U.S. patent application number 12/621218 was filed with the patent office on 2010-03-11 for garage door operator having thumbprint identification system.
This patent application is currently assigned to THE CHAMBERLAIN GROUP, INC.. Invention is credited to James J. Fitzgibbon, Mark L. Karasek.
Application Number | 20100060413 12/621218 |
Document ID | / |
Family ID | 29406332 |
Filed Date | 2010-03-11 |
United States Patent
Application |
20100060413 |
Kind Code |
A1 |
Fitzgibbon; James J. ; et
al. |
March 11, 2010 |
Garage Door Operator Having Thumbprint Identification System
Abstract
A movable barrier operator having thumbprint identification in
either a remote radio frequency transmitter, or a receiver/barrier
operator system or both is provided. A control circuit with a
non-volatile memory receives thumbprint information from a
fingerprint detector device and stores the information, identifying
an authorized user. On subsequent operation of the fingerprint
detector, a fingerprint data set is received in the control circuit
and an attempt is made to match the incoming data with previously
stored data thus establishing the identify of the user according to
highly reliable biometric principles. As an option, a variety of
different actions can be taken based upon the perceived identity of
a particular individual, as well as the type of device
communicating with the receiver/barrier operator.
Inventors: |
Fitzgibbon; James J.;
(Batavia, IL) ; Karasek; Mark L.; (Lombard,
IL) |
Correspondence
Address: |
FITCH EVEN TABIN & FLANNERY
120 SOUTH LASALLE STREET, SUITE 1600
CHICAGO
IL
60603-3406
US
|
Assignee: |
THE CHAMBERLAIN GROUP, INC.
Elmhurst
IL
|
Family ID: |
29406332 |
Appl. No.: |
12/621218 |
Filed: |
November 18, 2009 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
09735141 |
Dec 12, 2000 |
7642895 |
|
|
12621218 |
|
|
|
|
60172677 |
Dec 20, 1999 |
|
|
|
Current U.S.
Class: |
340/5.53 |
Current CPC
Class: |
G07C 2009/00793
20130101; G07C 9/00817 20130101; B60R 25/25 20130101; G07C
2009/00849 20130101; G07C 2009/00928 20130101; G07C 9/00182
20130101; B60R 25/00 20130101; B60R 25/305 20130101; B60R 25/252
20130101; G07C 9/00563 20130101 |
Class at
Publication: |
340/5.53 |
International
Class: |
G06F 7/04 20060101
G06F007/04 |
Claims
1.-9. (canceled)
10. A finger print access control which effects operation of a
movable barrier operator which movable barrier operator moves a
barrier and which barrier controls access to a secure area, the
finger print access control comprising: a fingerprint communicating
unit disposed outside the secure area and remote from a barrier
movement operator inside the secure area, the fingerprint
communicating unit comprising: a fingerprint sensor disposed
outside the secure area which generates finger print code
representative of a finger print and a signal representative of the
fingerprint; a transmitter controller which combines the finger
print code representing the fingerprint with a separate rolling
access code to provide a changing combined authorization code and a
changing combined authorization code signal representative of the
changing combined authorization code, which separate rolling access
code is configured to effect access to the secured area by active
communication with a rolling code acceptance apparatus and, which
separate rolling access code changes without regard to the time of
the active communication but which change is effected as a result
of each combined signal transmission in accordance with an
algorithm to produce the changing combined authorization code and
changing combined authorization code signal which is representative
of the separate rolling access code and the finger print code; a
transmitter which emits the changing combined authorization code
signal representative of a sensed fingerprint from the fingerprint
sensor and the separate rolling access code; and the barrier
movement operator comprising: a receiver inside the secure area
which receives the changing combined authorization code signal
representative of the separate rolling access code and the sensed
fingerprint, the receiver having a learning mode in which a portion
of the combined authorization code signal which is representative
of the sensed fingerprint emitted by the transmitter is received by
the barrier movement operator and stored in a memory thereof; a
fingerprint circuit disposed inside the secure area and responsive
to the received changing combined authorization code signal, the
fingerprint circuit configured to decode the portion of the
changing combined authorization code signal to identify the portion
of the changing combined code signal representing the sensed
fingerprint and configured to determine whether the portion of the
signal representing the sensed fingerprint is representative of an
authorized user, the finger print circuit effective for receiving
the changing combined authorization code signal, separating the
portion of the received changing combined authorization code signal
representative of the sensed fingerprint from the separate rolling
access code, and reading the stored signal representative of the
sensed finger print to verify authorized users without transmitting
a signal to the transmitter; the rolling code acceptance apparatus
inside the secured area and configured to determine whether the
separate rolling access code is acceptable after the fingerprint
circuit verifies the authorized user; and a barrier operator
circuit which commands a barrier to assume a particular position
when the sensed fingerprint is determined to be from an authorized
user and the separate rolling access code is determined to be
acceptable.
