid sheet used for
the information input system of the invention (4).
[0199] FIG. 77 is a diagram illustrating the grid sheet used for
the information input system of the invention (5).
[0200] FIG. 78 is a diagram illustrating the function of the medium
on which is formed the writing area used for the handwriting
input/output system of the invention (15).
[0201] FIGS. 79A and 79B are diagrams illustrating a dot pattern
used for the handwriting input/output system of the invention
(7).
[0202] FIGS. 80A and 80B are diagrams illustrating the dot pattern
used for the handwriting input/output system of the invention
(8).
BEST MODE FOR CARRYING OUT THE INVENTION
[0203] The following describes embodiments of the present invention
with reference to the drawings:
[0204] <Description of the Configuration of the Entire
System>
[0205] FIG. 1 is an external view showing an example of a use
situation of handwriting input/output system 1 of the invention.
According to FIG. 1, if scanner 3 is used to write on medium 2, a
text just as being written is displayed on display 6. This is
realized by imaging a dot pattern on the written trajectory by
scanner 3 and analyzing the image data by computer 4 (and accessing
server 5 if necessary). However, computer 4 may be embedded in
scanner 3.
[0206] FIG. 2 is a block diagram showing the configuration of the
first embodiment of handwriting input/output system 1 of the
invention.
[0207] This handwriting input/output system 1 at least comprises:
medium 2 (handwriting input sheet), imaging unit 7 (imaging means),
dot pattern analysis unit 8 (dot pattern analysis means),
trajectory recognition unit 9 (trajectory recognition means), and
process instruction unit 10 (process instruction means) to perform
a variety of instructions to information processing unit 11 and
access variety of servers 5 if necessary.
[0208] FIG. 3 is a block diagram showing the configuration of the
second embodiment of handwriting input/output system 1 of the
invention. The second embodiment further comprises imaging element
12, irradiation unit 13, and light control unit 14 in addition to
the configuration that the first embodiment comprises.
[0209] Here, as shown by dashed lines in FIG. 3, imaging element 12
and irradiation unit 13 are integrated in imaging unit 7, and light
control unit 14 is integrated in dot pattern analysis unit 8.
[0210] FIG. 4 is a block diagram showing the configuration of the
third embodiment of handwriting input/output system 1 of the
invention. The third embodiment further comprises timer 15 in
addition to the configuration that the first embodiment
comprises.
[0211] Here, as shown by a dashed line in FIG. 4, timer 15 is
integrated in trajectory recognition unit 9.
[0212] FIG. 5 is a block diagram showing the configuration of the
fourth embodiment of handwriting input/output system 1 of the
invention. The fourth embodiment further comprises angle measuring
unit 16 and angle change recognition unit 17 in addition to the
configuration that the first embodiment comprises.
[0213] Here, as shown by dashed lines in FIG. 5, angle measuring
unit 16 and angle change recognition unit 17 are integrated in dot
pattern analysis unit 8.
[0214] FIG. 6 is a block diagram showing the configuration of the
fifth embodiment of handwriting input/output system 1 of the
invention. The fifth embodiment further comprises rotation angle
reading unit 18, rotation angle change recognition unit 19 in
addition to the configuration that the first embodiment
comprises.
[0215] Here, as shown by dashed lines in FIG. 6, rotation angle
reading unit 18 and rotation angle change recognition unit 19 are
integrated in dot pattern analysis unit 8.
[0216] FIG. 7 is a block diagram showing the configuration of the
sixth embodiment of the handwriting input/output system of the
invention. The sixth embodiment further comprises sound recording
unit 20, sound recognition unit 21, and sound output unit 22 in
addition to the configuration that the first embodiment
comprises.
[0217] <Dot Pattern>
[0218] The following describes the dot pattern used in handwriting
input/output system 1 of the invention with reference to FIGS. 8 to
15D.
[0219] <Description of Dot Pattern; GRID1>
[0220] FIGS. 8 to 15D are diagrams illustrating an example of a dot
pattern formed on medium 2, that is, GRID1, in handwriting
input/output system 1 of the invention
[0221] It should be noted that in FIGS. 8 to 15D, the grid lines in
horizontal and vertical directions are added for convenience of
explanation, and do not exist in actual printing surface. It is
desirable that when scanner 3 as imaging means has an infrared
irradiation unit, the dot pattern 101 constituents, such as key dot
102, information dot 103, and reference grid point dot 104, are
printed with invisible ink which absorbs the infrared light or with
carbon ink.
[0222] FIG. 8 is an enlarged view showing an example of an
information dot of dot pattern 101 and the bit expression of data
defined therein. FIGS. 9A and 9B are explanatory views showing
information dot 103 arranged around key dot 102.
[0223] The information input/output method using the dot pattern
comprises a unit for generating dot pattern 101, a unit for
recognizing dot pattern 101, and a unit for outputting information
and a program from this dot pattern 101. That is, after retrieving
dot pattern 101 as image data by imaging unit 7 embedded in scanner
3, first, the method extracts reference grid point dot 104, next,
extracts key dot 102 based on the fact that there is no dot at the
location where reference grid point dot 104 is supposed to be,
extracts information dot 103, and digitizes information dot 103 to
extract the information region and convert the information into
numerical values. Based on the numerical information, information
and a program are output from this dot pattern 101. For example,
information, such as a sound and a program, is output, from this
dot pattern 101, to an information output device, personal
computer, PDA, mobile telephone, or the like.
[0224] To generate dot pattern 101, based on a dot code generation
algorithm, fine dots used for recognition of numerical information
including key dot 102, information dot 103, and reference grid
point dot 104 are arranged according to a predetermined rule. As
shown in FIG. 7, in a block of dot pattern 101 that represents
information, 5.times.5-reference grid point dots 104 are arranged
with reference to key dot 102, and information dot 103 is arranged
around virtual grid point 105 that is surrounded by four reference
grid point dots 104. Arbitrary numerical information is defined in
this block. The example illustrated in FIG. 8 shows four blocks of
dot patterns 101 arranged in parallel (in bold frame), provided,
however, that dot pattern 101 is not limited to four blocks and may
be repeatedly arranged many times in upper, lower, leftward, and
rightward directions.
[0225] When imaging unit 7 retrieves this dot pattern 101 as image
data, the reference grid point dots 104 can correct a distortion of
the lens of imaging unit 7, skewed imaging, expansion and
contraction of a paper surface, curvature of a medium surface, and
distortion during printing. Specifically, a function for
calibration (Xn, Yn)=f(Xn', Yn') is calculated to convert distorted
four reference grid point dots 104 into the original square, then
the vector of correct information dot 103 is obtained by
calibrating information dot 103 by the same function.
[0226] If reference grid point dots 104 are arranged in dot pattern
101, since the image data of this dot pattern 101 retrieved by
imaging unit 7 is calibrated its distortion attributable to imaging
unit 7, image data of dot pattern 101 can be recognized accurately
even though retrieved by a popular camera with a lens with high
distortion rate. Moreover, dot pattern 101 can be accurately
recognized even when dot pattern 101 is read by imaging unit 7
inclined with reference to the surface of dot pattern 101.
[0227] Key dots 102 are dots, as shown in FIG. 8, arranged by
shifting four reference grid point dots 104 which are disposed at
four corners of a block in certain directions. Key dot 102 is a
representative point of one block of dot pattern 101 that
represents information dot 103. For example, key dots 102 are the
dots being shifted reference grid point dots 104 disposed at four
corners of a block of dot pattern 101 upward by 20% of a gap
between neighbouring reference grid point dots 104 (if a distance
between reference grid point dots is 0.5 mm, by 0.1 mm). However,
these numbers are not limited to these, and may vary depending on
the size of the block of dot pattern 101.
[0228] Information dots 103 are dots used for recognition of a
variety of information.
[0229] Information dot 103 is arranged around key dot 102 as a
representative point and also disposed at the ending point of a
vector with the starting point of virtual grid point 5 at the
center surrounded by four reference grid point dots 104. For
example, this information dot 103 is surrounded by four reference
grid point dots 104. As shown in FIG. 9A, since dots away from the
virtual grid point 5 by 20% of a gap between neighbouring reference
grid point dots 104 (if a distance between reference grid point
dots is 0.5 mm, by 0.1 mm) have direction and length as expressed
by vectors, the dots can express three bits by being disposed in
eight directions by shifting by 45 degrees in a clockwise
direction. Therefore, one block of dot pattern 101 may express 3
bits.times.16=201 bits.
[0230] FIG. 9B is a method of defining information dot 103 having
two bits for each grid, in the dot pattern of FIG. 3. Two-bit
information is each defined by shifting a dot in + direction and x
direction. In this way, although 201-bit information can be indeed
defined, data may be allocated to each 32 bits by dividing for an
intended purpose. Maximum of 2.sup.16 (approx. 65,000) dot pattern
formats can be realized depending on the combination of + direction
and x direction.
[0231] It will be appreciated that the dot pattern format is not
limited to this, and may vary including a possibility of four-bit
expression by arranging the dots in 16 directions. Preferably, when
imaging the dot pattern by moving scanner 3 as imaging means close
to the medium surface or by touching the medium surface with
scanner 3, the dot diameter of key dot 102, information dot 103, or
reference grid point dot 104 is approximately 6-16% of a distance
between neighbouring reference grid point dots 104 (if a gap
between reference grid point dots is 0.5 mm, 0.03-0.08 mm) in
consideration of visual quality, printing accuracy in respect of a
paper quality, resolution of imaging unit 7, and optimal
digitalization. However, it will be appreciated that the dot
pattern is required to be formed so a predetermined dot pattern as
to be imaged within the imaging area, and the arrangement size of
one block of a dot pattern and the diameter of the dot are defined
appropriately, according to the size of the imaging opening of
scanner 3. Moreover, in consideration of information amount
required for an imaging area and possible false recognition of dots
102, 103, 104, a distance between reference grid point dots 104 is
preferably around 0.3-0.5 mm in both vertical and horizontal
directions. Displacement of key dot 102 is preferably around 20-25%
the grid distance, taking into account the possible false
recognition with reference grid point dot 104 and information dot
103.
[0232] On the other hand, it will be appreciated that, when a
non-contact scanner or an embedded camera of a mobile telephone,
not shown, are used as imaging means to image a dot pattern by
keeping them apart from a medium surface by a predetermined
distance, the dot pattern should be formed so a predetermined dot
pattern as to be imaged within the imaging area, and the
arrangement size of one block of the dot pattern and the diameter
of the dot are defined appropriately.
[0233] A distance between this information dot 103 and a virtual
grid point surrounded by four reference grid point dots 104 is
preferably the distance of around 15-30% the gap between
neighbouring virtual grid points 5. If the gap between information
dot 103 and virtual grid point 5 is shorter than this distance, the
dots are easily recognized as a big cluster, and are ugly as dot
pattern 101. On the other hand, if the gap between information dot
103 and virtual grid point 5 is wider than this distance, the
judgment of which one of adjacent virtual grid points 5 is the
center of the vector of information dot 103.
[0234] As shown in FIG. 8, one dot pattern is a dot pattern
comprising 4.times.4 block regions. Two-bit information dot 103 is
arranged in each block. FIGS. 9A and 9B show an example of the dot
code format of this information dot 103.
[0235] As shown in FIG. 10, one dot pattern stores a parity check,
a code value, an X coordinate, and a Y coordinate. It should be
noted that the details of the format will be described later.
[0236] FIG. 11 is an example of information dot 103 and bit
expression of data defined therein, showing another embodiment.
[0237] If two types of information dots 103, long and short
distances from virtual grid point 5 surrounded by reference grid
point dots 104, are used, and vector directions are eight
directions, four bits can be expressed. Here, the long distance one
of information dots 103 is preferably about 25-30% the gap between
neighbouring virtual grid points 5. The short distance one of
information dots 103 is preferably about 15-20% the gap between
neighbouring virtual grid points 5. However, a distance between the
centers of long and short information dots 103 is preferably longer
than the diameter of these dots.
[0238] The number of information dot 103 surrounded by four
reference grid point dots 104 is preferably one dot, taking into
account the visual quality. However, if visual quality is
disregarded and information amount should be increased, voluminous
information can be included by allocating one bit to one vector and
expressing information dot 103 using a plurality of dots. For
example, in eight direction concentric vectors, information dot 103
surrounded by four grid dots 4 can express 2.sup.8 pieces of
information, and thus, 16 information dots in one block accounts
for 2.sup.128.
[0239] FIGS. 12A to 12C are examples of information dots and bit
expression of data defined therein. FIG. 12A is a diagram of
disposing two dots, FIG. 12B is a diagram of disposing four dots,
and FIG. 12C is a diagram of disposing five dots.
[0240] FIGS. 13A to 13D are variants of dot pattern 101. FIG. 13A
is a schematic view of six-information dot arrangement, FIG. 13B is
a schematic view of nine-information dot arrangement, FIG. 13C is a
schematic view of 12-information dot arrangement, and FIG. 13D is a
schematic view of 1036-information dot arrangement.
