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BACKGROUND OF THE INVENTION
The use of symbols or labels which comprise bar codes as a means for
identifying data which is used in processing items sold in the retail
industry, and for other purposes as well, has been widely accepted. A
particular bar code, known as the Universal Product Code (UPC), has been
established as the industry standard for the grocery and other related
retail industries. In a multiple bar code, such as the UPC, each decimal
number or character is represented by two pairs of vertical bars and
spaces within a seven-bit pattern wherein a binary one bit is represented
by a dark module or bar of a predetermined width and a binary zero is
represented by a light module or space. Thus, for example, the decimal or
character one may be represented in the UPC code by the seven-bit pattern
0011001. In keeping with the format, the decimal one would be comprised of
an initial space of a two-bit width, followed by a two-bit wide bar,
another two-bit space and a one-bit wide bar. For each character or
decimal of the system, there are two bars and two spaces which have a
total width of seven modules or bits. The width of each of the bars or
spaces which comprise a character may be one, two, three or four modules
wide, so long as the sum of the bars and spaces is seven bits or modules
wide.
In present day merchandise checkout systems, the use of optical scanners or
readers for scanning the UPC labels on purchased merchandise items has
become quite common. In the checkout systems in use today, the optical
reader can take the form of a reader mechanism located in a checkout
counter, or the form of a hand-held wand. In either case, the optical
reader will scan the bar code pattern that forms the UPC label, and will
generate signals representing the bars and spaces of the pattern for
transmission to a processor which determines the character represented by
the bar code pattern. The character which identifies the purchased items
is then transmitted to an associated data terminal device and from there
to a remote or back office processor which looks up the price of the item
in a table located in the processor. The price is then transmitted back
through the terminal device, where the price is printed on a receipt by a
printer mechanism located in the terminal device, and then to a customer
display member located adjacent to the checkout counter where the price of
the item is displayed. If an error occurs due to a malfunction of the
printer or if the price of the item is not listed in the price-lookup
table, error signals are generated, notifying the operator to take
appropriate actions to correct the situation.
Means are customarily provided for altering error signals and other signals
generated by the reader, and for altering other functions of the reader.
For example, due to ambient noise conditions, it may be desirable to alter
the volume, frequency or duration of an audible signal indicating that an
acceptable scanning operation has been performed on the symbol being
scanned.
In the past, the alteration of such functions has often involved the
services of an equipment technician, since such alterations customarily
involved operations of some complexity, such as the changing of switch
settings within the reader, or by the making of software changes, which
would differ depending upon the type of reader which was attached to the
system.
It would be desirable to provide a method for alteration of reader
functions which is simple and effective and does not require the services
of a technician for accomplishment.
SUMMARY OF THE INVENTION
This invention relates to a method for changing the functions of a bar code
reader, and more particularly relates to such a method which uses the
scanning of bar codes to effect such changes.
In accordance with one embodiment of the invention, a method for changing a
function of a bar code reader, which is capable of reading data code
symbols, by reading of a bar code reader function symbol, comprises the
following steps: scanning a bar code symbol; determining whether the
scanned bar code symbol has been properly sensed; determining whether a
properly sensed bar code symbol possesses a certain characteristic which
identifies it as not being a data code symbol; determining whether a
sensed bar code symbol which is not a data code symbol is a bar code
reader function symbol; identifying the specific reader function encoded
in a sensed bar code reader function symbol; and performing the encoded
function.
It is accordingly an object of the present invention to provide a simple,
effective method for changing the functions of a bar code reader.
Another object is to provide a method for changing the functions of a bar
code reader which involves sensing a bar code reader function symbol.
Another object is to provide a method for changing the functions of a bar
code reader which involves sensing a bar code reader function symbol,
distinguishing said bar code reader function symbol from a data code
symbol, determining the legitimacy of said bar code reader function
symbol, and changing the function of the bar code reader in accordance
with the information contained in the bar code reader function symbol.
With these and other objects, which will become apparent from the following
description, in view, the invention includes certain novel features of
construction and combinations of parts, and of a process, a preferred form
or embodiment of which is hereinafter described with reference to the
drawings which accompany and form a part of this specification.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a flow diagram illustrating the method for changing the functions
of a bar code reader.
FIG. 2 is a block diagram of a bar code reader.
FIGS. 3A to 3F inclusive are representations of various bar code reader
function symbols.
FIG. 4 is a fragmentary perspective view of the mechanical elements of a
bar code reader.
FIG. 5 is a block diagram of a system including a bar code reader, a point
of sale terminal and a main processor.