11. The movable barrier operator system according to claim 10
wherein the fingerprint sensor comprises an optical fingerprint
sensor.
12. The movable barrier operator system according to claim 11
wherein the optical fingerprint sensor is an electroluminescent
fingerprint sensor.
13. The movable barrier operator system according to claim 11
wherein the fingerprint sensor comprises a charged coupled device
for generating a signal from which the signal representative of the
sensed fingerprint is produced.
14. The movable barrier operator system according to claim 10
wherein the transmitter comprises a radio frequency transmitter and
the signal representative of the sensed fingerprint is a radio
frequency signal, the radio frequency transmitter configured to
send a combined radio frequency authorization code signal.
15. The movable barrier operator system according to claim 10
wherein the transmitter comprises a wall control.
16. The movable barrier operator system according to claim 10
further comprises a memory associated with the fingerprint sensor
and the transmitter for storing information indicative of the
fingerprint.
17. The movable barrier operator system according to claim 10
wherein the fingerprint circuit compares a coded identification
transmission for operation of the barrier operator circuit.
18. The movable barrier operator system according to claim 10
wherein the separate rolling access code has a fixed code portion
and a rolling code portion, the rolling code portion changing as a
result of each combined signal transmission in accordance with an
algorithm.
19. A transmitter device which effects signals to a moveable
barrier operator which responsively moves a barrier as a result of
receiving the signals from the transmitter device, the transmitter
comprising: a transmit only transmitter; and a fingerprint sensor,
the transmitter configured to transmit a signal representative of a
combination of a finger print code representing a fingerprint and a
separate rolling access code which combination and signal
representative of the combination changes as a result of each
combined signal transmission in accordance with a predetermined
algorithm and without regard to the time of the signal
transmission.
20. The transmitter device according to claim 19 wherein the device
further includes a transmitter controller which combines the finger
print code representing the fingerprint with a separate rolling
access code to provide a changing combined authorization code and a
changing combined authorization code signal representative of the
changing combined authorization code.
21. The transmitter device according to claim 20 wherein the
separate rolling access code is configured to effect access to the
secured area by active communication with a rolling code acceptance
apparatus and, which separate rolling access code changes without
regard to the time of the active communication but which change is
effected as a result of each combined signal transmission in
accordance with a predetermined algorithm to produce the changing
combined authorization code and changing combined authorization
code signal which is representative of the separate rolling access
code and the finger print code.
22. The transmitter device according to claim 19 wherein the
transmit only transmitter is a wireless transmitter configured to
wirelessly transmit the signal representative of the combination of
the fingerprint and the separate rolling access code to a receiver
inside the secured area.
23. The transmitter device according to claim 22 wherein the device
further includes a transmitter controller which combines the finger
print code representing the fingerprint with a separate rolling
access code to provide a changing combined authorization code and a
changing combined authorization code signal representative of the
changing combined authorization code, and wherein the separate
rolling access code is configured to effect access to the secured
area by active communication with a rolling code acceptance
apparatus in the secured area and, which separate rolling access
code changes without regard to the time of the active communication
but which change is effected as a result of each combined signal
transmission in accordance with a predetermined algorithm to
produce the changing combined authorization code and changing
combined authorization code signal which is representative of the
separate rolling access code and the finger print code.
24. The transmitter device according to claim 23 wherein the
separate rolling access code has a fixed code portion and a rolling
code portion, the rolling code portion changing as a result of each
combined signal transmission in accordance with an algorithm.
25. A method for controlling a moveable barrier operator, the
method comprising: generating a signal and code representative of a
sensed fingerprint from a fingerprint sensor disposed outside the
secure area; combining the code representing the sensed fingerprint
with a separate rolling access code with a transmitter controller
outside the secured area to provide a changing combined
authorization code; changing combined authorization code signal
which includes the signal representative of the sensed finger print
and the separate rolling access code, which separate rolling access
code is configured to effect access to the secured area by active
communication with a rolling code acceptance apparatus and which
separate rolling access code changes in accordance with a
predetermined algorithm to produce the changing combined
authorization code signal which changes with each encoded signal
transmission and which separate rolling access code changes without
regard to the time of the active communication but which change is
effected as a result of each combined signal transmission in
accordance with an algorithm to produce the changing combined
authorization code signal; wirelessly emitting with a transmitter
outside the secured area the changing combined authorization code
signal representative of the sensed fingerprint from the
fingerprint sensor and the separate rolling access code; receiving
the changing combined authorization code signal representative of
the sensed fingerprint and separate rolling access code with a
receiver inside the secured area, the receiver having a learning
mode in which the signal representing a fingerprint emitted by the
transmitter is received by the barrier movement operator and stored
in a memory; determining whether a portion of the changing combined
authorization code signal representing the sensed fingerprint is
representative of an authorized user with a fingerprint circuit
disposed inside the secure area, the finger print circuit
responsive to the received changing combined authorization code
signal for decoding the changing combined authorization code signal
to identify the signal representing the sensed fingerprint, the
finger print circuit effective for receiving a finger print
identifying signal representative of the sensed finger print,
separating the received combined signal representative of the
sensed fingerprint from the separate rolling access code, and
reading the stored signal representative of a finger print to
verify authorized users without transmitting a signal to the
transmitter; determining whether the separate rolling access code
is acceptable after the fingerprint circuit verifies the authorized
user to effect access to the secured area with the rolling code
acceptance apparatus inside the secured area; and commanding a
barrier operator to assume a particular position with a barrier
operator circuit when the sensed fingerprint is determined to be
from an authorized user and the separate rolling access code is
determined to be acceptable.