[0241] Dot pattern 101 shown in FIG. 8 illustrates an example in
which 16 (4.times.4) information dots 103 are arranged in one
block. However, this information dot 103 is not limited to 16-dot
arrangement, and may vary in many ways. For example, depending on
the size of required information amount and the resolution of
imaging unit 7, six information dots 103 (2.times.3) may be
arranged in one block (FIG. 13A), nine information dots 103
(3.times.3) may be arranged in one block (FIG. 13B), 12 information
dots 103 (3.times.4) may be arranged in one block (FIG. 13C), or 36
information dots 103 may be arranged in one block (FIG. 13D).
[0242] <Description of Dot Pattern; Direction Dot>
[0243] Next, another embodiment of the dot pattern, direction dot,
is described with reference to FIGS. 14A to 14C.
[0244] This dot pattern defines the direction thereof by the shape
of the block. Reference points 201a to 201e are first arranged in
FIG. 14A. The shape indicating the orientation of the block is
defined by lines connecting reference points 201a-201e (in this
case, a pentagon facing upward). Then, based on these reference
points, virtual reference points 201f, 201g, 201h are arranged, and
information dot 203 is arranged at the end point of a vector having
a direction and length with this virtual reference point as the
starting point. In this way, in FIG. 14A to FIG. 14C, the
orientation of the block is defined by the way that reference
points are arranged. In addition, the direction dot that defines
the orientation of the block also defines the size of the entire
block. It will be appreciated that this block may be repeatedly
arranged in upper, lower, leftward, and rightward directions.
[0245] It should be noted that, while reference points 201a-201e
and information dot 203 are described as being of the same shapes
in FIG. 14A, the shapes of reference points 201a-201e may be larger
than information dot 203. Further, these reference points 201a-201e
and information dot 203 may be of any shape, as long as they are
identifiable, including a triangle, a rectangular, or other
polygons.
[0246] In FIG. 14B, information is defined by whether or not there
is an information dot on the virtual grid point of a block.
[0247] FIG. 14C shows that each two blocks shown in FIG. 14A are
connected in parallel in horizontal and vertical directions.
[0248] In handwriting input/output system 1 of the invention, the
dot pattern formed on medium 2 is not limited to GRID1 as long as
the dot pattern defines XY coordinate information and code
information.
[0249] For example, there can be used Japanese Patent No. 3766678
(GRID2), Japanese Patent No. 3858051 (GRID3), Japanese Patent No.
3858052 (GRID4), and Japanese Patent Application No. 2009-165163
(Stream dot pattern).
[0250] <Description of Dot Pattern Format>
[0251] FIGS. 15A to 15D are diagrams illustrating the format of a
dot pattern formed on medium 2 in handwriting input/output system 1
of the invention.
[0252] As shown in FIG. 15D, the dot pattern is a dot pattern
comprising 4.times.4 block regions, and the blocks are partitioned
into C.sub.1-0-C.sub.31-30. FIGS. 15A and 15B show the dot code
format of each region.
[0253] FIG. 15A is a format registering a page code, an X
coordinate, and a Y coordinate. The page code means the number of a
page of medium 2 when medium 2 is a booklet, and the X coordinate
and the Y coordinate respectively mean a position (a coordinate
value) on the medium. In this way, when a user scans medium 2 using
scanner 3, the page number of the medium and the coordinate
position of a read portion are simultaneously recognized by one
scanning operation.
[0254] FIG. 15B is a format registering a page code, an action
code, an X coordinate, and a Y coordinate. The action code means an
operation direction. For example, the action code is defined only
in regions where icons signifying operations, such as "Zoom in" and
"Zoom out," are drawn on the page, and included in the dot pattern
used in the icon regions described later. Further, if the action
code is defined in the entire writing area of the page and a
necessary process is performed during or after handwriting input,
the corresponding instruction process may be related with the
action code and executed. The instruction process, for example, is
a process to recognize a text or transmit a text to another
information processing device during or after handwriting input. It
should be noted that, while the specific writing area code in ( )
is used as a page code here, a plurality of the specific writing
area codes may be provided on a medium surface and these writing
areas may be defined by unique page codes so that what is written
where can be immediately determined. It will be appreciated that
the specific writing area code may be defined in combination with a
page code so that which writing area on which page can be
determined. Further, if a handwritten input content belongs to a
predetermined category, the recognition rate is significantly
improved by referring to the dictionary of that category. The
handwritten input content may be a symbol or an illustration in
addition to a letter and a character. It will be appreciated that
the action code may be defined in combination with the specific
writing area code to execute the corresponding instruction
process.
[0255] In FIG. 15C, by providing a writing area flag, when the
imaging unit images the dot pattern formed on a medium surface and
dot pattern analysis unit 8 analyzes the dot pattern, whether it is
a writing area or not can be immediately known. If it is not a
writing area, information output and/or instruction processing
associated to the code value/coordinate value is executed. If it is
the writing area, a predetermined process of handwriting input is
executed by the trajectory recognition unit. It will be appreciated
that this writing area flag may also be provided with the page code
(specific writing area code) or the action code in FIGS. 15A and
15B.
[0256] In this way, the dot pattern of the invention can register a
variety of code information including a page code and an action
code, and XY coordinates in one format. Alternatively, the dot
pattern can register only either XY coordinates or code
information. The format can be flexible.
<Imaging Unit>
[0257] FIGS. 16A-28 are diagrams illustrating imaging unit 7 used
for the handwriting input/output system 1 of the invention.
[0258] It should be noted that imaging unit 7 is preferably the
size and shape suitable for a person to hold, and most preferably,
a pen shape as shown in FIGS. 16A-16D.
[0259] FIG. 16A is a diagram showing the most basic embodiment of
imaging unit 7 of pen shape. In such an embodiment, projection for
instruction 23, transmission unit 24 are provided, and a C-MOS
sensor, which is not shown, is embedded generally along the axis of
the pen. Transmission unit 24 is equipped to allow imaging unit 7
to transmit a signal to other members using infrared communication,
wireless communication, or other methods. While transmission unit
24 is described for convenience of description, it does not have to
be provided somewhere to be seen from outside.
[0260] FIG. 16B and FIG. 16C are diagrams showing other embodiments
of pen-shaped imaging unit 7. In this embodiment, two buttons are
provided to accept operations by a user. Such two buttons are
transmission button 25 and retransmission button 26, and a user can
instruct imaging unit 7 to transmit a signal to other members by a
button operation. Here, retransmission button 26 is used to
retransmit the same signal when a signal transmitted by
transmission button 25 could not reach other destination members
due to the existence of a shielding material or other reasons.
[0261] FIG. 16C is a diagram showing another embodiment of
pen-shaped imaging unit 7. This embodiment is further provided with
microphone 27 for accepting sound input by a user and sound play
button 28. Microphone 27 is used for recording a sound used for
sound recognition, which is described later, and sound play button
28 is used for reproducing voice guidance, which is described
later.
[0262] FIG. 16D is a diagram showing another embodiment of
pen-shaped imaging unit 7. In this embodiment, pen 29 is stored in
the inner space of projection for instruction 23. Pen 29 comes out
by pressing pen retract button 30.
[0263] FIG. 17A is a section view showing the leading end of
pen-shaped scanner 31, which is an embodiment of imaging unit 7
comprising handwriting input/output system 1 of the invention. This
pen-shaped scanner 31 comprises: light guide 32 that has a hollow
formed thereinside and an opening at the leading end thereof; lens
33 that is disposed at a position near the opening of this light
guide 32; LED 34 (irradiation unit 13) arranged on the same surface
as this lens 33 and functions as the light source that irradiates
light of a predetermined wavelength to a medium surface on which a
dot pattern is formed; C-MOS sensor 35 (imaging element 12)
disposed at a position retracted from lens 33; PCB 36 at a further
retracted position; and, CPU that is mounted on PCB 36 yet is not
shown. The hollow of light guide 32 is formed in a tapered shape
expanding from lens 33 toward the opening. Here, the CPU plays any
or all rolls of dot pattern analysis unit 8, trajectory recognition
unit 9, process instruction unit 10, and information processing
unit 11.
[0264] Light guide 32 is made of transparent resin or opaque white
resin, and inside thereof functions as light guiding path. Light
irradiated from LED 34 proceeds inside light guide 32 onto medium 2
through the opening. If light guide 32 is made of opaque white
resin, as the irradiation light from LED 34 is adequately diffused
while proceeding light guide 32, the light can be more evenly
irradiated onto medium 2 through the opening.
[0265] <Controlling the Timing of Emitting LED Light>
[0266] FIG. 17B is a diagram showing the light emitting timing of
LED 34 through time. LED 34 instantaneously emits light of a
predetermined strength at each predetermined timing to expose
medium 2. C-MOS sensor 35 images reflected light off medium 2 and
transmits the image data to dot pattern analysis unit 8.
[0267] FIG. 17C is a diagram showing the reaction state of the
element of C-MOS sensor 35 through time. Afterimage of medium 2 is
burned on the element of C-MOS sensor 35 at the moment when LED 34
emits light of a predetermined strength and exposes medium 2. Here,
predetermined time t.sub.k is time required for maintaining the
condition of the afterimage that is analyzable by dot pattern
analysis unit 8 within time until the afterimage of imaging element
12 disappears.
[0268] If time .sub.ft during which LED 34 had been emitting light
is shorter than predetermined time a, since the afterimage of dots
is burned on the element of C-MOS sensor 35 without blur as shown
in FIG. 17D, this afterimage is transmitted to dot pattern analysis
unit 8 as image data. In this case, the transmission is performed
within time t.sub.1 during which the afterimage still remains on
the element.
[0269] On the other hand, if time .sub.ft during which LED 34 had
been emitting light greatly exceeds predetermined time a, the
afterimage of dots are blurry burned on the element of C-MOS sensor
35 as shown in FIG. 17E, disabling accurate reading of numerical
values.
[0270] While such an imaging method is particularly effective when
using a C-MOS sensor, CCD camera may be used instead of the
above-described imaging method.
[0271] The functions of light control unit 14 and dot pattern
analysis unit 8 used for handwriting input/output system 1 of the
invention are described with reference to FIGS. 18A to 18C.
[0272] FIG. 18A is a time-series describing the first pattern of
light emitting timing of LED 34 by light control unit 14, timing
for imaging a dot pattern by imaging element 12 and transmitting
the image data to the storage element, and timing for analyzing the
image data by dot pattern analysis unit 8. In the first pattern,
light emission .sub.ft.sub.n, imaging .sub.rt.sub.n, analysis
.sub.at.sub.n are sequentially performed. After analysis
.sub.at.sub.n ends, next light emission .sub.ft.sub.n+1 will not
take place until predetermined time t.sub.s elapses. Here,
predetermined time t.sub.s is defined as the maximum value of
anticipated values of time required for imaging, transmitting,
analyzing a dot pattern by imaging element 12 as anticipated
imaging, transmission, and analysis time.
[0273] FIG. 18B is a time-series describing the second pattern of
light emitting timing of LED 34 by light control unit 14, timing
for imaging and transmitting a dot pattern by imaging element 12,
and timing for analyzing image data by dot pattern analysis unit 8.
In the second pattern, after analysis .sub.at.sub.n ends, light
control unit 14 detects that the end of the analysis and next light
emission .sub.ft.sub.n-1 immediately takes place, then, the next
dot pattern is imaged t r-n+1 and analyzed .sub.at.sub.n+1.
[0274] FIG. 18C is a time-series describing the third pattern of
light emitting timing of LED 34 by light control unit 14, timing
for imaging and transmitting a dot pattern by imaging element 12,
and timing for analyzing image data by dot pattern analysis unit 8.
In the third pattern, having a plurality of task processors or
light control units 14 and dot pattern analysis units 8, imaging
.sub.rt.sub.n of a dot pattern for next analysis takes place at the
same time as analysis .sub.at.sub.n-1, light emission
.sub.ft.sub.+1 takes place as soon as the analysis .sub.at.sub.n-1
ends, then, the image data imaged at imaging .sub.rt.sub.n is
analyzed .sub.at.sub.n. It should be noted that, while analysis
.sub.at.sub.n may start at the same time as light emission
.sub.ft.sub.n-1, as the light emission time of LED 34 is extremely
short, there is not much difference in the total time from the
light emission of LED 34 until dot pattern analysis unit 8 ends
analysis of image data.
[0275] <Attaching a Pen>
[0276] Pen-shaped scanner 31 is attached with pen 37 as writing
material. Usually, when printing with writing material such as a
pen, the writing material is used in an inclined state. For this
reason, the circumference of pen-shaped scanner 31 is formed so
that the scanner can be inclined up to 45 degree. In this way, by
imaging a medium surface near the leading end of pen 37,
brushstroke, moving distance, and the like can be accurately
analyzed when printing with pen 37 apart from the center of the
imaging area. Further, by offset correction, which is described
later, the brushstroke can be analyzed even more accurately.
