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Claims  |
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What is claimed is:
1. A hand-held scanner for reading characters from a strong of characters
recorded on a substrate, comprising:
a housing, being adapted to be held by a user in the manner of a pen and
being further adapted such that the scanner may be conveniently moved, in
contact with the substrate, along the string of characters, the housing
having a bottom face adjacent the substrate, the bottom face having a
projection on the substrate;
movement sensor means, mounted to the housing, for detecting movement of
the scanner across the surface of the substrate;
optical means, located within the housing, for viewing an area of view;
optical detector means, located within the housing, for detecting the
relative intensity of light reflected from each of a plurality of points
in the area of view;
wherein the housing is further adapted such that the area of view is
outside of the projection of the housing's bottom face on the substrate,
so that the user may view a field of view which includes the area of view,
and such that the field of view is entirely unobstructed by the housing in
at least one direction along the string of characters from the area of
view, so as to facilitate tracing.
2. An apparatus according to claim 1, wherein the field of view is entirely
unobstructed by the housing in both directions along the string of
characters from the area of view.
3. A hand-held scanner for reading characters from a string of characters
recorded on a substrate, comprising:
a housing, being adapted to be held in the manner of a pen and being
further adapted such that the scanner may be conveniently moved, in
contact with the substrate, along the string of characters;
movement sensor means, mounted to the housing, for detecting movement of
the scanner across the surface of the substrate;
optical means, located within the housing, for viewing an area of view;
optical detector means, located within the housing, for detecting the
relative intensity of light reflected from each of a plurality of points
in the area of view;
wherein the housing has an elongated shape and a longitudinal axis, and a
brow proximate to the substrate and angled with respect to the
longitudinal axis, the brow having a window for defining the area of view,
such that the area of view may lie substantially outside the projection of
the housing on the substrate.
4. An apparatus according to claim 3, wherein the area of view does not
extend substantially above the tallest character in the character string
nor substantially below the deepest character in the character string.
5. An apparatus according to claim 4, wherein the length of the area of
view, in a direction transverse to the string of characters, is between
5.40 mm and 5.70 mm long.
6. An apparatus according to claim 3, wherein the scanner further includes
memory means for storing codes representing individual characters.
7. An apparatus according to claim 6, further comprising a battery-operated
power supply and wherein the scanner is self-contained.
8. An apparatus according to claim 7, further including interface means,
including a connector, for transferring the codes from the memory means to
a computer.
9. An apparatus according to claim 7, wherein the memory means is
removable.
10. An apparatus according to claim 3, further including a computer, in
communication with the housing.
11. An apparatus according to claim 10, wherein the computer further
includes a direct memory access channel, and the computer accepts the
synchronization signals via the direct memory access channel.
12. An apparatus according to claim 11, the computer further including
display means for display of scanned characters.
13. An apparatus according to claim 3, wherein the movement sensor means
includes a wheel whose axis is transverse to the string of characters
while the scanner is being used for scanning.
14. An apparatus according to claim 3, wherein the optical detector means
further includes:
photo diode array means for transforming light into an electrical signal;
and
amplification means for accepting and amplifying the electrical signal;
wherein the photo-diode array means and the amplification means are mounted
in separate packages.
15. An apparatus according to claim 14, wherein the photo diode array means
further includes a linear array of photo diodes and the center to center
spacing between adjacent photo diodes is between 0.0800 mm and 0.0868 mm.
16. A hand-held scanner for reading characters from a string of characters
recorded on a substrate, comprising:
a housing, being adapted to be hand-held and being further adapted such
that the scanner may be conveniently moved, in contact with the substrate,
along the string of characters;
movement sensor means, mounted to the housing, for detecting movement of
the scanner across the surface of the substrate and providing
synchronization signals indicative of a series of positions along the
length of the string of characters;
optical means, located within the housing, for viewing an elongated area of
view transverse to the string of characters;
optical detector means, located within the housing, for detecting the
relative intensity of light reflected from each of a plurality of points
along the elongated area of view and providing an intensity signal for
each point; and
electronic means, mounted within the housing, for accepting intensity
signals and synchronization signals and identifying the intensity signals
associated with a given character in the string of characters;
wherein the housing has an elongated shape and a longitudinal axis, and a
brow proximate to the substrate and angled with respect to the
longitudinal axis, the brow having a window for defining the area of view,
such that the area of view may lie substantially outside the projection of
the housing on the substrate.