26. The method according to claim 25 wherein the fingerprint sensor
comprises an optical fingerprint sensor.
27. The method according to claim 26 wherein the optical
fingerprint sensor is an electroluminescent fingerprint sensor.
28. The method according to claim 25 wherein the fingerprint sensor
comprises a charged coupled device for generating a signal from
which the signal representative of the sensed fingerprint is
produced.
29. The method according to claim 25 wherein the transmitter
comprises a radio frequency transmitter and the signal
representative of the sensed fingerprint is a radio frequency
signal.
30. The method according to claim 25 wherein the separate rolling
access code has a fixed code portion and a rolling code portion,
the rolling code portion changing as a result of each combined
signal transmission in accordance with an algorithm.
31. A finger print access control which effects operation of a
movable barrier operator which movable barrier operator moves a
barrier and which barrier controls access to a secure area, the
finger print access control comprising: a fingerprint communicating
unit disposed outside the secure area and remote from a barrier
movement operator inside the secure area, the fingerprint
communicating unit comprising: a fingerprint sensor disposed
outside the secure area which generates finger print code
representative of a finger print and a signal representative of the
fingerprint; a transmitter controller which combines the finger
print code representing the fingerprint with a separate rolling
access code to provide a changing combined authorization code and a
changing combined authorization code signal representative of the
changing combined authorization code, which separate rolling access
code is configured to effect access to the secured area by active
communication with a rolling code acceptance apparatus and, which
separate rolling access code changes without regard to the time of
the active communication but which change is effected as a result
of each combined signal transmission in accordance with a
predetermined algorithm to produce the changing combined
authorization code and changing combined authorization code signal
which is representative of the separate rolling access code and the
finger print code; a wireless transmitter which wirelessly emits
the changing combined authorization code signal representative of a
sensed fingerprint from the fingerprint sensor and the separate
rolling access code; and the barrier movement operator comprising:
a receiver inside the secure area which receives the changing
combined authorization code wireless signal representative of the
separate rolling access code and the sensed fingerprint, the
receiver having a learning mode in which a portion of the combined
authorization code signal which is representative of the sensed
fingerprint emitted by the transmitter is received by the barrier
movement operator and stored in a memory thereof; a fingerprint
circuit disposed inside the secure area and responsive to the
received changing combined authorization code signal, the
fingerprint circuit configured to decode the portion of the
changing combined authorization code signal to identify the portion
of the changing combined code signal representing the sensed
fingerprint and configured to determine whether the portion of the
signal representing the sensed fingerprint is representative of an
authorized user, the finger print circuit effective for receiving
the changing combined authorization code signal, separating the
portion of the received changing combined authorization code signal
representative of the sensed fingerprint from the separate rolling
access code, and reading the stored signal representative of the
sensed finger print to verify authorized users without transmitting
a signal to the transmitter; the rolling code acceptance apparatus
inside the secured area, the rolling code acceptance apparatus
configured to determine whether the separate rolling access code is
acceptable; and a barrier operator circuit which commands a barrier
to assume a particular position when the sensed fingerprint is
determined to be from an authorized user and the separate rolling
access code is determined to be acceptable.
32. The transmitter device according to claim 31 wherein the
wireless transmitter is a radio frequency transmitter and the
separate rolling access code has a fixed code portion and a rolling
code portion, the rolling code portion changing as a result of each
combined signal transmission in accordance with an algorithm.