[0277] Pen 37 as writing material can be used without leaving a
writing trail on a medium by being retracted by a variety of
methods. A technique used for a pen, such as a general ballpoint
pen, can be used as is for the retracting method. For example, a
retraction method by pushing or rotating can be used or a cap can
be used for covering.
[0278] Further, the pens may be switchable as if a general
three-color ballpoint pen. In such a case, in addition to
exchanging pens of different colors, an eraser or correction pen
may be used instead of the pen.
[0279] Further, projection for instruction 23 (a stylus pen) may be
provided instead of pen 37 to image the vicinity of the writing by
projection for instruction 23. A retraction space may be provided
inside projection for instruction 23 to retract pen 37 to use
projection for instruction.
[0280] <Offset Correction>
[0281] As shown in FIG. 17A, in pen-shaped scanner 31, XY
coordinate values defined by a dot pattern imaged by imaging unit 7
and XY coordinate values defined by a dot pattern on a trajectory
actually written by pen 37 are different. Further, the XY
coordinate values defined by the dot pattern on the trajectory
should be converted into xy coordinate values in the writing area
on the medium surface to execute written input or operation
instruction.
[0282] The following describes a method of calibrating XY
coordinate values of a dot pattern imaged by imaging unit 7 into
those of a dot pattern on a trajectory actually written by pen 37,
and a method of converting XY coordinate values in the dot pattern
coordinate system into xy coordinate values in the writing area
coordinate system in handwriting input/output system 1 of the
invention.
[0283] <Relationship Between the Writing Area Coordinate System
and the Dot Pattern Coordinate System>
[0284] FIG. 19 shows an example of the writing area.
[0285] In the writing area coordinate system, lower left corner is
defined as (0, 0). xy coordinate values in the writing area are
expressed by mille meters. For example, coordinate position (16,
40) indicates a position moved from the lower left corner by 16 mm
rightward and 40 mm upward.
[0286] Blocks of dot patterns, each of which defines one set of XY
coordinate values in the dot pattern coordinate system, are
continuously formed in the writing area. The XY coordinate values
indicate the position of the central point of the block. The
coordinate values in the dot pattern coordinate system are
expressed as [X, Y] to be distinguished from the coordinate values
in the writing area.
[0287] If the lower left corner of the writing area is defined as
the origin (0, 0) in the coordinate system, and the lower left
corner of the block of the dot pattern where [0, 0] are defined is
adjusted to the origin (0, 0), the dot patterns are formed such
that XY coordinate values at the lower left corner in the dot
pattern coordinate system become [-0.5, -0.5] in any writing area
as shown in FIG. 20. In such a case, a unique code value is defined
in the dot pattern formed on each writing area to identify each
writing area. The same code values may be used if there is no need
to identify the writing areas from one another.
[0288] Further, as shown in FIG. 22, a dot pattern defining XY
coordinate values is formed on the entire paper surface, and unique
code values are defined in the writing areas in addition to the XY
coordinate values. In such a case, XY coordinate values of the
lower left corner of the writing area become [Xn0, Yn0] (n is a
number identifying the writing area).
[0289] Next, if one side of each block is L mm, the XY coordinate
values are converted into those in the writing area coordinate
system as described below.
[0290] As shown in FIG. 20, if a dot pattern is formed by defining
the XY coordinate values of the origin (0, 0) as [-0.5, -0.5], the
coordinates [X, Y] in the dot pattern coordinate system become
(X.times.L+L/2, Y.times.L+L/2) in the writing area coordinate
system.
[0291] It should be noted that, as shown in FIG. 21, if the lower
left corner of the writing area is defined as the origin (0, 0) in
the coordinate system, and the central point of the block of a dot
pattern that defines [0, 0] is adjusted to the origin, the
coordinate values become (X.times.L, Y.times.L).
[0292] It should be noted that the relationship between the writing
area coordinate system and the dot pattern coordinate system in the
example of FIG. 21 is the same as the example in the enlarged view
portion of FIG. 19.
[0293] As shown in FIG. 22, if the XY coordinate values at the
lower left corner of the writing area are [Xn0, Yn0], coordinates
[X, Y] in the dot pattern coordinate system become
((X-Xn0).times.L, (Y-Yn0).times.L) in the writing area coordinate
system n.
<Calculating XY Coordinate Values [Xc, Yc] of the Center of the
Imaging Area C in a Dot Pattern Coordinate System>
[0294] The method for calculating XY coordinate values [Xc, Yc] of
the center of the imaging area is described with reference to FIG.
23.
[0295] The number of pixels M forming the distance between the
centers of neighboring blocks is calculated by temporarily storing
the captured image in a frame buffer of a predetermined resolution
and analyzing the image. As the distance between the centers equals
to length L of one side of the block, if the size per pixel of the
captured image with reference to L is defined as value k in the dot
pattern coordinate system, k=L/M.
[0296] Similarly, by analyzing the image, the number of pixels u
comprising the distance between the center of the block P [Xp, Yp]
closest to the center of the imaging area C and the center of the
imaging area C is calculated. The distance CP from the center of
the image area C to the center of the block that is closest to the
center of the imaging area becomes CP=k.times.u.
[0297] Next, if the dot pattern is formed on a paper surface so
that the orientation of the dot pattern (the orientation of the
writing area) becomes upward direction of the writing area, the
angle formed by the orientation of the dot pattern and PC vector is
defined as .theta.' (rotation in anticlockwise direction is defined
as the positive direction), [Xc, Yc]=[Xp-CP.times.sin .theta.',
Yp+CP.times.cos .theta.'] is calculated.
[0298] <Calculating xy Coordinate Values Q (xq, yq) at the Pen
Tip in the Writing Area Coordinate System (when the Pen Stands
Perpendicular to the Paper Surface.)>
[0299] As shown in FIG. 24, the coordinate values at the center of
the imaging area C in the writing area coordinate system are
defined as (xc, yc) and the coordinate values at the pen tip on the
medium surface are defined as Q(xq, yq). As shown in FIG. 25, if
differences between x coordinate values and y coordinate values of
point C and point Q are defined as .DELTA.xq and .DELTA.yq
respectively, the following formula can be obtained:
.DELTA.xq=xq-xc
.DELTA.yq=yq-yc
[0300] When a dot pattern is formed so that the orientation of the
dot pattern becomes upward direction of the writing area, the
orientation of CQ vector with the center of the imaging area C as
the starting point and the pen tip as the end point is defined as
the orientation of scanner 31.
[0301] The angle formed by the orientation of the dot pattern and
the orientation of pen-shaped scanner 31 is defined as .theta.
(rotation in anticlockwise direction is defined as the positive
direction).
[0302] Further, as shown in FIG. 26, if the distance from the
center of the imaging area C to the pen tip Q in a state in which
pen-shaped scanner 31 stands perpendicular to the paper surface is
defined as s,
.DELTA.xq and .DELTA.yq become:
.DELTA.xq=-s.times.sin .theta.,
.DELTA.yq=s.times.cos .theta..
[0303] Therefore, xq and yq become:
xq=xc-s.times.sin .theta.,
yq=yc+s.times.cos .theta..
<Calculating xy Coordinate Values Q' (xq', yq') at the Pen Tip
in the Writing Area Coordinate System (when the Pen is Inclined
with Reference to the Paper Surface.)>
[0304] As shown in FIG. 27, if pen-shaped scanner 31 is inclined
with reference to a paper medium, the distance from the center of
imaging area C to the pen tip Q is different.
[0305] If the inclination of pen-shaped scanner 31 from the normal
line direction of the paper surface is defined as .alpha.
(hereafter referred to as "inclination of pen"), and the distance
from the center of the imaging area to the pen tip is defined as
s', s in the above formula can be replaced with s'. The following
formula can be obtained:
xq'=xc-s'.times.sin .theta.
yq'=yc+s'.times.cos .theta.
[0306] Further, s'=s/cos .alpha. and if this is substituted into
the above formula, the following formula can be obtained:
xq'=xc-s'.times.sin .theta./cos .alpha.
yq'=yc+s'.times.cos .theta./cos .alpha.
[0307] <A Distance from the Center of the Imaging Area to the
Pen Tip when Using the Pen with the Pen Tip Retracted in the Main
Body>
[0308] It should be noted that if the pen tip is retracted as shown
in FIG. 28, while pen-shaped scanner 31 gets closer to the paper
surface only by .DELTA.L, s and s' are not affected and the same
formula can be used.
<Calculating Inclination .alpha. of Pen>
[0309] To detect inclination .alpha. of the pen, inclination
measuring means, such as inclination sensor, may be equipped on the
main body.
[0310] Alternatively, inclination .alpha. of the pen can be
calculated from relational expression .alpha.=f(.DELTA.BL) by
calculating brightness BLi, j=1, p at predetermined plurality of p
points of the captured image, and using a difference in brightness
.DELTA.BL between the brightest point and the darkest point.
[0311] .alpha. can be calculated from .alpha.=f(BLi, j=1, p) with a
parameter of BLi, j using Fourier's function and sin function.
[0312] Further, a may be calculated by preparing a table that
relates .DELTA.BL to a in advance. It should be noted that the
inclination direction of the pen can be obtained by measuring the
direction from the darkest point of BLi, j=1, p to the brightest
point thereof.
[0313] <Medium 2>
[0314] FIGS. 29 to 42 are diagrams illustrating medium 2 used for
the handwriting input/output system 1 of the invention.
[0315] FIG. 29 is a diagram showing medium 2 printed (formed) with
a dot pattern over the entire surface thereof to form the writing
area.
[0316] Such a dot pattern defines XY coordinate values and a page
code. Here, the page code means a code that identifies a medium
using the code information.
[0317] FIG. 30 is a diagram showing medium 2 on which, in the area
printed with a dot pattern that defines a page code and XY
coordinate values, another dot pattern that defines further action
code is printed.
[0318] Here, the action code means a code for instructing a
predetermined operation (particularly operation of application) to
information processing unit 11 using the code information in terms
of handwriting input/output to a specified medium. In this way,
security can be enhanced and erroneous operations can be
decreased.
[0319] The medium is a set of a plurality of sheets and a different
page code is allocated to each sheet. The page code is, for
example, "01" for page 1, "02" for page 2, and "03" for page 3.
[0320] On the area printed with a dot pattern that defines an
action code, a text, graphic, photograph, and icon for illustrating
the meaning of such an action code to users can be superimposed and
printed. For example, the action code of the area where a text icon
"START" is superimposed and printed instructs information
processing unit 11 to start up the application for handwriting
input/output. The action code of the area where a text icon
"CANCEL" is superimposed and printed instructs information
processing unit 11 to abandon (cancel) input result by the
application for handwriting input/output or instructs information
processing unit 11 to cancel the execution of a process when
information processing unit 11 is to determine whether or not to
execute the predetermined process. The action code of the area
where a text icon "STORE" is superimposed and printed instructs
information processing unit 11 to store the input result by the
application for handwriting input/output. The action code of the
area where a text icon "END" is superimposed and printed instructs
information processing unit 11 to terminate the application for
handwriting input/output.
[0321] FIG. 31 is a diagram showing medium 2 on which the area
printed with a dot pattern that defines XY coordinate values and a
page code and the area printed with a dot pattern that defines an
action code and a page code are divided. In such a case, a variety
of instructions can be executed only to the page specified by the
page code without selecting the target page of the medium. In this
way, security can be enhanced and erroneous operations can be
decreased.
[0322] FIG. 32 is a diagram showing the first medium printed with a
dot pattern that defines XY coordinate values and a page code and
the second medium that is a paper controller printed with dot
patterns that define only action codes. In such a case, a variety
of instructions of handwriting input/output can be executed on any
page of the medium. It should be noted that, when the writing area
and the icon are provided on a different component, in addition to
a paper controller as shown in FIG. 32, they can be provided on a
sticker, a sticky note, or a card to be attached on a different
medium.
[0323] The action code of the area superimposed and printed with a
text icon "INPUT TEXT" instructs information processing unit 11 to
input a letter, character, or figure of a text in an operation of
the application for handwriting input/output. The action code of
the area superimposed and printed with a text icon "INPUT COMMENT"
instructs information processing unit 11 to input a letter,
character, or figure of a comment in an operation of the
application for handwriting input/output. The action code of the
area superimposed and printed with a text icon "EDIT" instructs
information processing unit 11 to edit a letter, character, or
figure in an operation of the application for handwriting
input/output (that is, it is possible to edit a file, such as a
document and an image, prepared by an application other than the
application for handwriting input/output). The action code of the
area superimposed and printed with a text icon "ENTER" instructs
information processing unit 11 to determine the execution of a
process when information processing unit 11 is to determine whether
or not to execute the predetermined process.
[0324] FIG. 33 is a diagram showing a booklet that includes the
first medium printed with a dot pattern that defines XY coordinate
values and page code A and the second medium that is a paper
controller printed with a dot pattern that defines an action code
and page code A.