FIG. 6 is a representation of a UPC data symbol.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring now to FIG. 5, there is shown a block diagram of a checkout
system which may embody the present invention. This system includes a bar
code reader 20 for scanning a coded label on a purchased merchandise item
and for generating coded signals representing the identity of the
purchased item. These signals are transmitted over a communications link
22 to a terminal device 24, shown here as a point of sale terminal, which
in turn transmits the signals over a further communications link 26 to a
main processor 28. The processor 28, utilizing the signals received,
determines the price of the purchased item from a price look-up table
stored in the processor 28. The numerical data representing the price is
transmitted over the communications link 26 to the terminal device 24
which prints the price on a receipt. The data may also be transmitted over
the communications link 22 to the reader 20 which actuates a customer
display to display the price of the item purchased to the customer. The
bar code reader is not limited to use in merchandise systems, as it may be
used in a wide variety of other applications, such as the checking in and
out of library books and other materials, for example.
Referring now to FIG. 4, there is shown a perspective view of the
mechanical structure of the bar code reader 20 which includes a scanner
assembly generally indicated by the numeral 30, comprising a light source
32 emitting an optical scanning light beam 34 in the visible or near
visible spectrum, the light beam being directed through an aperture 36
located in a supporting surface 38 of a checkout counter 40. The light
source 32 may be a helium or neon laser that is pumped to produce a
continuous laser beam of red monochromatic light of approximately 6,328
angstrom wave length.
In a manner that is well-known in the art, the light beam 34 produced by
the source 32 may be focused by a lens system 42 onto a multi-faced mirror
44. The mirror 44 is mounted on the shaft 46 of a motor 48 which rotates
the mirror 44 at a substantially constant speed. The mirror 44 is
positioned to intercept the light beam 34 and projects the same through
the aperture 36 to scan the encoded indicia on a label 50 (FIG. 6) fixed
to a merchandise item 52. As shown in FIG. 6, the encoded data on the
label 50 comprises a plurality of black coded areas 53 and white coded
areas 55 representing data concerning the identity of the merchandise
item. The rotation of the mirror 44 causes a succession of light beams 34
to scan any encoded label 50 positioned over the aperture 36.
The light beam is reflected off the label 50 through an optical filter 54
to a photo-responsive pick-up device such as a photo-multiplier 56 which
converts the reflected light beam into electrical signals, the amplitude
of which correspond to the amounts of light received. Thus, the amplitude
of the light reflected from the white coded areas 55 on the label 50 (FIG.
6) will be greater than the light reflected from the black coded areas 53.
Conventional amplifying circuits will produce a relatively high voltage
which can be assigned a binary one value when the beam 34 is scanning a
black coded area 53 on the label and a relatively low voltage which can be
assigned a binary zero value when the beam 34 is scanning a white coded
area 55. Thus, the information contained on the label 50 can be decoded
and used as an input to a processor for use in generating the price of the
purchased item 52.
Referring now to FIG. 2, shown there is a partial block diagram of the bar
code reader 20. The reader 20 includes the scanner assembly 30, a
microprocessor 62 for checking and decoding the encoded data read by the
scanner assembly 30, a conventional memory storage unit 64, an output
buffer unit 66 for transmitting the data read by the scanner assembly 30
over the communication link 22 to a processor unit (not shown) in the POS
terminal 24, a tone generator 68 and light indicators 70.
When the scanner assembly 30 reads a label 50 on a merchandise item 52
which is positioned adjacent the aperture 36, the serial data read is
transmitted to the microprocessor 62. The microprocessor 62 will decode
and check the received serial data to determine if the data is valid or
not, will then generate control signals indicating a good or a bad read,
and will transmit such signals to the tone generator 68 and to the light
indicators 70 to cause said tone generator 68 and said light indicators 70
in the bar code reader 20 to be operated to provide appropriate indication
to the operator of the terminal.
For a more detailed description of the bar code reader 20 and the bar code
which is read, reference may be had to the following U.S. patents, which
are assigned to the assignee of the present application: U.S. Pat. Nos.
4,253,018, issued Feb. 24, 1981; 4,272,675, issued June 9, 1981;
4,275,380, issued June 23, 1981; 4,282,426, issued Aug. 4, 1981;
4,287,507, issued Sept. 1, 1981; and 4,679,154, issued July 7, 1987.
As has been previously stated, in the present invention, the bar code
reader 20 may also be used to read bar code labels which do not contain
merchandise identification information, but instead contain information
which is effective to alter certain functions performed by the bar code
reader 20. It will be seen that the entry of function altering information
or commands into the reader 20 by means of a scanning operation rather
than by altering switch settings or reprogramming the reader 20 provides
substantial advantages from the standpoint of time required and
simplicity.
Referring to FIGS. 3A to 3F inclusive, shown there are six bar code labels
80, 82, 84, 86, 88 and 90, respectively, which, for example, may be used
to perform six different changes in function of the bar code reader 20.
Examination of these six labels which will hereinafter be collectively
referred to as the function labels, and comparison of them with the
merchandise identification label 50 of FIG. 6, will disclose certain
common features, and certain areas of difference. For example, both the
function labels and the merchandise identification label have a guard bar
comprising two narrow dark bars with an intervening light space at both
the left and right margins of the label. Both have a number system
character comprising a light space and a relatively wide dark bar at the
left side of the label inward from the left guard bar. Both have two
five-digit character groupings with a center band pattern positioned
therebetween. In the examples, the left character grouping comprises the
same five characters (1 2 3 4 5) for all seven labels, although this would
usually not be the case.