33. A transmitter device which effects operation of a movable
barrier operator which movable barrier operator moves a barrier and
which barrier controls access to a secure area, the transmitter
device comprising: a fingerprint communicating unit disposed
outside the secure area and remote from a barrier movement operator
inside the secure area, the fingerprint communicating unit
comprising: a fingerprint sensor disposed outside the secure area
which generates finger print code representative of a finger print
and a signal representative of the fingerprint; a transmitter
controller which combines the finger print code representing the
fingerprint with a separate rolling access code to provide a
changing combined authorization code and a changing combined
authorization code signal representative of the changing combined
authorization code, which separate rolling access code is
configured to effect access to the secured area and which separate
rolling access code changes without regard to the time of the
active communication but which change is effected as a result of
each combined signal transmission in accordance with an algorithm
to produce the changing combined authorization code and changing
combined authorization code signal which is representative of the
separate rolling access code and the finger print code; and a
transmit only transmitter which emits the changing combined
authorization code signal representative of a sensed fingerprint
from the fingerprint sensor and the separate rolling access
code.
34. The transmitter device of claim 33 wherein the transmitter is a
wireless transmitter which is configured to wirelessly transmit the
changing combined authorization code signal to effect entry into a
secured area.
Description
[0001] This application is a continuation of application Ser. No.
09/735,141 which was filed on Dec. 12, 2000 entitled GARAGE DOOR
OPERATOR HAVING THUMBPRINT IDENTIFICATION SYSTEM, which application
Ser. No. 09/735,141 claimed the benefit of U.S. Provisional
Application No. 60/172,677, filed Dec. 20, 1999, both applications
are incorporated by reference as if fully rewritten herein.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The invention relates, in general, to movable barrier
operators and, in particular, to garage door operators having
systems for receiving data trans-missions that are encoded or
encrypted to identify one or more authorized users, optionally
without regard to the particular transmitter employed.
[0004] 2. Description of the Related Art
[0005] The garage door of many homes is controlled by a garage door
opening system which protects against unwanted uses by means of
electronically transmitted and received access codes. The access
code systems now available provide a sufficient level of security
so that for many homeowners the garage door is one of the primary
means of entering and exiting the house. Home convenience and
protection equipment such as garage door operators, lighting
systems and security systems are coming to be viewed as necessities
and not merely luxuries. These systems are often controlled by
transmitters providing a radio frequency signal carrying coded
information. For security, the coded information must be kept
secret and can, for example, be taken from a large number of
possible codes. For convenience, the transmitters and receivers
they control should be simple to program.
[0006] Various controller systems have been proposed and/or
manufactured using digital radio control and digital system
processing, and allowing codes to be established by the user or
randomly generated. In one system, a unique code is established at
the transmitter using a number of two-position switches. The remote
receiver also has a like number of switches to set, the established
code. For further information on the structure and operation of
such a system, reference may be made to U.S. Pat. No. 29,525 to
Willmott. In U.S. Pat. No. 4,178,549 to Ledenbach et al., the
receiver recognizes a received signal from a particular transmitter
by measuring and comparing relative durations of the pulse and
non-pulse time intervals. Other systems have been proposed which do
not require the user to set the code by operating switches on the
transmitter and receiver. In one system, a random code generator at
the receiver establishes the code. The new code is placed in the
memory of a transmitter by holding the transmitter in proximity to
the receiver which flashes the established code by means of a light
emitting diode to a phototransistor in the transmitter. In another
system, each transmitter has its own unique code. The receiver can
store up to five unique codes. Should a transmitter be lost or
stolen, the code for that transmitter can easily be removed from
the memory of the receiver. For further information concerning the
structure and operation of such systems, reference may be made to
U.S. Pat. Nos. 4,529,980 to Liotine et al., and 4,750,118 to
Heitschel et al., respectively.
[0007] Garage door operators have become more sophisticated over
the years, providing users with increased convenience and security.
However, further improvements are sought, such as ease of
establishing the identity to the user to be granted access by
either the receiver or transmitter component of a garage door
operating system. Improvements for increasing the ease with which a
user can generate data needed to set up a transmitter or receiver
are continuously being sought. Further advantages have been sought
in improving the ease with which a user can generate data
identifying the user as one authorized to operate a transmitter, a
receiver, or other components of a garage door operator control
system. Further, it is desirable that the data developed by the
user be suitable for encoding in a practical manner.
SUMMARY OF THE INVENTION
[0008] The invention relates in general to garage door operator
systems for controlling an actuator in response to receiving an
authorized and especially a coded authorized transmission. The
apparatus includes a fingerprint device which identifies an
individual as being authorized to transmit a coded signal which,
when detected by a receiver within radio frequency range, will
decode the transmitter signal, recognizing the code and energizing
the receiver so as to actuate a garage door operator.
[0009] A need exists for a door operator system with enhanced
security features which automatically limits access to authorized
users, thereby providing protection to the homeowner if the garage
door transmitter should become lost or stolen. In order to be
commercially successful, such systems must not have their
convenience or usefulness degraded as by requiring the homeowner to
perform lengthy and difficult setup procedures.