17. An apparatus according to claim 16, further including means for
translating intensity signals into binary data and means for assembling
the binary data associated with a given single character into a set of
binary data representative of that single character.
18. An apparatus according to claim 17, further including display means,
mounted to the housing, for display of scanned characters.
19. A hand-held scanner for reading characters from a string of characters
recorded on a substrate, comprising:
a housing, being adapted to be held by a user in the manner of a pen and
being further adapted such that the scanner may be conveniently moved, in
contact with the substrate, along the string of characters;
movement sensor means, mounted to the housing, for detecting movement of
the scanner across the surface of the substrate;
optical means, located within the housing, for viewing an area of view;
optical detector means, located within the housing, for detecting the
relative intensity of light reflected from each of a plurality of points
in the area of view;
wherein the housing is further adapted such that the user may view a field
of view which includes the area of view, along a line of sight, between an
eye of the user and the area of view, that is approximately perpendicular
to the substrate, and such that the field of view is entirely unobstructed
by the housing in at least one direction along the string of characters
from the area of view, so as to facilitate tracking.
20. An apparatus according to claim 19, wherein the field of view is
entirely unobstructed by the housing in both directions along the string
of characters from the area of view. |
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Claims |
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Description |
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TECHNICAL FIELD OF THE INVENTION
The invention relates generally to hand-held scanners and more specifically
to hand-held scanners for scanning text.
BACKGROUND OF THE INVENTION
Hand-held scanners used for acquiring textual information from printed
sources are available but all of them are bulky, most require to be
connected via cable to a computer while in use and none are capable of
reading along a line of text, one character at a time, to selectively read
a single line of text or a portion of a single line of text.
U.S. Pat. No. 4,887,165 to Sato discloses a portable image reader, having a
detachable memory, capable of scanning a document and selectively storing
bit-mapped images in its detachable memory for later transfer to a
computer for OCR processing and editing. The image reader of the Sato
invention is designed to operate disconnected from the body of the
document editing apparatus. It is moved by hand down a document such that
its viewing area covers each entire line of text in succession. There is
provision for selective discard of scanned images (such as portions of a
page read from the document for test purposes or portions of a page that
are deemed unnecessary) to improve utilization of the limited memory
available. However, the device is not capable of selectively reading
individual characters from a line.
U.S. Pat. No. 4,158,194 to McWaters discloses a battery-operated hand-held
optical character reader, including a hand-held wand and a recognition
control unit, that is capable of manual scanning of alphanumeric
characters. The wand includes a keyboard and a display and is designed to
be moved along a line of text such as on a label or on a document. The
wand provides illumination of the label or document by use of a
fiber-optic light pipe. The wand is, however, attached by a cable (or by a
receive/transmit unit) to the recognition control unit which is battery
operated and portable but too large to be hand-held.
U.S. Pat. No. 4,817,185 to Yamoguchi discloses an optical character reader
having a hand-held scanner whose field of view covers a plurality of
characters such as for reading the characters on a price tag. This scanner
provides character line deletion and selects from among horizontal optical
recognition ranges of various widths corresponding to possible character
heights.
U.S. Pat. No. 3,947,817 to Requa discloses a hand-held optical data reader
and a processor utilizing a two dimensional array of photosensitive
elements capable of operation at a high frame rate. The processor is an
OCR device using hardware combinational logic. The optical data reader is
connected by a cable to the processor. The invention includes timing
circuitry to overcome the inaccuracies arising from the loosely
constrained movement of a hand-held device.
U.S. Pat. No. 3,918,028 to Humphrey discloses a hand-held optical reader
having a light source and a line-array of optical sensors and the
hand-held optical reader contains OCR circuitry. The OCR circuitry is
capable of recognizing a limited set of characters consisting of
horizontal and vertical bars.
U.S Pat. No. 4,048,617 to Neff discloses apparatus and method for detecting
and discarding characters picked up on the back scan when using a
hand-held optical scan unit.
U.S. Pat. No. 4,180,204 to Koenig discloses a hand-held scanner for
scanning and recognizing characters on shipping labels and for marking the
label on successful completion of a character recognition reading using a
photosensitive dye-forming material and a UV flash.