[0325] In such a case, a dot pattern registering the same XY
coordinates may be printed on the writing area of each page. This
is because when performing writing operation, the writing area can
be identified by using an icon of the controller area that
registers an action code and a page code. In other words, the
position of the writing area and the page can be changed without
changing XY coordinate values. In such a case, a variety of
instructions can be executed only to the page specified by the page
code without selecting the target page of the medium. In this way,
security is enhanced and erroneous operations can be decreased.
[0326] Alternatively, a dot pattern that defines an action code for
instructing the information processing unit to start up the
application for handwriting input/output may be printed over the
entire writing area. In such a case, if writing is performed on a
medium surface, the application for handwriting input/output
automatically starts up.
[0327] Further, the writing area on the medium is not limited to
one, and a plurality of writing areas can be defined. (When a
plurality of writing areas are provided)
[0328] The following describes four examples of the case in which a
plurality of writing areas are provided with reference to FIGS. 34
to 38.
First Example
[0329] As shown in FIG. 34, the first example is a case in which a
dot pattern that defines: XY coordinate values in a dot pattern
coordinate system different from those of other writing areas; and,
a code value that specifies the writing area, is formed on each of
the plurality of writing areas
[0330] In FIG. 34, a dot pattern that respectively defines XY
coordinate values in the dot pattern coordinate system and code
values m, n that specify the writing area is formed on each writing
area.
[0331] By defining a plurality pieces of information in the code
value, the code value can include, for example, a category number
that categorizes a page number as well as the writing area.
[0332] If a page number is included, which writing area of which
page can be determined. When there are selections of information,
process instructions, choices, and the like that are to be
processed as a common code, a defined page number or information
that specifies the selection can be defined as a code value.
[0333] As shown in FIG. 35, the writing area can be divided to
define a different code value. In FIG. 35, code values are n1, n2,
n3, and n4. In this way, a plurality of selections can be set in
one writing area.
[0334] This first example has a benefit that the lower left corner
of each area always becomes 0 (the origin), making it easily to
handle.
Second Example
[0335] In the second example, as shown in FIG. 36, a dot pattern
that defines XY coordinate values in a single dot pattern
coordinate system is formed over the entire predetermined area, and
the dot pattern of the writing area defines a code value as well as
XY coordinates.
[0336] In FIG. 36, a dot pattern that defines XY coordinate values
in a single dot pattern coordinate system with the lower left
corner of a predetermined area as the origin is formed over the
entire predetermined area. The two writing areas in this
predetermined area define XY coordinate values of lower left
corners, [Xm0, Ym0], [Xn0, Yn0], and code values m, n that specify
the writing areas respectively.
[0337] As for the code value, similarly to the first example, the
writing area can be divided to define a different code value.
[0338] It should be noted that the area formed with a dot pattern
other than the writing areas cannot be written in.
[0339] According to the second example, where the writing area is
laid out within the predetermined area can be easily understood by
reading XY coordinate values.
Third Example
[0340] In the third example, as shown in FIG. 37, a writing area is
further embedded in another writing area.
[0341] In FIG. 37, a dot pattern that defines XY coordinate values
in a single dot pattern coordinate system with the lower left
corner of a predetermined area as the origin and code value L that
specifies the writing area is formed over the entire predetermined
area. In the two writing areas in this predetermined writing area,
XY coordinate values of the lower left corners [Xm0, Ym0], [Xn0,
Yn0] and code values m, n that specify the writing areas are
defined respectively.
[0342] According to this example, small writing areas, such as
selection fields, can be easily located within a large writing area
for freely writing texts and figures.
[0343] If this is to be realized by the first example, when forming
a writing area inside another writing area, the writing area should
be provided with a vacant portion, which complicates the task of
forming the dot pattern.
[0344] Further, if a writing area can be formed within another
writing area in a single coordinate system, writing can be
performed irrespective of the writing area within another writing
area by changing input modes. For example, a setting may be
provided in which writing in a writing area within another writing
area becomes valid only when the input modes were switched or a
specific symbol was drawn.
[0345] As for the code value, likely to the first example, the
writing area can be divided to define a different code value.
[0346] In this example, where the writing area is laid out can be
easily understood by reading XY coordinate values.
Fourth Example
[0347] In the fourth example, as shown in FIG. 38, a single dot
pattern coordinate system is defined over the entire predetermined
area, and the writing area is formed with a dot pattern that
defines XY coordinate values in this coordinate system and a code
value that specifies the writing area.
[0348] In FIG. 38, a single coordinate system with the lower left
corner as the origin is defined in a predetermined area. In the two
writing areas in this predetermined area, XY coordinate values of
the lower left corners [Xm0, Ym0], [Xn0, Yn0] and code values m, n
that specify the writing areas are defined respectively.
[0349] In this example, unlike the second example, no dot pattern
is formed in an area other than the writing area.
[0350] In this example, if there are a mechanical of a print
material, such as a graphic and a text, and a mechanical of a dot
pattern, it is possible to prepare the mechanical of the dot
pattern by mask processing that automatically lays out the writing
area adjusted to the coordinate system of the mechanical of the
print material by disposing a mask, enabling easy issuance of a dot
pattern.
[0351] Further, as XY coordinate values are read out when reading a
dot pattern, where the writing area is laid out in a predetermined
area is understood, which can be used, for example, for a research
of studying an advertisement effect depending on the location on a
paper surface.
[0352] It will be appreciated that, while the above descriptions
are all described using the dot pattern coordinate system, the same
goes for the writing area coordinate system converted from the dot
pattern coordinate system.
[0353] FIGS. 39A and 39B are diagrams showing a document, which is
a specific example where a plurality of writing areas are defined
on a medium.
[0354] FIG. 39A is a diagram showing such a document on which the
XY coordinate values of the origin and a specific code that
instructs specifying of a writing area are defined.
[0355] In FIG. 39A, "KATAKANA" writing area is defined within
"NAME" writing area, "POST CODE" writing area within "ADDRESS"
writing area, "WALK MINUTE(S)," "TRAIN MINUTE(S)," "BUS MINUTE(S)"
writing areas within "MAP TO HOME" writing area.
[0356] Further, "SEX" writing area is divided into "MALE" and
"FEMALE" writing areas, "DATE OF BIRTH" writing area is divided
into "YEAR," "MONTH," and "DAY."
[0357] Such layouts of the writing areas are made possible by
allocating a different specific code to each area.
[0358] FIG. 39B is a diagram showing that, in such a document, XY
coordinate values of the origin are not defined in each writing
area and only a specific code that instructs specifying of the
writing area is defined.
[0359] Having such a configuration, the position of written
information can be located in the entire medium surface.
[0360] FIGS. 40A and 40B are diagrams showing the states of the
documents of FIGS. 39A and 39B after actual handwritten input.
[0361] FIG. 40A is a diagram showing the document of FIG. 39A after
actual handwritten input.
[0362] FIG. 40B is a diagram showing a state in which, after
receiving handwritten input of FIG. 39A, the result of processing
performed by information processing unit 11 is displayed on display
6 or output by printing.
[0363] While the details are described later, handwriting
input/output system 1 of the invention performs output as shown in
FIG. 40B by recognizing the letters, characters, and figures
handwritten input by some methods.
[0364] <Printing a New Dot Pattern>
[0365] In handwriting input/output system 1 of the invention,
additional handwriting input can be performed on a print material
that is reflected handwritten input by information processing unit
11.
[0366] FIG. 41A is a diagram showing medium 2 on which trajectory
information recognized by trajectory recognition unit 9 and a dot
pattern are superimposed and printed. While not shown in the
drawings, medium 2 shown in FIG. 41A may be newly printed with a
dot pattern different from the dot pattern printed on medium 2 on
which handwriting input is first performed.
[0367] FIG. 41B is a diagram showing medium 2 on which the result
of processing performed by information processing unit 11 is
printed by superimposing and printing a dot pattern thereon. While
not shown in the drawings, medium 2 shown in FIG. 41B may be newly
printed with a dot pattern different from the dot pattern printed
on medium 2 on which handwriting input is first performed.
[0368] <Braille, Bank>
[0369] Also, medium 2 may be further provided with guide bank 38
(narrow convex portion) or Braille 39.
[0370] FIG. 42 shows a writing area with guide bank 38 provided on
the periphery, and the projections of Braille 39 are provided
together with a dot pattern on the writing area. Having guide bank
38 in this way, even when a visually impaired user uses the
handwriting input/output, the user can understand the position of
the writing area. Having Braille 39 and the dot pattern in the same
area, even when a visually impaired user uses the handwriting
input/output, input efficiency close to equivalent to physically
unimpaired people can be maintained.
[0371] <Dot Pattern Analysis Unit>
[0372] Dot pattern analysis unit 8 calculates XY coordinate
information and code information defined by a dot pattern by
analyzing the code of the image data according to the information
input/output method using a dot pattern used in the above-described
GRID1.
[0373] In handwriting input/output system 1 of the invention, as
the code of the trajectory written (traced) by a user on the medium
with imaging unit 7 is sequentially analyzed by dot pattern
analysis unit 8, the XY coordinate information and code information
express this trajectory (trajectory information).
[0374] <Trajectory Recognition Unit>
[0375] Trajectory recognition unit 9 recognizes a letter,
character, and figure written on the medium based on the change in
trajectory information.
[0376] The method of recognizing the trajectory is a method of
handling a letter, character, and figure as a graphic and referring
to the XY coordinate patterns of the letter, character, and figure
in database, just as in general OCR (Optical Character Reader).
[0377] Here, particularly in this invention, the content to be
written in the writing area can be specified in advance using code
information. That is, by referring to a letter, character, and/or
figure information pattern table that is categorized in advance,
the trajectory information can be recognized with high accuracy.
Specifically, if only Arabic numerals are designated to be written
in advance, trajectory recognition unit 9 refers only to the table
of Arabic numerals whereby the recognition rate improves. If no
Arabic numeral is recognized, all letters, characters, and figures
in database may be referred to as usual.
[0378] Further, after performing the above-described trajectory
recognition, the semantic information of the letter, character,
and/or figure written in the writing area or a word formed by one
or plurality of letters and characters can be converted into a
semantic information code by referring to a predefined semantic
information code table (a dictionary). That is, if "Tokyoto
Bunkyoku" in kanji is written in, trajectory recognition unit 9
recognizes the pattern of each kanji letter "To" "Kyo" "To" "Bun"
"Kyo" "Ku," then refers to a semantic information code table (a
dictionary) and converts into a semantic information code defined
as corresponding to "Tokyoto" and a semantic information code
defined as corresponding to "Bunkyoku." In this way, the
information processing unit can recognize that the name of places
"Tokyoto," "Bunkyoku" were input.
[0379] In addition, referring to the semantic information code
table (a dictionary) also assists pattern recognition of letters
and characters. For example, when the letter "To" of "Tokyo" in
kanji is poorly written by a user and hard to be recognized by
trajectory recognition unit 9 as to whether "To" or "Sha" in kanji
is written, if the word "Tokyo" is defined in the semantic
information code table and the word "Shakyo" is not defined (the
word "Shakyo" normally does not exist), trajectory recognition unit
9 can recognize that the user wrote the letter "To."
[0380] <Timer>
[0381] Handwriting input/output system 1 of the invention may
further comprise timer 15. Timer 15 has a function to detect time
information.
[0382] Here, time information is under the following
conditions:
[0383] (i) in the order of the writing history touched and drawn by
imaging unit 7 on the writing area
[0384] (ii) a collection of time from when imaging unit 7 touches
on the writing area until separates from writing area 7, ignoring
time during which imaging unit 7 is apart from the writing area
after starting writing. That is, except for time during which
imaging unit 7 is apart from the writing area, time for handwriting
input/output and the order is described based on the time when (1)
starts and ends. In this way, time when a letter or character is
written can be understood, accuracy of character recognition is
improved, and the character input speed of the subject person can
be understood.
[0385] (ii) By recording all times when imaging unit 7 touches on
and separates from the writing area, it is understood that how long
it was taken to answer a questionnaire or select a product. Then,
by comparing with the ordinary case, difficulty of a question and
the way of thinking, the character, age, and sex of the writer can
be understood.
[0386] (iv) Also, by understanding the moving speed of the pen,
brushstroke of a letter or character or difficulty of writing the
letter or character can be analyzed, and, further, mental state and
physical state of the writer can be anticipated.
[0387] <Angle Measuring Unit, Angle Change Recognition
Unit>
[0388] Handwriting input/output system 1 of the invention may
further comprise angle measuring unit 16 and angle change
recognition unit 17. Angle measuring unit 16 and angle change
recognition unit 17 measure and recognize the inclination of
imaging unit 7 with reference to the medium surface.
[0389] As for the method of measuring angle and recognizing a
change in angle, the above-described calculation method of
inclination .alpha. of the pen can be used as is. In such a case,
even if imaging unit 7 does not comprise the pen, the inclination
can be measured and recognized. Also, as shown in FIGS. 43 to 47,
the inclination calculation method disclosed in the invention of an
information output device according to Japanese Patent Application
No. 2005-267565 (PCT/SG2006/000267) can be used. However, other
methods than these may also be used.