[0010] This need is met and an advance in the art is achieved with
the present invention, in which a garage door transmitter/actuating
receiver system stores both transmitter-specific and thumbprint or
other fingerprint identification data for use by the garage door
actuator and its related control system.
[0011] In one embodiment, the transmitter responds to received
thumbprint data and activates its transmission output stage only
when a received thumbprint data set matches a stored thumbprint
data set. Thus, the transmitter is able to provide a high level of
security and automatic protection while requiring a user to merely
perform a single "keypress" motion with the thumb. Accordingly,
should the transmitter become lost or stolen, any attempt to
operate the transmitter by unauthorized individual will
automatically be ignored with a high degree of security.
[0012] With a simple thumbpress, an authorized user causes the
control system associated with the garage door actuator to receive
authorized security codes, which may be made specific to a
particular user. The actuator control system responds to received
access codes and activates the door only when a received code
matches a stored valid code.
[0013] In one embodiment, a transmitter permits activation of a
garage door control system by transmitting data containing a
rolling portion and a fixed code portion. The data includes an
indication of which authorized user initiated transmission, and it
is possible to take action uniquely reserved for that particular
individual. For example, in a two car family having a multiple car
garage, the correct garage door will "automatically" respond to the
individual operating the transmitter. In addition, only certain
members of the household can, via their thumbprint, be granted
access to learning or programming features of a garage door control
system.
BRIEF DESCRIPTION OF THE DRAWINGS
[0014] FIG. 1 shows a garage door and operator system embodying the
present invention;
[0015] FIG. 2 is a schematic diagram of a hand-held transmitter
operating system of the garage door operator and system shown in
FIG. 1;
[0016] FIG. 3 is a schematic diagram of a wall-mounted transmitter
operating system of the of the garage door operator and system
shown in FIG. 1;
[0017] FIG. 4 is a schematic diagram of a barrier operator system
according to principles of the present invention;
[0018] FIG. 5 is a schematic diagram of a transmitter according to
principles of the present invention;
[0019] FIG. 6 is a schematic diagram of a LEARN system for the
barrier operator of FIG. 4;
[0020] FIG. 7 shows the fingerprint device of FIG. 4 in greater
detail;
[0021] FIG. 8 is a schematic diagram showing the receiver of FIG. 4
in greater detail;
[0022] FIG. 9 is a schematic diagram of another transmitter device
according to principles of the present invention;
[0023] FIG. 10 is a schematic diagram of another wall mounted
transmitter device according to principles of the present
invention;
[0024] FIG. 11 is a schematic diagram of another barrier operator
device according to principles of the present invention;
[0025] FIG. 12 is a schematic diagram of a transmitter device of
FIGS. 9-11;
[0026] FIG. 13 is a schematic diagram of a LEARN function of the
barrier operator of FIG. 11;
[0027] FIG. 14 is a schematic diagram of the fingerprint device of
FIG. 11; and
[0028] FIG. 15 is a schematic diagram showing the receiver of FIG.
11 in greater detail.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0029] Referring now to the drawings and especially to FIG. 1, a
garage door operator system embodying the present invention is
generally indicated at 10, and includes a head unit 12 mounted
within a garage 14. More specifically, the head unit 12 is mounted
to the ceiling of the garage 14 and includes a rail 18 extending
therefrom with a releasable trolley 20 attached having an arm 22
extending to a multiple paneled garage door 24 positioned for
movement along a pair of door rails 26 and 28. The system includes
a hand-held transmitter unit 30 adapted to send signals to an
antenna 32 positioned on the head unit 12 and coupled to a receiver
incorporated in the head unit 12. An external control pad 34 is
positioned on the outside of the garage having one or more buttons,
windows or the like devices thereon and communicates via radio
frequency transmission with antenna 32 located at the head unit 12.
A control module 39 is mounted on a wall of the garage. The control
module 39 may be connected to the head unit by a pair of wires, but
is preferably radio-linked via an antenna 39a. The control module
39 includes a light switch 39b, a lock switch 39c and a command or
LEARN switch 39d. A protective system is employed with an optical
emitter 42 connected via a power and signal line 44 to the head
unit. An optical detector 46 is connected via a wire 48 to the head
unit 12.
[0030] Two embodiments of systems for garage door operator control
will be discussed. These systems include provision for establishing
highly reliable user identity codes with a minimum of effort by the
user. A first system is shown in FIGS. 1-8, with FIGS. 2, 3 and 4
showing transmitter and receiver modules employed in the
system.
[0031] FIG. 2 shows a schematic diagram of a module (i.e., car or
hand-held) transmitter 100 of the type generally identified in FIG.
1 by reference numeral 30. Transmitter 100 has an input in the form
of a conventional fingerprint device 102 and an output in the form
of an antenna 104 radiating radio frequency information.