The difference between the function labels 80, 82, 84, 86, 88 and 90 on the
one hand and the merchandise identification label 50 on the other hand,
which enables the bar code reader 20 to distinguish between function
labels and merchandise identification labels, resides in the character
immediately to the left of the right-hand guard bar in all of these
labels. In the merchandise identification label 50, this is a modulo check
character, which is calculated in accordance with the other data
characters included in the label to produce a check digit so that a
mathematical operation involving all of the characters sensed from the
label, including the check character, will always produce a final result
having a certain characteristic. For example, the Universal Product Code
employs a modulo 10 check for merchandise identification labels.
The function labels, on the other hand, are designed in terms of their
character values so that they will not pass a modulo 10 check. In these
labels, the character immediately to the left of the right-hand guard bar,
in the same relative position as the module check character of the
merchandise identification label, is used as part of the data which
determines the particular function to be performed. In the labels
illustrated in FIGS. 3A to 3F inclusive, this character is a 5 in FIG. 3A,
a 4 in FIG. 3B, a 3 in FIG. 3C, a 2 in FIG. 3D, a 1 in FIG. E and a 0 in
FIG. 3F.
Clearly the microprocessor 62 of the bar code reader 20 can be programmed
to cause any suitable function to be altered in response to the reading of
a given function character. Examples of functions which may be assigned to
various function labels are tabulated below.
______________________________________
LIST OF SPECIAL FUNCTION SYMBOLS
Function
UPC Version "A"
Label Symbol No. Function
______________________________________
80 012345000095 Reader Reset or make
function changes
permanent.
82 012345000094 Enter Diagnostic Mode.
Exit by power down or
reset symbol.
84 012345000093 Bad Tone Frequency
Adjustment. Each scan
will increase the bad
tone frequency. There
are eight different
frequencies. Frequency
will increase to
highest and next scan
will set to lowest.
86 012345000092 Good Tone Frequency
Adjustment. Each scan
will increase the good
tone frequency. There
are eight different
frequencies. Frequency
will increase to the
highest and next scan
will set to lowest.
88 012345000091 Good Tone Length
Adjustment. Each scan
will cause good tone
length to increase by
15 milliseconds in the
range of 0-225
milliseconds.
90 012345000090 Bad Tone Length
Adjustment. Each scan
will cause bad tone
length to increase by
15 milliseconds in the
range of 0-225
milliseconds.
______________________________________
In the above listing, the bad tone and good tone frequency adjustments and
the length adjustments relate to the tone generator 68 of FIG. 2.
It should be noted that the above list should not be construed as a
complete list. Many other functions of a bar code reader or other
apparatus could be controlled by a function symbol, such as enabling or
disabling of the capability of reading different bar codes, changing bar
code decode algorithms, and changing host interface logic to allow
communication with a multitude of different host systems.
The bar code reader 20 can store the various function settings in a
non-volatile memory, such as a battery-backed random access memory or an
electrically erasable or programmable read only memory, in order to allow
removal of power from the reader 20 while still maintaining the correct
function settings.
Shown in FIG. 1 is a flow diagram representing the process through which
functions of the bar code reader may be changed by scanning function
labels such as those shown in FIGS. 3A to 3F inclusive.
Commencing with the start of the operation, which is represented by block
100, a function symbol, such as the symbol contained in label 80, is
sensed by the scanning assembly 30 of the bar code reader 20. A
determination is then made, as represented by block 102, as to whether or
not a UPC symbol has been read, using criteria based upon UPC code
standards. If not, the process returns to the start block 100.
Assuming that the reader 20 determines that a UPC symbol has been read, the
reader 20 then examines the data scanned from the label which was read and
determines whether the symbol passes a modulo 10 check and is therefore a
legitimate merchandise identification symbol, as represented in block 104.
If so, the reader 20 provides to the operator an indication that a good
symbol reading has taken place, the data representing the symbol is sent
to the terminal 24, as represented in block 106, and the process returns
to the start block 100.
If the symbol does not pass the mod 10 check in block 104, the process
continues to block 108, in which a determination is made as to whether or
not the symbol being read is a reader function symbol, using criteria
based upon common characteristics of the reader function codes. If the
symbol is not a proper reader function code, the reader 20 provides to the
operator an indication of this, as represented by block 110, and the
process returns to the start block 100.
If the symbol being read is determined to be a proper reader function
symbol, the process continues, as represented in block 112. The reader 20
performs the selected function, and indicates the reader's acceptance of
this function to the operator by an appropriate indication, such as an
audible tone, or the use of indicating lights. The process then returns to
the start block 100, so that the reader 20 is prepared for sensing of the
next symbol.
While the form of the invention illustrated and described herein is
particularly adapted to fulfill the objects aforesaid, it is to be
understood that other and further modifications within the scope of the
following claims may be made without departing from the spirit of the
invention.
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