[0390] It should be noted, in recognizing a change in angle with
reference to the medium surface by imaging unit 7, the criteria of
measuring and recognizing an inclination can be an angle when
imaging unit 7 touches on the medium surface as well as an angle
when imaging unit 7 stands perpendicular to the medium surface.
[0391] <Rotation Angle Reading Unit; Rotation Angle Change
Recognition Unit>
[0392] Handwriting input/output system 1 of the invention may
further comprise rotation angle reading unit 18 and rotation angle
change recognition unit 19. Rotation angle reading unit 18 and
rotation angle change recognition unit 19 read out and recognize
the rotation angle when the imaging light axis of imaging unit 7
stands generally perpendicular and is rotated.
[0393] While the method for calculating an angle formed by the
orientation of a dot pattern and the orientation of imaging unit 7
was described in the section describing the offset correction, this
method can be used as a method for reading and recognizing the
rotation angle regardless of the existence of the pen. That is, as
the dot pattern is always oriented a certain direction, a
difference between angle .theta..sub.1 formed by the orientation of
the dot pattern and the orientation of imaging unit 7 when standing
imaging unit 7 perpendicular to the medium surface and imaging for
the first time and angle .theta..sub.2 formed by the orientation of
the dot pattern and the orientation of imaging unit 7 after
predetermined time has elapsed (anticlockwise rotation is defined
as the positive direction) can be read out and recognized as the
rotation angle.
[0394] <Method for Identifying Touching Motion and Flicking
Motion>
[0395] FIGS. 48A to 48D describe a method for determining a motion
of touching on the writing area by imaging unit 7 (touching motion)
and a motion of flicking imaging unit 7 off the writing area from
the state in which imaging unit 7 touches on the writing area
(flicking motion) in handwriting input/output system 1 of the
invention.
[0396] As shown in FIG. 48A, when imaging unit 7 touches on the
writing area, the dot pattern of the writing area can be imaged at
the moment when imaging unit 7 touches on the writing area. Then,
if imaging unit 7 separates from the writing area, as irradiation
light from LED 34 will not reflect on the medium surface any more,
C-MOS sensor 35 does not detect the irradiation light from LED 34
(reflection from the medium surface) and, as the result, the dot
pattern cannot be imaged as shown in FIG. 48C.
[0397] As shown in FIG. 48B, when imaging unit 7 is flicked off the
writing area from the state in which imaging unit 7 touches
thereon, the dot pattern of the writing area can be imaged at the
moment imaging unit 7 touches on the writing area, until which the
same goes with the touching motion on the writing area. Then, if
imaging unit 7 is flicked off the writing area from the state in
which imaging unit 7 touches on the writing area, as the leading
edge of imaging unit 7 is still oriented toward the writing area
for a predetermined time period, the irradiation light from LED 34
reflects on the medium surface. While C-MOS sensor 35 images the
dot pattern of the medium surface, as the moving speed of imaging
unit 7 is fast, the dot pattern is blurry imaged as shown in FIG.
49D and cannot be analyzed.
[0398] That is, imaging unit 7 analyzes image data imaged after a
predetermined time period has elapsed (e.g., in 0.2 seconds) with
reference to the moment when imaging unit 7 imaged the dot pattern
by touching the writing area and analyzed the image data. If
imaging unit 7 does not image a dot pattern (does not detect the
reflection light), process instruction unit 10 regards imaging unit
7 as performing the touching motion and transmits information
processing unit 11 a process instruction that had been defined in
advance as corresponding to the touch motion. If imaging unit 7
images the dot pattern (detects the reflection light), yet the dot
pattern is blurred and cannot be analyzed, process instruction unit
10 regards imaging unit 7 as performing the flicking motion and
transmits information processing unit 11 a process instruction that
had been defined in advance as corresponding to the flicking
motion. If the dot pattern can be analyzed, as shown in FIG. 49E,
normal handwriting input operation will be performed.
[0399] <Process Instruction Unit>
[0400] Process instruction unit 10 transmits a process instruction
as well as trajectory information based on information recognized
by trajectory recognition unit 9 to information processing unit
11.
[0401] An instruction to specify a page based on the page code, an
instruction to specify a certain writing area based on the specific
code, and a variety of instructions based on the action codes,
which are defined by the dot pattern printed on the medium surface
as described above, are actually instructed by process instruction
unit 10 to information processing unit 11.
[0402] Also, while the details are described later, process
instruction unit 10, instructs information processing unit 11 to
execute a variety of operations of the application for handwriting
input/output.
[0403] Further, process instruction unit 10 instructs information
processing unit 11 to execute predetermined processes based on the
measured and recognized results by angle measuring unit 16 and
angle change recognition unit 17 and the read and recognized
results by rotation angle reading unit 17 and rotation angle change
recognition unit 19.
[0404] <Information Processing Unit>
[0405] Information processing unit 11 executes a variety of
processes according to the process instructions performed by
handwriting input/output system 1 of the invention.
[0406] <Server>
[0407] Handwriting input/output system 1 of the invention may
access server 5 that stores a variety of information if needed.
[0408] <Trajectory Recognition Server>
[0409] Server 5 can store, for example, information for trajectory
recognition. As is employed by a general OCR (Optical Character
Reader), a plurality of letters, characters, and figures are
defined by being related with XY coordinate patterns and
stored.
[0410] Also, the letters, characters, and figures are defined by
being related with category codes for categorizing them and
stored.
[0411] Further, by referring to a semantic information code table
(a dictionary), letters, characters, and figures are defined and
stored by being related with semantic information codes for
outputting a word comprising one or a plurality of letters and
characters, a figure, or a combination thereof
[0412] Handwriting input/output system 1 of the invention can
easily manage even enormous amount (number) of writing areas as the
writing areas can be specified using code information as well as XY
coordinate information. Particularly, it is significantly
advantageous when storing written information in a shared global
server that can be used by anonymous people.
[0413] <Other Servers>
[0414] It goes without saying that server 5 can store a variety of
information including a sound, text, image, moving picture,
application and other information, in addition to information for
trajectory recognition. For example, server 5 can store the
application for handwriting input/output. That is, if information
processing unit 11 does not have the application for handwriting
input/output, the application for handwriting input/output can be
searched in the server and executed, provided, however, the
application for handwriting input/output on the server may be
executed in priority.
[0415] It should be noted that the application for handwriting
input/output in another information processing unit 11 may be
executed instead of the one on server 5.
[0416] It will be appreciated that, in addition to the above
embodiment, server 5 can be implemented in many ways by modifying
the embodiment.
[0417] <Application for Handwriting Input/Output>
[0418] The following describes the application for handwriting
input/output to be run in handwriting input/output system 1 of the
invention.
[0419] This application is a system that reflects writing on the
medium surface to the computer by executing a variety of
operations.
[0420] Writing on the medium surface may be performed by
instructions of process instruction unit 10 to information
processing unit 11 on a real time basis while watching display 6
that displays the process result, or performed without watching
display 6 and process instruction unit 10 may instruct information
processing unit 11 after the writing.
[0421] <Writing Operation>
[0422] The following describes the writing operation in handwriting
input/output system 1 of the invention.
[0423] The writing operation is performed by writing a letter,
character, or figure to be input in the writing area on the medium
surface using imaging unit 7.
[0424] Imaging unit 7 images a dot pattern superimposed and printed
on the writing area at a predetermined time interval while imaging
unit 7 is moving on the medium surface. The subsequent procedure is
as described above.
[0425] The following describes each operation executed by
handwriting input/output system 1.
[0426] <Method of Recognizing a Letter, Character, and
Figure>
[0427] FIGS. 49A to 49E are conceptual views illustrating the first
operation of inputting a letter of a text by handwriting.
[0428] As shown in FIG. 49A, if a letter is written in the writing
area using imaging unit 7, imaging unit 7 sequentially images the
dot patterns on the trajectory and dot pattern analysis unit 8
obtains trajectory information comprising XY coordinate information
and code information as shown in FIG. 49B.
[0429] It should be noted that, while FIG. 49B shows spacing
between the imaging positions of dot patterns on the trajectory
being wide for convenience of explanation, the spacing is actually
smaller.
[0430] As shown in FIG. 49C, information processing unit 11
executes the first operation based on the result of recognition on
the basis of the trajectory information, and outputs the result on
display 6.
[0431] When recognizing a figure as shown in FIG. 49D, the
recognition method is the same as the one for recognizing a letter
or character. The recognition result is displayed on display 6 as
shown in FIG. 49E.
[0432] Alternatively, XY coordinate information calculated by dot
pattern analysis unit 8 may be input/output as is without
recognizing a letter, character, or figure. In this case,
handwriting input/output system 1 of the invention functions as a
pen tablet.
[0433] <Second Operation>
[0434] As shown in FIG. 50, the second operation is an operation of
inputting letters and characters of a comment by handwriting. It
should be noted that, while the comment portions are enclosed by
dashed lines for convenience of explanation in FIG. 50, the dashed
lines do not have to be actually drawn.
[0435] The method for recognizing a letter, character, and figure
is the same as the one of the first operation.
[0436] Information processing unit 11 recognizes the letters and
characters of the comment input by the second operation as a
comment different from the text.
[0437] With regard to the comment, a description between lines may
be reflected by information processing unit 11 as is as shown in
FIG. 51, or alternatively, a part of a text where a comment is
desired to be inserted may be specified by an underline and the
comment may be listed beside the text by information processing
unit 11 as shown in FIG. 52.
[0438] <Third Operation>
[0439] The third operation is an operation for editing a
handwritten input letter or character.
[0440] Each editing is performed by writing a letter, character, or
figure, which is defined in advance as an edit mark by information
processing unit 11, using imaging unit 7.
[0441] A method for recognizing a letter, character, or figure is
the same as the one for the first operation.
[0442] FIG. 53 is a diagram illustrating the edit mark used in the
editing operation as the third operation of the invention.
[0443] A line forming one enclosed area means an edit mark that
selects a letter, character, or figure within the area.
[0444] Two pairs of lines that do not enclose area means an edit
mark that selects a letter, character, or figure between the two
pairs of lines.
[0445] A tick mark means an edit mark that specifies the target of
cutting when cutting and pasting.
[0446] Double lines mean an edit mark of deleting (erasing).
[0447] "Delete" means an edit mark of deleting (erasing).
[0448] "Stet" means cancellation of "Delete" edit mark.
[0449] Zigzag line with more than three up and down patterns means
an edit mark of cancelling.
[0450] Double headed arrow means an edit mark of switching the
selected letters, characters, or figures.
[0451] Single headed arrow means an edit mark of directly
specifying the pasting destination.
[0452] Characters (A), (B), (C) means an edit mark that copies
(cuts) the selected letter, character, or figure with flag and
specifies the pasting position apart from the original
position.
[0453] However, it will be appreciated that edit marks other than
above may also be defined.
[0454] FIG. 54 is a diagram showing medium 2 before executing the
third operation.
[0455] Medium 2 is described a text handwritten input by executing
the first operation or a text printed as the result of the
handwriting input.
[0456] FIG. 55 is a diagram illustrating an editing state on medium
2 by the third operation.
[0457] If a line enclosing the area is drawn as (a) in FIG. 55, the
application for handwriting input/output recognizes the area
enclosed by the line as one editing subject.
[0458] If a line that does not enclose area and is of a
parenthesis-like shape is drawn as (b) in FIG. 55, and if a
corresponding line of an ending parenthesis-like shape is drawn in
the following area as (c) in FIG. 55, the application for
handwriting input/output recognizes the in-between area as one
editing subject. Particularly, these lines are used when the
editing subject is more than one line.
[0459] If, after selecting an editing subject, "Delete" is drawn as
(d) in FIG. 55 on the line indicating the editing subject, the
application for handwriting input/output deletes the letters or
characters of the editing subject.
[0460] If, after selecting an editing subject, an arrow that
specifies from the editing subject to a predetermined position is
drawn as (e) in FIG. 55, the application for handwriting
input/output cuts and pastes or copies and pastes the editing
subject to the specified area. Here, pasting can be not only
inserted in-between letters and characters (or line head or line
end), but also performed by specifying the pasting destination as
an editing subject as (f) in FIG. 55 to delete and overwrite the
original letters and characters.
[0461] In this case, if the edit mark of tick for deleting is
additionally drawn on the line indicating the editing subject to be
copied as (g) in FIG. 55, the application for handwriting
input/output processes as cutting and pasting the editing subject,
as the result, the subject is deleted as being cut. If the tick is
not additionally drawn as (h) in FIG. 55, the application for
handwriting input/output processes as copying and pasting.