Preferably, the data outputted from transmitter 100 is in the form
of a sequence of trinary code digits, including both trinary
rolling code digits and trinary fixed code digits described in
commonly assigned U.S. Pat. No. 5,949,349, the disclosure of which
is herein incorporated by reference. The present invention can also
be employed with less rigorous security systems employing, for
example, only fixed code data formats.
[0032] Data information from the fingerprint device 102 is sent to
the control circuit 108 which is preferably, but not necessarily,
embodied as a special purpose integrated circuit. The control
circuit 108 outputs data to the radio frequency circuit 106.
[0033] The fingerprint device 102 preferably includes a window
against which a user's thumb is pressed. The thumbprint is used to
provide biometric identification data unique to the user's anatomy.
Although fingerprint data can be taken from any digit of the user's
hand, it is generally preferred that the biometric identification
information employed in the present invention be taken from one of
the user's thumbs, as this simplifies the image processing to be
performed.
[0034] Preferably, the fingerprint device contains a window of
conductive rubber and especially rubber impregnated with graphite.
The window is coated with an electroluminescent material which
illuminates to emphasize the ridges on the surface of a user's
thumb. The illuminated ridge pattern is scanned by an inexpensive
CCD camera. A mapping of the thumbprint ridges is stored in
temporary memory. The thumbprint image data is then digitized
according to a predetermined pattern, and a thumbprint data set
comprising a predetermined number of data points, is extracted.
Preferably, the fingerprint device employed is offered for sale by
Who? Vision Systems, Inc., a unit of XL Vision, Inc. of Sebastian,
Fla. under the designation TACTILESENSE Fingerprint module.
[0035] The data points of the sensed thumbprint image are compared
against stored sets of thumbprint data resident in a non-volatile
memory either in the fingerprint device, the transmitter or the
received barrier operator. In the first embodiment, thumbprint data
set matching is carried out in a receiver/barrier operator system
140 to be described below in FIG. 4. This results in a
substantially reduced cost for the fingerprint device in that
non-volatile memory and circuitry to perform comparison is not
required.
[0036] The fingerprint device 102 outputs the digitized thumbprint
data points to the control circuit 108 on the line 110. Preferably,
the control circuit 108 performs only simple line level and pulse
squaring functions on the incoming data from the fingerprint device
102 but does not perform interpretation functions thereon. The
output of the control circuit 108 is in digital pulse form and is
fed to the RF circuit 106. In the preferred embodiment, the
information passed through the RF circuit 106 and radiated by the
antenna 104 is preferably of the trinary rolling code data type
having both rolling code and fixed code digits. The information
digits in both rolling code and fixed code format are generated in
the control circuit 18 in the manner described in commonly assigned
U.S. Pat. No. 5,949,349, the disclosure of which is herein
incorporated by reference. It is generally preferred that the
control circuit 108 combine the aforementioned data with a code
indicating the type of transmitter (i.e., mobile transmitter)
radiating the data to a receiver system. If desired, the device
code information can also include unique identifiers, similar to
the information afforded by a serial number system.
[0037] FIG. 3 shows a wall mounted transmitter system 120. As can
be seen by comparison with FIG. 2, the wall mounted transmitter
system 120 has the same schematic form as the hand-held transmitter
system 100, but preferably includes a device code different from
that of other types of hand-held and other transmitter devices.
Wall mounted transmitter 120 corresponds to the control device 39,
shown in FIG. 1.
[0038] Although not described in detail herein, it should be
understood that the wall-mounted transmitter system 120 can also be
employed as a keyless entry system, corresponding to the control
pad 34 in FIG. 1, mounted outside of the garage structure.
Previously, control devices of this type were provided with a
number of key switches such as a numeric keypad which a user would
manipulate according to a memorized key code sequence. With the
present invention, a user's thumbprint is all that is required in a
single "key press" type of manipulation.
[0039] Referring again to FIG. 3, the antenna 104 and the RF
circuit 106 are the same as employed in FIG. 2. The control circuit
124 of the system 120 may of two types, one similar to the control
circuit 108 described above and the other containing the addition
of an optional non-volatile memory containing additional
information to be transmitted through the RF circuit 106 and
radiated from the antenna 104. Preferably, as with the hand-held
transmitter system 100, the wall-mounted transmitter 120 sends
device identification codes through the RF circuit and transmitter,
identifying the sending unit as a wall-mounted transmitter
component. If multiple wall-mounted transmitters are operated in
the same vicinity, additional identification codes can be provided
to identify the particular wall-mounted transmitter being activated
by a user's thumbprint.