The article "Scanners Build a Better Image", PC Magazine, Mar. 28, 1989,
describes the Mitsubishi Hand-Held Image Scanner. This hand-held scanner
requires cable connection to a PC and with an optional attachment is
capable of reading a full 81/2 by 14 inch document. This device is not
designed to scan selectively along a succession of single lines of text.
It is difficult for a user of a prior art scanner to aim the scanner and
sweep the line of characters accurately because, with prior art scanners,
it is impossible to view simultaneously characters before the device,
directly under the device, and following the device. Accuracy of aim is
critical, and the human hand is subject to variable movements that would
jeopardize accurate movement.
SUMMARY OF THE INVENTION
A hand-held scanner is provided for reading characters from a string of
characters recorded on a substrate. The housing of the scanner is shaped
so that it may be held like a pen and conveniently moved, in contact with
the substrate, along the string of characters. Movement of the scanner
across the surface of the substrate is sensed by a sensor. An optical
system, located within the housing, views a small area of the substrate
and an optical detector detects the relative intensity of light reflected
from each of several points in the area of view.
In a preferred embodiment, the area of view is clearly visible to the user
while the scanner is being used for scanning. Also clearly visible, so as
to facilitate tracking, is at least a portion of the string of characters
adjacent to the area of view. The height of the area of view is not
substantially greater than the maximum height of a character. The scanner
includes memory for storing codes representing individual characters. In
one embodiment the scanner includes a computer, connected to the housing
via a cable. In a further embodiment the scanner is self-contained and
battery operated.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a general view of a first embodiment of a hand-held scanner
according to the present invention.
FIG. 2a is a partially cut-away elevation view of a second embodiment of a
hand-held scanner according to the present invention, showing the major
systems.
FIG. 2b is a partially cut-away plan view of the scanner of FIG. 1, showing
the same major systems.
FIG. 2c shows the geometry of the optical system of the embodiment of FIG.
2a.
FIG. 3a is a partially cut-away perspective view of the tip of an
embodiment of the scanner of FIG. 1.
FIG. 3b shows a series of intersection lines along the string of
characters.
FIG. 4a shows an embodiment wherein the electronic processor is a personal
computer.
FIG. 4b shows a self-contained embodiment wherein the electronic processor
is mounted within the housing.
FIG. 5 is a functional block diagram of the scanner.
FIGS. 6a, 6b and 6c show the circuit diagram of the digital I/O board.
FIG. 7 shows the knurled wheel of the embodiment of FIG. 1.
FIG. 8 is a partially cut-away view of a third embodiment of the scanner,
having an illumination system.
FIG. 9a shows a general view of the movement sensor of the embodiment of
FIG. 8.
FIG. 9b shows a view of the movement sensor along direction A--A of FIG.
9a.
FIG. 10 provides detail of the geometry of the optical system of the
embodiment of FIG. 8.
FIG. 11 is a partially cut-away perspective view of a fourth embodiment of
the present invention.
FIG. 12 is a general view of the embodiment of FIG. 11.
FIG. 13 is a partially cut-away plan view of the embodiment of FIG. 11.
FIG. 14 is a partially cut-away elevation view of the embodiment of FIG. 11
.
DETAILED DESCRIPTION OF THE INVENTION
The invention provides a small, battery-operated, hand-held, pen-like
scanner for note-taking, i.e., acquiring textual information from printed
sources. The scanner is capable of reading and storing selected
information, for example, some or all of the characters from a given line
of text. The text is stored in a series of digital data records, each
record containing a representation of a single character in bit-mapped
form. The scanner has a contact scanning head having an area of view sized
for compatibility with printed characters having point size 9pt, 10pt or
11pt which are commonly-used print standards. The scanner is stroked along
a line of text, in one embodiment from left to right, so that each
character in turn is partially in the view area. In this way the area of
view encompasses a succession of substantially vertical slices of each
character. A character boundary is recognized when the view area of the
scanner is filled by white space. A digital bit-map representation of a
given character is stored in the memory of the scanner along with
appropriate delimiters. In this way a series of records are stored
corresponding to the sequence of characters along the line of text. The
scanner also recognizes and stores the spaces between words and an
indication of "end of line" (or carriage return). In a first embodiment a
connector is provided in the scanner so that records ("frame units" of
bit-mapped data) may be uploaded into a computer having OCR software
capable of transforming the records into an ASCII text file.
A first embodiment of the scanner of the present invention is shown in FIG.