[0462] If edit marks, such as (A), (B), as flags are additionally
drawn on an editing subject as (i) in FIG. 55, the editing subject
is copied with flag (A), (B), and can be arbitrary pasted any
number of times thereafter. Further, the editing subject can be
pasted to a separate position such as somewhere in a different page
as (j) in FIG. 55.
[0463] If double lines are drawn over letters and characters as (k)
in FIG. 55, the application for handwriting input/output deletes
the letters and characters struck out by the double lines.
[0464] If two editing subjects are connected by the edit mark of
double-headed arrow as (l) in FIG. 55, the application for
handwriting input/output swaps the editing subjects.
[0465] FIG. 56 is a diagram showing a text to which is reflected,
by the application for handwriting input/output, the result of
editing by the third operation on medium 2.
[0466] FIG. 57 is a diagram illustrating an operation that, after
performing the editing by the third operation as shown in FIG. 60,
cancels the editing and restores to the state before the
editing.
[0467] If a zigzag line that is the edit mark of cancellation is
added to the area where the edit mark of tick is once added and
deleted as (a) in FIG. 57, the application for handwriting
input/output cancels the deletion of the once deleted area and the
area is restored.
[0468] If, after once copying and pasting by adding the edit mark
of (A) mark, a zigzag line is added to the edit mark of arrow that
specifies a pasting destination as (b) in FIG. 57, the application
for handwriting input/output restores the state before inserting
letters and characters by copying and pasting.
[0469] FIG. 58 is a diagram showing a text to which is reflected,
by the application for handwriting input/output, the result of the
cancellation of editing by the third operation on medium 2.
[0470] <Hierarchical Relationship Among Operations>
[0471] The following describes the hierarchical relationship among
operations.
[0472] The third operation may be an operation performed in
parallel with the first and second operations.
[0473] In such a case, the third operation simultaneously edits the
letters and characters of a text and the letters and characters of
a comment.
[0474] On the other hand, the third operation may be a sub
operation that depends on the first and second operations
respectively.
[0475] In such a case, only the letters and characters of the text
is edited when performing the third operation as a sub operation
that depends on the first operation, and only the letters and
characters of the comment is edited when performing the third
operation as a sub operation that depends on the second
operation.
[0476] It will be appreciated that handwriting input/output system
1 of the invention can be modified and implemented to execute a
variety of operations if necessary, in addition to the
above-described first to third operations.
[0477] <Storing to a Computer>
[0478] As shown in FIG. 59, by rotating imaging unit 7 in a
clockwise direction by a predetermined rotation angle (e.g., 10
degree or more) while touching on the medium surface, process
instruction unit 10 instructs information processing unit 11 to
store the result of input letters and characters and text
composition (the result of changed file content). If imaging unit 7
itself has a function capable of recording an editing history,
imaging unit 7 transmits the result of the above text composition
to information processing unit 11.
[0479] As shown in FIG. 60, by rotating imaging unit 7 in an
anticlockwise direction by a predetermined rotation angle (e.g., 10
degree or more) while touching on the medium surface, process
instruction unit 10 instructs information processing unit 11 to
abandon the result of input letters and characters and text
composition (the result of changed file content).
[0480] To recognize rotation of imaging unit 7, the above-described
method of reading rotation angle and recognizing a change in
rotation angle are used.
[0481] <Starting Up and Terminating an Application>
[0482] As shown in FIG. 61, by rotating imaging unit 7 in a
clockwise direction by a predetermined rotation angle (e.g., 10
degree or more) while touching on the medium surface, then rotating
imaging unit 7 in an anticlockwise direction by a predetermined
rotation angle (e.g., 10 degree or more) within predetermined time
(e.g., one second or less), process instruction unit 10 instructs
information processing unit 11 to start up the application for
handwriting input/output.
[0483] As shown in FIG. 62, by rotating imaging unit 7 in an
anticlockwise direction by a predetermined rotation angle (e.g., 10
degree or more) while touching on the medium surface, then rotating
imaging unit 7 in a clockwise direction by a predetermined rotation
angle (e.g., 10 degree or more) within predetermined time (e.g.,
one second or less), process instruction unit 10 instructs
information processing unit 11 to terminate the application for
handwriting input/output.
[0484] <Operation Switching Motion: Method 1>
[0485] The following describes the first method of switching
operations with reference to FIGS. 63A to 63D.
[0486] This method uses the above-described method of measuring
angle and recognizing a change in angle.
[0487] As shown in FIG. 63A, by standing imaging unit 7 on the
medium surface and inclining on the left side of the medium surface
only by a predetermined angle (e.g., 15 degree or more) with
reference to the angle formed by medium surface and imaging unit 7,
process instruction unit 10 instructs information processing unit
11 to start the first operation of inputting a text by
handwriting.
[0488] As shown in FIG. 63B, by standing imaging unit 7 on the
medium surface and inclining it on the right side of the medium
surface only by a predetermined angle (e.g., 15 degree or more)
with reference to the angle formed by medium surface and imaging
unit 7, process instruction unit 10 instructs information
processing unit 11 to start the second operation of inputting a
comment by handwriting.
[0489] As shown in FIG. 63C, by standing imaging unit 7 on the
medium surface and inclining it on the upper side of the medium
surface only by a predetermined angle (e.g., 15 degree or more)
with reference to the angle formed by medium surface and imaging
unit 7, process instruction unit 10 instructs information
processing unit 11 to start the third operation of editing a text
and a comment.
[0490] As shown in FIG. 63D, by standing imaging unit 7 on the
medium surface and inclining it on the lower side of the medium
surface only by a predetermined angle (e.g., 15 degree or more)
with reference to the angle formed by medium surface and imaging
unit 7, process instruction unit 10 instructs information
processing unit 11 to terminate the running operation and start the
predetermined normal operation (running at the time of staring
up).
[0491] FIG. 64 is a plan view that is viewed from immediately
above, complementing the description of the first method of
switching operations.
[0492] <Operation Switching Motion: Method 2>
[0493] The following describes the second method of switching
operations.
[0494] Switching of operations may be performed by input means,
such as a button, equipped on the main body of imaging unit 7.
[0495] In addition to imaging unit 7, switching of operations may
be performed via external input means, such as a mouse and a
keyboard.
[0496] <Operation Switching Motion: Method 3>
[0497] The following describes the third method of switching
operations.
[0498] Imaging unit 7 of an embodiment capable of storing a
plurality of pen tips thereinside and switching them may switch
operations in conjunction with switching motion of the pen
tips.
[0499] In such a case, as each operation can be colored, each
operation can be easily distinguished on the medium.
[0500] Further, when equipping an eraser or a correction pen
instead of the pen tip, information processing unit 11 may
correspondingly erase a letter, character, or figure instead of
writing.
[0501] <Determination, Cancellation>
[0502] When information processing unit 11 is to determine whether
or not to execute a predetermined process, if imaging unit 7 stands
perpendicular to the medium surface, touches on the medium surface
once, then, touches again the medium surface within predetermined
time (e.g., one second or less) as shown in FIG. 65A, process
instruction unit 10 instructs information processing unit 11 to
determine execution of a process.
[0503] If imaging unit 7 stands perpendicular to the medium
surface, touches on the medium surface once, then, does not touch
again the medium surface within predetermined time (e.g., within
one second) as shown in FIG. 65B, process instruction unit 10
instructs information processing unit 11 to determine cancellation
of execution of a process.
[0504] <Other Usages>
[0505] While the above configurations are devised based on the
assumption that the writing history remains in medium 2,
handwriting input/output system 1 of the invention may be
configured without leaving a writing history in medium 2 and
handwriting input may be performed while watching display 6.
[0506] <Sound Recognition>
[0507] While the present invention is a handwriting input/output
system, sound recognition and voice guidance functions may be added
to assist handwriting input.
[0508] <Sound Recording Unit>
[0509] Sound recording unit 20 is configured centering on a micro
processing unit (MPU) 40 as shown in FIG. 66. Under the control of
the micro processing unit (MPU) 40, sound information input from
microphone 41 is processed by A/D converter 43 and compression
circuit 44 through amplifier 42, then, stored as digital sound
information.
[0510] <Sound Recognition Unit>
[0511] Sound recognition unit 21 converts recorded sound
information to corresponding text information, and process
instruction unit 10 transmits information processing unit 11 a
process instruction based on the text information together with the
text information.
[0512] In such a case, by imaging a dot pattern that defines a
category code prior to the sound recognition, accuracy of the sound
recognition can be enhanced. That is, when searching the database
and outputting text information, text information in the sound
recognition information table corresponding to the category code is
referred to without referring to all text information, thereby
enhancing the accuracy of sound recognition.
[0513] For example, if "Ueno" is pronounced, it is difficult to
determine whether that means the name of a place or the name of a
person. However, if "Ueno" is pronounced and input as sound
information after a category code signifying "Address" was imaged,
sound information of "Ueno" as well as the category code signifying
inputting of an address is transmitted to information processing
unit 11.
[0514] <Switching to Sound Recording Mode>
[0515] If handwriting input/output system 1 of the invention
records sound instead of handwritten input, switching to the sound
recording mode is required by performing a predetermined operation.
The following describes the method of switching to the sound
recording mode.
[0516] <Tracing a Specific Symbol>
[0517] As the first method of switching to the sound recording
mode, there is a method of switching to the sound recording mode by
writing (tracing, drawing) a specific symbol that signifies
switching of imaging unit 7 to the sound recording mode. Sound
recording unit 20 starts recording sound when trajectory
recognition unit 9 recognizes the trajectory of the specific symbol
signifying switching of imaging unit 7 to the sound recording mode,
and transmits to sound recording unit 20 (or transmitting through
process instruction unit 10).
[0518] <Flicking the Pen>
[0519] As the second method of switching to the sound recording
mode, as shown in FIG. 67, there is a method of switching to the
sound recording mode by a flick motion of imaging unit 7 from the
state it touches on the writing area of the medium surface.
[0520] <Switching by Sound Recognition>
[0521] As the third method of switching to the sound recording
mode, there is a method of switching to the sound recording mode by
recording a predetermined sound by sound recording unit 20 and
recognizing the predetermined sound by sound recognition unit
21.
[0522] When operation is performed by the above methods, process
instruction unit 10 instructs information processing unit 11 to
input sound instead of handwritten input in the application for
handwriting input/output.
[0523] <Sound Output Unit>
[0524] Sound output unit 22 reproduces a predetermined audio file
according to an instruction from process instruction unit 10. The
audio file that is digitized and stored in advance is output from
speaker 45 or earphone 46 through A/D converter 42 and amplifier
42.
[0525] <Voice Guidance>
[0526] Handwriting input/output system 1 of the invention may
provide voice guidance to a user inputting by handwriting using
code information.
[0527] That is, as the dot pattern printed on the writing area is
defined with a voice guidance code that instructs information
processing unit 11 to reproduce sound, if handwriting input is
started (imaging unit 7 images a dot pattern), the audio file
related in advance to the voice guidance code is played by sound
output unit 22.
[0528] However, the voice guidance code and the corresponding audio
file may also be used for other purposes than voice guidance.
[0529] <Grid Sheet>
[0530] FIGS. 68 to 72F are explanatory views showing embodiments of
using a grid sheet as an information input assistance sheet by
attaching it on a display in handwriting input/output system 1 of
the invention. This grid sheet is a transparent sheet on which a
dot pattern is formed and functions as a touch panel when overlaid
and attached on a monitor surface.
[0531] Using a grid sheet disclosed in Japanese Patent Application
No. 2007-230776 (PCT/JP2008/002188) as medium 2, the medium can be
attached on the monitor surface of display 6 to use the monitor
surface as a touch panel, provided, however, means other than the
grid sheet may be employed.
[0532] In addition to using a grid sheet as medium 2, the grid
sheet may be used by being overlaid on medium 2. Such a using
method is particularly effective, firstly, when a user wants to
edit a text or image printed (written) on a medium that is not
specially made for handwriting input/output using handwriting
input/output system 1 of the invention, secondly when a user
hesitates to press imaging unit 7 against the monitor surface.
[0533] FIGS. 68 to 69B are explanatory views showing an embodiment
of using a grid sheet by attaching it on display 6.
[0534] FIG. 68 is a diagram of using a grid sheet with an
information processing device that is a general purpose computer
system. In this embodiment, the grid sheet is attached on a display
screen of a personal computer or the like, such as a liquid crystal
display (LCD) or a CRT (cathode-ray tube) display. The grid sheet
is formed as a transparent film and printed with a dot pattern.
While the details are described later, this dot pattern is formed
by making XY coordinate values and/or code values into a pattern
based on a predetermined algorithm. A scanner as dot pattern
reading means is connected to the main body of the computer. A user
touches the grid sheet using the scanner in accordance with the
instructions on the screen seen through the grid sheet. The scanner
reads out the dot pattern, transmits the dot pattern to the
personal computer through a USB cable. The central processing unit
(CPU) of the personal computer analyzes the dot pattern, calculates
XY coordinate values on the grid sheet, then, converts the XY
coordinate values to xy coordinate values on the display. In this
way, touch panel-style input is realized based on the coordinate
value information.