[0040] Referring now to FIG. 4, a receiver/barrier operator system,
generally indicated at 140, includes control capability to energize
a motor in the head unit 12 so as to impart an opening or closing
movement to the movable barrier such as a gate or the garage door
24. The logical functions preformable by the barrier operator 140
are invoked, using a number of different transmitter or hard-wired
sending devices. A receiving antenna 144 directs radiated radio
frequency information to radio frequency receiver 146 which
preferably performs simple pulse forming or other "data cleaning"
operations on the received information, sending the "raw" data on
the line 148 to the control circuit 150. If desired, the radio
frequency receiver 146 can provide a simple "pass-through" of the
data directly to the control circuit 150. In the preferred
embodiment, hard-wired sending devices are employed in the LEARN
mode of operation.
[0041] As mentioned, in the preferred embodiment, the information
transmitted and received is in the form of both rolling code and
fixed code. The control circuit 140 performs the necessary
interrogation of the data and confirms if the signal received is
authorized with respect to the rolling code, according to commonly
assigned U.S. Pat. No. 5,949,349. If the received data were in a
more simple form, for example, solely in a fixed code form, the
control circuit 150 would perform the necessary data interrogation
to determine if the coded information corresponds to that of a
valid transmitter.
[0042] In a second aspect, the control circuit of the barrier
processes fingerprint data arranged in the form of a structured
thumbprint data set. As indicated in FIG. 4, control circuit 150
includes non-volatile memory, which is provided for storing
previously acquired thumbprint data sets corresponding to different
authorized users. The control circuit 150 performs a match-seeking
comparison between the incoming thumbprint data set and previously
stored or LEARNED thumbprint data sets. If a match is found, and
optionally if rolling code authentication is proven, then a user's
request is translated into appropriate control signals sent on a
line 160 to a motor 162 which in turn imparts an opening or closing
motion to the garage door as required. A photo beam system with an
emitter 42 and a detector 46 send appropriate permissive or
blocking signals on input line 172 to the control module 150. Other
types of interactive accessories can also be employed with the
control system, if desired.
[0043] In a further mode of operation, barrier operator system 140
is employed to LEARN (i.e., save a user's thumbprint. In its
simplest form, an appropriate LEARN command signal is communicated
to control circuit 150 instructing the control circuit to receive
fingerprint identification data on the line 178 and to store the
data in non-volatile memory within the control circuit. If desired,
thumbprint data integrity checks can also be performed by the
control circuit 150 before storing the received thumbprint data
set. As will be seen in the second embodiment, the LEARN command
can also be sent by the remote RF-linked transmitters. Preferably,
for security purposes, the command to LEARN, i.e., identify and
store in non-volatile memory a thumbprint data set, is communicated
by a hard-wired LEARN button 180 which preferably is in the form of
a dedicated key switch. In order to store a thumbprint data set for
later recognition in the barrier operator 140, a user would issue a
thumbpress to the fingerprint device 102 while simultaneously
pressing the LEARN button 180. In this manner, incoming fingerprint
data is routed on the line 178 to the LEARN port of the control
circuit 150, rather than the fingerprint data input port connected
to the line 156. As will be seen herein, the LEARN mode is also
employed to store both fingerprint and rolling code data as
transmitted via RF data signals into the non-volatile memory of the
control circuit.
[0044] Before proceeding to a detailed explanation of various
operating modes of the garage door operating system, it should be
mentioned that the barrier operator system 140 shown in FIG. 4 can
be located in the head unit 12 of FIG. 1, if desired. This may be
preferred in certain instances because of manufacturing and cost
control advantages, especially since designs have already been
developed providing radio receiving functions in the head unit, as
shown above with reference to FIG. 1. However, with the user
authentication provisions associated with the present invention,
and in particular the LEARN mode requiring use of a fingerprint
device dedicated to the barrier operator, it may be convenient to
provide an additional wall-mounted unit. At a minimum, it is
anticipated that the fingerprint device 102 and the LEARN button
180 be conveniently located in this wall-mounted position, with the
remainder of the barrier operator 140 located in the head unit 12
shown in FIG. 1. It is contemplated, in this regard, that the
fingerprint data lines 156, 178 and the line connecting LEARN
button 180 to the control circuit 150 be hard wired, or optionally
radio-linked, to the head unit.
[0045] Referring now to FIG. 5, operation of either transmitter 100
or 120 is shown in greater detail. While the respective transmitter
is energized, the fingerprint window is continuously scanned to
detect if the user's thumb is pressed against the device, as
indicated in step 184. Once a finger press is detected, control is
transferred to step 186 in which the fingerprint data received from
fingerprint device 102 is combined with the rolling code data in
control circuit 108 of FIG. 2 or control circuit 1124 of FIG. 3.
The combined data is then transmitted in step 188 as a radio
frequency signal, preferably one having a sequence of multiply
formatted digits. Any conversion of data to the radio frequency
regime is carried out in either the control circuit or the radio
frequency circuit of the transmitter.