1. The entire scanner 1, in this embodiment is battery operated and
self-contained. It is shown, held in the hand of the user, scanning a
document 2. A second embodiment includes a computer external to the
housing, and is shown in FIG. 4a. A partially cut-away elevation and plan
view of the second embodiment are shown in FIGS. 2a and 2b respectively.
FIG. 2a shows a wheel 21, sometimes referred to as a "roller", in contact
with the substrate 2. The general location of the movement sensor 22, the
optical system 23 and the detector electronics board 24 are shown in these
drawings. FIG. 2a shows the lens 25 and the diode array detector 26. The
image of the substrate in the area of view, which is shown in FIG. 3a, 32
is focussed by the lens onto the diode array detector. In this embodiment
the diode array detector comprises 64 individual diodes. FIG. 2b shows the
cut-away area of the housing 4 which permits the user to see the
characters about to enter the area of view of scanner. To further
facilitate tracking, a visual alignment guide may be provided. An index
line or a pair of index lines on top of (or on the side of) the housing
may be provided. Alternatively, an alignment protrusion or bar may be
provided.
FIG. 3a shows a partially cut-away perspective view of the tip of the
scanner, or scanner head, showing the wheel 21 in contact with the
document, the elongated area of view 32, or strip and the cut-away region
of the housing 4. The optical system (23 in FIG. 2a), includes the lens
and the diode array detector. FIG. 3a shows a sensing window 33 through
which the optical system views an elongated area of view 32. The length of
the long axis of the elongated area of view 32 is 5.40 mm-5.70 mm. FIG. 3b
shows a series of intersection lines 34 along the string of characters
corresponding to successive scan positions as the scanner is moved over
the substrate along the line of characters. Each intersection line,
corresponding to a single position of the area view 32, is viewed by a
diode array detector. The diode array detector in the second embodiment
includes an array of 128 diodes. Half of the diodes (64 diodes, every
second diode) are used. Thus, viewing a single intersection line yields 64
pixels. The first pixel and the 64th pixel are shown in FIG. 3b as items
35 and 36 respectively. An "end-of-character" is recognized when the diode
array sees only white space. Data from the intersection lines between two
consecutive "white space" lines defines a single character. Each
intersection line provides 64 bits of data. One character therefore is
represented by n * 64 bits of data where n is the number of intersection
lines the character contains. In the example shown in FIG. 3b, the letter
"e" is encoded by the five intersection lines 37 yielding 5 * 64=320 bits
of data.
FIGS. 4a and 4b show the location of the electronic processor function 41
referred to hereinbelow. In FIG. 4a, which shows the second embodiment,
the processor function resides in a personal computer. FIG. 4b, which
shows he first embodiment, the processor function is included in a
microprocessor mounted within the housing. The scanner of both embodiments
inserts a single, soft carriage return each time the wheel loses contact
with the document. FIG. 4a shows, on the screen of the PC display, a
typical display resulting from scanning a series of short lines of text.
The embodiment of FIG. 4b, the self-contained scanner, also includes a
connector (not shown) so that after a document has been scanned, data
stored in the scanner memory may be transferred via a cable to a computer.
Of course, other methods of transferring data could be used, within the
scope of the invention, such as infra red transmission or a removable
memory.
FIG. 5 shows all three major functional elements of a preferred embodiment
of a scanner corresponding to FIG. 4a. The three major elements are the
light intensity measurement system 514, the movement detection system 515
and the control and synchronization system 516. The light intensity
measurement system includes the optical system 23, the detector board 503
including the diode array detector 26, the signal amplifier 504, the
output (TTL) comparator 505, and the serial to parallel converter 506. The
movement detection system includes the wheel 21, the movement sensor 22,
wheel sensor comparator 1 508, wheel sensor logic 509, bandpass filter 510
and wheel sensor comparator 2 511. The control and synchronization system
includes the digital I/O card 512, an off-the-shelf board mounted within
the PC, the PC itself and the software that runs the PC. Each of these
three systems will now be discussed in turn.
LIGHT INTENSITY MEASUREMENT SYSTEM
The optical system for a preferred embodiment is shown in FIGS. 2a, 2b and
2c. It includes a symmetric biconvex lens 25, 9 mm focal length, 6 mm
diameter, positioned in the Schiempflugg condition between the object and
the image. Referring to FIG. 2c, in this condition, the object plane 29,
the image plane 27 and the plane of the lens 28 meet in a line 201 and all
points on the object plane are in focus on the image plane. The angles
have been chosen so that total internal reflection within the detector
window cannot occur. Unity optical magnification is used. At this
magnification the simple symmetric lens yields relatively good image
quality. The operating f number is 4 or higher.