[0535] According to this, this sheet realizes touch panel style
input, allowing providing a convenient touch panel with low cost.
Further, when browsing Internet sites, even information to which
link information is not set can be referred to by searching
relevant information.
[0536] It should be noted that, while FIG. 68 uses a personal
computer as an information processing device, the present invention
is not limited to this, and the information processing device may
be a personal computer, PDA, television receiving device, front and
rear projectors, game machine, karaoke machine, mobile telephone
terminal, POS terminal, ATM, KIOSK terminal, car navigation system,
pachinko, watch, smartphone, or the like. In these devices, the
grid sheet is placed on the displaying screen of the display or the
screen to make a touch panel-style inputting device.
[0537] FIGS. 69A and 69B are section views showing the internal
structure of the grid sheet described in FIG. 68.
[0538] FIG. 69A is a longitudinal section view showing a state in
which the scanner is used to touch the grid sheet.
[0539] As shown in FIG. 69A, the grid sheet has a laminated
structure comprising an infrared reflection layer, a dot pattern
layer, a transparent protection sheet (a protection layer) in the
order from the display device side.
[0540] The infrared reflection layer is made of a transparent sheet
for evaporation made of material that transmits visible light, such
as vinyl, polyvinyl chloride, polyethylene terephthalate, and
polypropylene, evaporated with infrared reflection material. The
infrared reflection layer reflects infrared light, that is
irradiated from the infrared irradiation means of the scanner and
transmitted through the transparent protection sheet, back to the
scanner and transmits visible light. In this way, the irradiation
light can be limited only to infrared light irradiated from the
infrared irradiation unit, allowing imaging of only bright and
clear dot patterns and accurate analysis of the dot codes.
[0541] The dot pattern layer is printed with a dot pattern in which
dots made of infrared absorbing material, such as carbon ink, are
arranged in accordance with a predetermined rule as described
later.
[0542] The transparent protection sheet is made of material that
transmits visible light and infrared rays, such as vinyl, polyvinyl
chloride, polyethylene terephthalate, and polypropylene. If a dot
pattern is repeatedly touched by the scanner, the dots are worn
off, causing a problem of making the dot pattern hard to read
accurately. To solve the problem, a transparent protection sheet is
provided to prevent dots from wearing and dirt, allowing the sheet
to be used for a long period of time.
[0543] The scanner incorporates an IR-LED as infrared irradiation
means, IR filter that cuts off a predetermined wavelength element
of the reflection light, C-MOS sensor as imaging element, and a
lens. The scanner images the reflection light of the irradiation
light irradiated on the grid sheet. As described above, as the dot
pattern is printed with ink having an infrared absorbing
characteristic, only the dot portion is imaged in black in the
image captured by the C-MOS sensor.
[0544] In this case, a reflection layer specularly reflected off
the infrared reflection layer does not enter into the lens as shown
in FIG. 69A and imaged in black at the center as shown in FIG. 69B.
For this reason, the entire dot pattern cannot be imaged.
Therefore, infrared light is required to be diffusely reflected to
be entered into the lens. That is, as shown in FIG. 70A, an
infrared diffusion layer is provided between the dot pattern
printed layer and infrared reflection layer. This infrared
diffusion layer is formed of transparent or translucent material.
In this way, as shown in FIG. 70B, infrared light irradiated from
IR-LED is specularly reflected off the infrared reflection layer,
diffused by the infrared diffusion layer, then, as the result, the
reflection light of all imaging area enters into the lens.
[0545] It should be noted that, while the infrared diffusion layer
is provided on the grid sheet in FIG. 70, the invention is not
limited to this, and a filter made of infrared diffusing material
may be provided on the imaging opening of the scanner.
[0546] FIGS. 71A to 71G are section views showing a variety of
structures of the grid sheet.
[0547] FIG. 71A is a grid sheet comprising: an infrared reflection
layer having a characteristic of reflecting infrared light and
transmitting visible light; and a dot pattern layer. As shown in
FIG. 71A, infrared light irradiated from the infrared irradiation
means is first absorbed at the part on which the dots of the dot
pattern layer are formed (hereafter, referred to as the dot
portion), and transmits other area. Next, the transmitted infrared
light is specularly reflected off the infrared reflection layer,
then, transmits other part than the dot portion of the dot pattern
layer.
[0548] FIG. 71B is a grid sheet provided with an infrared diffusion
layer, which transmits visible light as well as diffuses the
infrared light, inbetween the infrared reflection layer and the dot
pattern layer. As shown in FIG. 71B, infrared light irradiated from
the infrared irradiation means is first absorbed at the dot portion
of the dot pattern layer, and transmits other area thereof. Next,
the transmitted infrared light is diffused by the infrared
diffusion layer, specularly reflected off the infrared reflection
layer, diffused again by the infrared diffusion layer, then,
transmits other part than the dot portion of the dot pattern
layer.
[0549] FIG. 71C is a grid sheet provided with an infrared diffusion
layer, which transmits visible light as well as diffuses infrared
light, on one side of the dot pattern layer, that is, opposite side
to the infrared reflection layer. As shown in FIG. 71C, infrared
light irradiated from the infrared irradiation means is first
diffused at the infrared diffusion layer, absorbed at the dot
portion of the dot pattern layer, then transmits other area
thereof. Next, the transmitted infrared light is specularly
reflected off the infrared reflection layer, transmits other part
than the dot portion of the dot pattern layer, and diffused by the
infrared diffusion layer.
[0550] FIG. 71D is a grid sheet comprising: an infrared diffuse
reflection layer having a characteristic of diffusely reflecting
infrared light from one side and transmitting visible light; and a
dot pattern layer. As shown in FIG. 71D, infrared light irradiated
from the infrared irradiation means is absorbed at the dot portion
of the dot pattern layer, then transmits other area thereof. Next,
transmitted infrared light is diffusely reflected by the infrared
diffuse reflection layer and transmits other part than the dot
portion of the dot pattern layer.
[0551] FIG. 71E is a grid sheet shown in FIG. 71A provided with a
protection layer having a characteristic of transmitting infrared
light and visible light on the outer surface of the dot pattern
layer side of the grid sheet. Having such a protection layer
prevents the dots from wearing and dirt, enabling longer useful
life of the sheet.
[0552] It should be noted that the protection layer may be provided
on the outer surface of the dot pattern layer side of the grid
sheet shown in FIGS. 71B to 71D in addition to the grid sheet of
FIG. 71A.
[0553] FIG. 71F is a grid sheet shown in FIG. 71A further having a
characteristic of reflecting infrared light coming from the
opposite side to the dot pattern layer. Having such a
characteristic, infrared light from the display screen or screen
attached with the grid sheet of the invention can be cut off and
the irradiation light can be limited only to infrared light
irradiated from the infrared irradiation means. In this way, only
bright and clear dot patterns can be imaged and the dot code can be
correctly analyzed.
[0554] It should be noted that not only the grid sheet in FIG. 71A
but also the grid sheets shown in FIGS. 71B to 71E may also have a
characteristic of reflecting infrared light coming from the
opposite side (the other side) to the dot pattern layer.
[0555] FIG. 71G is a grid sheet shown in FIG. 71A further provided
with an adhesive layer on the other side to the dot pattern layer
side of the infrared reflection layer. The adhesive layer is made
of detachable material. The adhesive layer is only required when
using the grid sheet by attaching it to a display device or a
medium, and not required when using the grid sheet by placing it on
a printed material or by sandwiching it. Having such an adhesive
layer, easy attachment of the grid sheet to a display or the like
can be realized.
[0556] It should be noted that the adhesive layer may be provided
not only on the grid sheet in FIG. 71A, but also on the other side
to the dot pattern layer side of the infrared reflection layers of
the grid sheets shown in FIGS. 71B to 71E.
[0557] FIGS. 72A to 72F show other embodiments of the grid sheet.
These embodiments feature dot pattern layers provided on both sides
of the sheets.
[0558] FIG. 72A is a grid sheet comprising: an infrared reflection
layer having a characteristic of reflecting infrared light from
each side thereof off to each direction as well as transmitting
visible light; and dot pattern layers provided on both sides of the
infrared reflection layer. In this way, both sides of the sheet can
be used and so convenience is improved.
[0559] FIG. 72B is a grid sheet provided with infrared diffusion
layers, which transmit visible light and diffuse infrared light
from each direction, between the infrared reflection layer and the
dot pattern layer of each side.
[0560] FIG. 72C is a grid sheet provided with infrared diffusion
layers on the further outer surface of the each side of the dot
pattern layers on the infrared reflection layer.
[0561] FIG. 72D is a grid sheet comprising: an infrared diffuse
reflection layer; and dot pattern layers provided on both sides of
the infrared diffuse reflection layer.
[0562] FIG. 72E is an information input assistance sheet which is
the grid sheet shown in FIG. 72A provided with protection layers,
having a characteristic of transmitting infrared light and visible
light coming from each direction, on both outer surfaces
thereof
[0563] It should be noted that the protection layers may also be
provided on both outer surfaces of the grid sheets shown in FIGS.
72B to 72D in addition to the one in FIG. 72A.
[0564] FIG. 72F is a grid sheet shown in FIG. 72A further provided
with adhesive layers on opposite sides of the dot pattern layer
sides of the infrared reflection layer, that is, on both outer
sides of the grid sheet.
[0565] It should be noted that the adhesive layers may also be
provided on both outer surfaces of the grid sheets shown in FIGS.
72B to 72E in addition to the one in FIG. 72A.
[0566] Details of each layer of the grid sheets in FIGS. 72A to 72F
and details of how to reflect light are the same as described
above, and so not described here.
[0567] It should be noted that, in the grid sheets shown in FIGS.
72A to 72F, different coordinate values and/or code values may be
made into a pattern between the dot pattern layers on one side and
the other side of the infrared reflection layer or infrared diffuse
reflection layer.
[0568] In addition, in the grid sheets shown in FIGS. 71A to 72F, a
text, illustration, photograph, and the like may be superimposed
and printed on the dot pattern layers or other layers with ink made
of infrared transmitting material or infrared reflecting
material.
[0569] <Problem with Grid Sheet>
[0570] As described above, if an infrared diffuse reflection layer
is not provided on the grid sheet, light is specularly reflected
off the sheet surface, creating an area where infrared reflection
does not enter around the center of the imaging element, which
generates an "eyeball phenomenon" in which a black eye is imaged at
the center as shown in FIG. 69B. Thus, a diffuse reflection layer
is required to be provided and which increases the cost.
Means to Solve the Problem
[0571] Therefore, a method of forming a dot pattern using diffuse
reflection material (diffuse reflection ink) is used for a grid
sheet without a diffuse reflection layer. In this method, as the
dots formed with diffuse reflection material diffusely reflect
infrared light to every direction as shown in FIG. 73A, the
incident infrared light to the dots always enters the imaging
element. In this way, as shown in FIG. 73B, the captured image
shows that the dot pattern is detected as white dots in the black
eyeball area.
[0572] <Method of Determining White Dots and Black Dots>
[0573] An algorithm capable of determining conventional black dots
printed on a normal medium surface and also recognizing the
above-described white dots printed on a grid sheet without a
diffuse reflection layer.
[0574] As one of the simplest methods, there can be considered a
method of, when starting analyzing white dots, inverting all black
and white (negative and positive) of a captured image and using an
analysis algorithm for analyzing black dots. For example, if
brightness of incident light is expressed using eight bits
(black:0-white:255) at each pixel of an image and if the brightness
level of arbitrary pixel (pixel number i, j) is defined as BL(i,
j), brightness level (i, j) of the image with inverted black and
white can be obtained from the following formula:
(i,j)=255-BL(i,j)
However, this method requires black and white inversion calculation
for all pixels, which raises a problem of requiring additional
calculation time.
[0575] Alternatively, instead of using this method, the following
describes details of a method of determining white and black dots
using an algorithm of changing a threshold for black dots to
analyze white dots in the eyeball area.
[0576] First, an analysis algorithm for determining black dots is
described with reference to FIG. 74A. This algorithm is a scan-line
algorithm performed per line, calculating differences of brightness
between pixels that are apart at a predetermined interval starting
from the left end to rightward direction, determining whether the
difference exceeds or falls below the positive/negative threshold,
determining the pixel on the right side as a dot if the difference
falls below the negative threshold, and determining the dot starts
from that pixel. Likewise, if the difference exceeds the positive
threshold, the algorithm determines that the pixel on the right
side is not a dot, and determines that the dot ends at the previous
pixel. Here, if dots are determined with the threshold of absolute
quantity, when an image is captured by inclining the scanner, dark
part and bright part are generated. Lowering in brightness at dark
part becomes significant and dots at dark part cannot be
determined. However, as described above, using thresholds for
determining a difference in brightness between two points, dots can
be determined accurately even at dark part of the image.