In a preferred embodiment, the optical system includes a SELFOC lens
system. This approach provides a lower cost lens system. The use of a
SELFOC lens system also minimizes assembly cost because such systems are
"self-aligning".
The detector board 503 includes an EG&G/Reticon CCD array. For an
embodiment corresponding to FIG. 4a, the detector board also includes line
receivers and line driver buffers to interface to the cable. The CCD array
detects light, and transmits its signal via the detector/video board cable
507 to the signal amplifier 504.
In the embodiment of FIG. 4a, the detector 503 is an EG&G T series CCD
array with 128 pixels covering 0.25 inch (6.35 cm). In a preferred
embodiment, every other pixel is sampled, yielding 64 pixels/line or 256
pixels/inch (101 pixels/cm). The video board electronics 501 has a
"boxcar" style output. The output is fed into a comparator 505 and a
serial to parallel converter 506. A field stop is used to limit the image
projected onto the detector.
The signal amplifier 504 is located on the video board 501, within the
housing, to ensure good electronic transmission. A level shifting circuit
whose output is fed to the comparator 505 is also mounted on the video
board.
The video board 501 provides the proper voltages and control signals for
the detector board 503, generates clock phases, and amplifies and
translates the CCD output signal. The output of the video board consists
of three control signals, namely, a pixel clock, a start-of-frame signal,
and an end-of-frame signal, and one analog signal which is the sampled and
held CCD output bit. After a start-of-frame (and before the end-of-frame),
the analog output is sampled on the rising edge of the pixel clock to
ensure accurate data.
The output (TTL) comparator 505 is used to convert each sampled-and-held
analog signal from the video board into a binary indication of light. The
comparator has an adjustable threshold. The output of the comparator is a
TTL compatible serial data stream, a stream of 64 bits out of the CCD
array. These 64 bits contain the data from the viewing of a single
intersection line.
Eight serial-in/parallel-out shift registers are used to capture this data
stream. The serial bits are clocked with a gated pixel clock which is only
active between a start-of-frame and an end-of-frame, and corresponds to
one clock every other pixel. The parallel output of the serial-to-parallel
convertor is used as the digital data for the software.
MOVEMENT DETECTION SYSTEM
The wheel 21 is preferably made of steel, has a straight: knurled
circumference and is rotatably mounted on a close fitting metal axle
pressed into the housing. In one embodiment an electromagnetic wheel
sensor is used. Alternatively, an optical wheel sensor may be used.
An electromagnetic wheel sensor has the advantage that it generates its own
signal. However, the amplitude of signals so generated is a function of
speed and at low speeds the amplitude is small. A preferred alternative is
a fiber optic reflective-type wheel sensor which senses reflections from a
polished camber on the knurl. Optical speed sensors operate down to very
low speeds, but require a reliable source of light. The same source of
light may be used to provide illumination for both the substrate and the
wheel sensor.
The wheel sensor output is used to synchronize scanning at correct
positions along the character string. The output of the wheel sensor is
used to initiate scans at intersection lines 34 along the character stream
as shown in FIG. 3b. When the scanner is moved across the surface of the
substrate so that the wheel rotates and the wheel sensor detects the
rotation, then comparator 508 and logic 509 generate a square wave. A
differential amplifier, not shown but located between items 22 and 508 in
FIG. 5, amplifies the wheel sensor's output to generate a signal large
enough to drive wheel sensor comparator 1 508. Wheel sensor comparator 1
uses hysteresis to detect pulses from the wheel sensor, translates these
pulses into fixed amplitude pulses and toggles a flip flop to provide a
50% duty cycle signal, or square wave. A change of state of this square
wave indicates a displacement of the scanner across the substrate of
1/30th of an inch (0.0847 cm). The square wave is further filtered by a
band-pass filter 510 (high-pass filtered, rectified then low-pass
filtered) to yield a signal that is fed into wheel sensor comparator 2 511
to detect motion and generate a RUNNING signal. As shown in FIG. 5, this
process yields LINE MARK triggers and a RUNNING signal. These signals are
fed via the digital I/O board 512 into the PC 41 and are used by the PC
software to generate DATA CLOCK signals which control the timing of
scanning via video board 501 to correspond to the intersection lines 34 of
FIG. 3b.
FIG. 7 shows the wheel construction having straight knurls 71 and a camber
72. In a preferred embodiment the wheel has a diameter 73 of 0.250 inch
(6.35 cm) over the points of the knurls and a width 74 of 0.312 inch (7.92
cm). The camber 72 has a cutback 75 of 0.015 inch (0.381 cm) and a face
width 76 of 0.050 inch (1.27 cm). It is cut at a 45.degree. angle and the
face is buffed bright. The knurls may be 0.012 inch (0.30 cm) deep
(medium) or 0.005 inch (0.13 cm) deep (fine).
CONTROL, DISPLAY AND SYNCHRONIZATION SYSTEM
In the embodiment of FIG. 4a, an off-the-shelf digital I/O board 512,
located within the PC, is used to accept the digital data from the
movement sensor and from the optical system. The circuitry for this I/O
board is shown in FIGS. 6a, 6b and 6c. Software in the PC detects motion
by monitoring the RUNNING signal. When the RUNNING signal is active, the
pen is moving and scans are initiated. Software in the PC monitors the
BUSY signal from the video/PC logic board 502 to determine when to upload
the contents of the image buffers in the serial to parallel convertor 506.
When the BUSY bit becomes inactive, the software uploads the data. This
data includes the binary image, as well as the speed sensor SYNCH signal.
Typically, data will be read at a rate faster than 300 frames per inch
(118 frames per cm), although the SYNCH signal will only signal 1/30th of
an inch (0.0847 cm).
When memory is full, or when pen motion is no longer detected, software in
the PC processes the raw data. For every change in the SYNCH signal
(representing 1/30th of an inch or 0.0847 cm), the software compresses the
data such that there are ten frames worth of data for each SYNCH
transition (1/300th of an inch or 0.00847 cm). This off-line processing
yields the required resolution of 1/300th inch (0.00847 cm), without
requiring a speed sensor with so fine a grain.
Once the raw data has been compressed, and perhaps displayed, the software
can perform additional data compression for storage to disk.
EMBODIMENT WITH ILLUMINATION SYSTEM
The illumination system of an alternative embodiment is shown in FIG. 8. A
source of illumination 81 generates a focussed light beam 87 which is
reflected off a mirror 86 to illuminate the field of view 88. An optical
system 82 projects an image 83 of the field of view onto an image sensor
84. In this embodiment a movement sensor system 85, having a wheel 89, is
mounted external to the housing. Details of the movement sensor system are
shown in FIG. 9a and FIG. 9b. In this system an optical coding disk 91
mounted on support structure 92 is illuminated by an LED light source 93.
Light detector 94 detects light beam 96 and thereby detects rotation of
the disk which is driven via a gear train in transmission box 95. Details
of the geometry of the optical system for this embodiment are given in
FIG. 10. The axis 102 of the illumination system is angled to the area of
view. It is at an angle 104 of 30.degree. to the axis 101 perpendicular to
the area of view. The mirror is at angle 116 of 15 to the perpendicular to
the area of view. The axis of the detection system 103 is a)so angled to
the area of view. The angle 105 is 45.degree.. The long axis or length of
the area of view 107 is 5.40 mm-5.70 mm.
CHARACTER CAPACITY OF SCANNER MEMORY
Bit-mapped image codes representative of a given character are transformed
into ASCII or other codes in a computer. It can be seen that as processors
and memory become smaller and cheaper this function may be performed
within the housing of the self-contained hand-held scanner of FIG. 4b. In
such an embodiment individual characters may be stored temporarily in
bit-mapped form as described herein above and are then transformed into
and accumulated in ASCII form. Since many more characters may be stored in
a given block of memory in ASCII form than may be stored in bit-mapped
form, the character capacity of the scanner is increased significantly.
PHOTO DIODE MOUNTING
Commercially available diode arrays having integral amplification are too
large to fit within the confines of a housing that is not substantially
greater than 1 inch (2.54 cm) across so that it may be pen-like.
Accordingly, the diode array and the amplifier are mounted in separate
packages. The center to center spacing between adjacent photo diodes is
chosen to be between 0.0800 mm and 0.0868 mm for similar reasons.
FULL FIELD OF VIEW
The first embodiment of the scanner of the present invention allows the
user to view an unobstructed | | |