[0577] Here, the reason for using the difference between pixels
that are apart at a predetermined interval instead of the
difference in brightness between neighboring pixels, is that, as a
brightness difference is small around the outline with an image
captured with blurred dot outline, if the distance between pixels
for extracting a difference is too close, the difference is small
and does not exceed the threshold, disabling determination of
dots.
[0578] For example, if this predetermined interval is "4," and a
difference between pixel number i and pixel number i+4 on line j is
.DELTA.BL(i, j), .DELTA.BL(i, j) can be obtained by the following
formula:
.DELTA.BL(i,j)=BL(i+4,j)-BL(i,j)
The threshold to be used is defined as .phi. (.phi.>0). It
should be noted that, if brightness is expressed by eight bits
(bright level 0-255), .phi.=approx. 25-50 at bright area, and
.phi.=approx. 8-16 at dark area are appropriate.
[0579] In this way, by dynamically changing the threshold for dark
area with small brightness difference from dot portion and the
threshold for bright area with large brightness difference from dot
portion, the dots can be more accurately determined.
[0580] Here, if, in relation to threshold .phi., .DELTA.BL(i, j) is
.DELTA.BL(i, j)<-.phi., it is determined that a dot starts from
the pixel of i+4 position. If .DELTA.BL(i, j)>.phi., it is
determined that a dot ends at the pixel of i+3 position.
[0581] This threshold determination is inverted in the algorithm
for analyzing the positions of white dots.
[0582] That is, if, in relation to the same threshold .phi.,
.DELTA.BL(i, j) is .DELTA.BL(i, j)>.phi., it is determined that
a dot starts from the pixel of i+4 position. If .DELTA.BL(i,
j)<-.phi., it is determined that a dot ends at the pixel of i+3
position.
[0583] Using this method, positions of white dots can be easily
determined without inverting black and white of all pixels.
[0584] <Configuration of Pen Scanner with Enlarged Eyeball
Part>
[0585] If white dots are read out by a scanner using a grid sheet,
the size of the black eye part should be increased to enlarge the
area of detecting a dot pattern.
[0586] Now, the configuration of a scanner that makes larger black
eye part is described.
[0587] As shown in FIG. 75, on the assumption of a light path
through which infrared light emitted from around the inner side of
the open end of the image opening can be specularly reflected off
the grid sheet and enter into the imaging element, a light guide is
provided outside the light path to evenly irradiate the entire
medium surface. In this way, infrared light emitted from the light
guide is specularly reflected off the grid sheet to make large area
of the captured image the black eye part. Here, a light blocking
part should be provided at the position shown in FIG. 75 to prevent
excessive infrared light from being specularly reflected off the
grid sheet and entering into the imaging element. It should be
noted that, if the scanner is inclined, while the black eye area
becomes smaller due to the structure, the imaging area is enlarged
and the number of imaged white dots increases, enabling analyzing a
dot code without a problem.
[0588] <Method of Determining Whether in Contact with a Medium
or not>
[0589] If the codes on a medium are kept being read while the
scanner is in contact with the medium surface, for example, if a
user slightly shifts the reading position without intention, the
scanner reads out a code different from the user's intention and
reproduces a different content. To eliminate such a situation, the
scanner may be configured to ignore a code different from the code
read for the first time. However, when tracing a medium surface
using the scanner as in handwriting input, codes (coordinate
values) being read one after another should be input. In such a
case, coordinate values may always be processed as normal input
when a new coordinate value is read for the next time while
ignoring errors. Further, if the scanner is configured to input the
same code that was read for the second time as the code that was
read for the first time when an error once occurs due to a slight
movement of the scanner, the scanner keeps starting the same
content over and over again (playing, such as repeating "hello,
hello, hello . . . ," occurs), disabling appropriate operation.
[0590] Thus, it is necessary to determine whether the scanner is in
contact with the medium surface, and as long as the scanner is in
contact with the medium surface, ignore the same code that is read
for the second time (a different code may also be ignored), and
continue the execution of a content or an instruction corresponding
to the code that was read by the scanner for the first time when
the scanner became in contact with the medium surface. It will be
appreciated that if the scanner is once separated from the medium
surface and becomes in contact with the medium surface again, the
ongoing content and instruction is terminated and execution of the
content and instruction corresponding to the newly read code
(whether it is the same code or a different code) is started. It
should be noted that if the code cannot be read even the scanner is
in contact with the medium surface, the execution of ongoing
content and instruction continues.
[0591] If this method is used and only black dots arranged on the
medium surface are to be read, brightness at the center part of the
read image may be simply measured to determine that the pen is in
contact with the medium surface if it is bright, and determine that
the pen is not in contact with the medium surface if it is dark.
The reason why only brightness of the center part is measured is
because decrease in brightness is small at the center part even
when the scanner is inclined, thus, not affecting the
determination, and the measurement time can be minimum by defining
only the center part as the measurement area.
[0592] However, with the scanner that can read both black dots and
white dots, as the center part of the read image is dark when
reading white dots, it is erroneously determined that the pen is
not in contact with the medium surface.
[0593] So, the following describes a method of determining whether
the scanner that can read both black and white dots is in contact
with either a normal medium surface (e.g., print medium surface) or
a grid sheet, or not in contact with any of them, with reference to
FIG. 76.
[0594] First, an image is captured by the imaging element
(S10).
[0595] Whether the center part of the captured image is bright or
not is measured (S20), and if the center part is bright, it is
determined that the scanner is in contact with a normal medium
surface (S25). The measurement of whether the center part of the
image is bright or not is determined by whether or not the
brightness at the center part of the image exceeds a predetermined
threshold or not.
[0596] If the center part is not determined as bright, white dots
are searched in the image (S30). If white dots are detected, it is
determined that the scanner is in contact with the grid sheet
(S35).
[0597] If it is determined that there is no white dot, it is
determined that the scanner is not touching the medium surface
(S40).
[0598] After determining S25, S35, and S40, the analysis ends.
[0599] To search white dots in a dark part area in S30, whether
peripheral pixels form white dots is determined in a spiral manner
from the center of the captured image within a predetermined area
(minimum area where a predetermined amount of dots always exist) as
shown in FIG. 77.
[0600] If it is determined that the scanner is in contact with a
normal medium surface in S25 above, analysis of black dots (a
conventional algorithm) is started. If it is determined that the
scanner is in contact with a grid sheet in S35, analysis of white
dots (a new algorithm) is started.
[0601] <Newly Added Features Under the Priority Claim Based on
Patent Application>
<Afterimage Characteristic of Imaging Element>
[0602] It should be noted, for the electrical charge of the element
shown in FIG. 17C, the way in which afterimage of imaging element
12 disappears within predetermined time t.sub.k may be slower in
addition to the one shown in FIG. 17C.
[0603] <Shape of Writing Area>
[0604] So far as described above, the writing area was always a
rectangle. If the writing area is identified using code information
as in this invention, the shape of the writing area may be, for
example, a polygon, circle, ellipse, heart, and star as shown in
FIG. 78. Or if an illustration and a dot pattern are superimposed
and printed, the shape may be the outline of the actual line of the
illustration. Whatever the shape of the writing area may be,
similar analysis efficiency can be realized.
[0605] Conventionally, to identify the writing area only using the
coordinate information, the coordinates indicating the boundary of
the writing area should be defined in advance using a table or a
function, and whether the input coordinate value is in the scope of
the table or the function or not should be determined for each
time. As the result, the analysis becomes complicated, and if the
writing area is identified using only coordinate information, the
writing area is required to be a rectangle to minimize decrease in
analysis efficiency of the memory used, calculation rate, and the
like. If the writing area is a rectangle, the minimum value and
maximum value of the XY coordinate values of the rectangular area
are stored in a table and whether the input coordinate value is in
the scope or not is determined. Therefore, even when the writing
area is a rectangle, memory is required to be used four times as
much and four times of additional comparing calculations to
determine whether it is the writing area is required compared with
the case of specifying the writing area using code information.
Further, if there are a plurality of writing areas, determination
of which one of the writing areas is required, and, thus, enormous
volume of memory used and calculation rate are expected to be
required. In this invention, as code information directly
identifies the writing area no matter what the shape of the writing
area is like, the writing area can be identified without using
additional memory used or performing additional calculations.
[0606] <Determining by Combination of Arrangement
Directions>
[0607] The following describes another method of automatically
determining operation.
[0608] If a dot pattern that defines information by arranging an
information dot with a distance and direction from a reference
position (the first digitized information), such as GRID1 and
GRID3, is used, information of the combination of the arrangement
directions (the second digitized information) whether arranging the
information dot on + direction lines (on upward, downward,
leftward, and rightward direction lines), or arranging on x
direction lines (on diagonal lines) can be defined. If the case in
which an information dot is arranged on x direction lines is
defined as "0" and the case in which an information dot is arranged
on + direction lines is defined as "1," the second digitized
information in the dot pattern of FIG. 79B is "1010010110100101,"
and the second digitized information in the dot pattern of FIG. 80B
is "0000000011111111."
[0609] In addition to the arrangement direction of an information
dot, the second digitized information can be defined by the
combination of which distance the information dot is arranged with
reference to the virtual reference point by defining two or more
patterns of distances to arrange an information dot from a virtual
reference point (arrangement distances).
[0610] It will be appreciated that the second digitized information
may be defined by the combination of both the arrangement direction
and arrangement distance of an information dot.
[0611] That is, the second digitized information means information
that is defined by the arrangement rule of an information dot, such
as the arrangement direction and arrangement distance of the
information dot.
[0612] While the inventor had proposed a dot pattern format that
defines both code information and coordinate information, with such
a dot pattern format, a large dot pattern distribution area has to
be provided to increase the number of information dots, requiring a
large scanning area of the optical reading unit of the pen scanner
to read the dot pattern.
[0613] For this reason, it was difficult for toys and the like that
comprise an optical reading unit with low reading accuracy,
calculation rate, and calculation capacity to use a format that
defines both code information and coordinate information. However,
the above-described method can define large amount of information
even with a dot pattern with small number of information dots in a
small distribution area.
INDUSTRIAL APPLICABILITY
[0614] Firstly, the handwriting input/output system of the
invention has an industrial applicability as an input device with
which a person who has not acquired techniques for using existing
input devices used for computer operations, such as a mouse,
keyboard, and tablet, can use as if writing on a paper medium.
Further, the handwriting input/output system of the invention has
an industrial applicability as a toy mainly targeting children,
particularly as an educational toy.
[0615] Secondly, as the handwriting input/output system of the
invention can identify the writing area based on the code
information read out simultaneously with the coordinate
information, if a handwritten input content belongs to a
predetermined category, the recognition rate significantly
increases by referring to a dictionary of that category.
[0616] Thirdly, the handwriting input/output system of the
invention determines whether it is the writing area or not only by
reading a dot pattern without a special operation of an operator,
realizing intuitive handwriting input by anybody as if using a
favorite writing material.
DESCRIPTION OF REFERENCE NUMERALS AND SIGNS
[0617] 1 HANDWRITING INPUT/OUTPUT SYSTEM [0618] 2 MEDIUM [0619] 3
SCANNER [0620] 4 COMPUTER [0621] 5 SERVER [0622] 6 DISPLAY [0623] 7
IMAGING UNIT [0624] 8 DOT PATTERN ANALYSIS UNIT [0625] 9 TRAJECTORY
RECOGNITION UNIT [0626] 10 PROCESS INSTRUCTION UNIT [0627] 11
INFORMATION PROCESSING UNIT [0628] 12 IMAGING ELEMENT [0629] 13
IRRADIATION UNIT [0630] 14 LIGHT CONTROL UNIT [0631] 15 TIMER
[0632] 16 ANGLE MEASURING UNIT [0633] 17 ANGLE CHANGE RECOGNITION
UNIT [0634] 18 ROTATION ANGLE READING UNIT [0635] 19 ROTATION ANGLE
CHANGE RECOGNITION UNIT [0636] 20 SOUND RECORDING UNIT [0637] 21
SOUND RECOGNITION UNIT [0638] 22 SOUND OUTPUT UNIT [0639] 23
TRANSMISSION UNIT [0640] 24 TRANSMISSION BUTTON [0641] 25
RETRANSMISSION BUTTON [0642] 26 MICROPHONE [0643] 27 SOUND PLAY
BUTTON [0644] 28 PROJECTION FOR INSTRUCTION [0645] 29 PEN [0646] 30
PEN RETRACT BUTTON [0647] 31 PEN-SHAPED SCANNER [0648] 32 LIGHT
GUIDE [0649] 33 LENS [0650] 34 LED [0651] 35 C-MOS SENSOR [0652] 36
PCB [0653] 37 PEN [0654] 38 GUIDE BANK [0655] 39 BRAILLE [0656] 40
MICRO PROCESSING UNIT (MPU) [0657] 41 MICROPHONE [0658] 42
AMPLIFIER [0659] 43 A/D CONVERTER [0660] 44 COMPRESSION CIRCUIT
[0661] 45 SPEAKER [0662] 46 EARPHONE
* * * * *