[0046] Referring now to FIG. 6, the LEARN procedure for the barrier
operator of FIG. 4 will now be described. Beginning with a step
200, the control circuit 150 polls an input line 202 to determine
if the LEARN switch 180 is depressed. Upon detection of a key press
at the LEARN switch 180, the LEARN mode is set within control
circuit 150 as indicated by step 206 and is confirmed in step 208.
As indicated above, the present invention provides heretofore
unattainable convenience by requiring a user to only execute a
simple thumbpress to provide the necessary individual data input to
the barrier operator system. In the LEARN mode, the system expects
a thumbpress at fingerprint device 102 of FIG. 4 (causing a data
transmission therefrom) concurrent with actuation with LEARN switch
180. Accordingly, program control is transferred to a step 210 to
confirm that thumbpress information has been processed by the
fingerprint device 102 and the output data is being communicated on
the line 178 to an appropriate input port of the control circuit
150 (see FIG. 4). As mentioned above, the present invention also
contemplates that fingerprint data may be transmitted via a radio
frequency communications link and, in the absence of thumbpress
data from the fingerprint device 102 in FIG. 4, control is
transferred to a step 212 to determine if RF data is being received
by the antenna 144 and the RF receiver 146.
[0047] In order to carry out step 212, it is preferred that the
control device 150 poll the input line 148 during the LEARN
operation. If radio frequency data and thumbpress data are not
detected by the control circuit 150, control is transferred to a
step 216 to determine if a "LEARN mode timer" located within the
control circuit 150 has expired. If so, control is transferred to a
step 218 to clear the LEARN mode flag previously set. Control is
then transferred to the step 200, thus requiring the user to
release and re-actuate the LEARN switch 180 to initiate further
processing of the LEARN mode.
[0048] If the control circuit 150 detects fingerprint data on the
line 178 in the step 210, control is transferred to the step 222
which directs the incoming fingerprint data on the line 178 to be
stored into the next non-volatile memory location internal to the
control circuit 150. A step 222 contains routines to verify that
the thumbprint data on the line 178 is properly formatted and
within a predetermined range of values. As an added feature, in the
step 222, previously stored fingerprint data can be compared to
determine if there is a match with the newly acquired fingerprint
data. Action can then be taken to alert the user as to duplication
of data, if desired.
[0049] Assuming a thumbpress is not detected in the fingerprint
device 102 of the barrier operator system shown in FIG. 4, control
is transferred to the step 212, as indicated above. Assuming valid
radio frequency data is being received on the line 148, control is
transferred to the step 226.
[0050] As indicated in FIG. 4, it is generally preferred that the
two input lines, 156, 178, be provided between the fingerprint
device 102 of FIG. 4 and control circuit 150. Although operation of
the LEARN procedure shown in FIG. 6 can be accomplished with a
single input line 156, it is generally preferred for system
security purposes, that a separate dedicated line 18 be provided
for LEARN mode operation.
[0051] In a step 226, the incoming RF data signals are interrogated
for valid format, it being generally preferred that the incoming
coded information be provided in multiple portions (e.g., a rolling
code portion and a fixed code portion) according to commonly
assigned U.S. Pat. No. 5,949,349 which, as mentioned, is
incorporated as if fully set forth herein.
[0052] As previously indicated, in the step 186 (see FIG. 5) the
fingerprint data, i.e., the thumbpress data set, is combined with
rolling code data, either the rolling code portion thereof or the
fixed code portion thereof. In the step 222 the incoming radio
frequency data is disassembled and after various formatting tests
and other verification procedures, the thumbprint data set
information is identified and stored in the next open volatile
memory location internal to the control circuit 150. The remaining
rolling code data is also stored in non-volatile memory within
control circuit 150, either with the disassembled thumbpress data
set, or in a separate memory location.
[0053] The LEARN mode is then cleared and program control is
transferred to the step 208 for confirmation. In normal operation,
control is then transferred to the polling step 200.
[0054] Turning now to FIG. 7, NORMAL (i.e., non-LEARN) operation of
the barrier operator system 140 of FIG. 4 will now be described. It
should be understood that the NORMAL operation indicated in FIG. 7
is concurrently active with the LEARN procedure shown in FIG. 6.
Accordingly, in a step 230 the determination is made if the LEARN
mode has been "set", i.e., made active. A flag within control
circuit 150 is employed for this purpose. A "true" response in the
step 230 indicates that the LEARN switch 180 has been depressed as
indicated in the step 200 (see FIG. 6) and the LEARN mode flag has
accordingly been set in the step 206 (also shown in FIG. 6). If the
LEARN mode has been determined to have been set in the step 230,
the LEARN mode flag internal to the control circuit is continuously
polled until it is determined that the LEARN mode is no longer
active.
[0055] Control is then transferred to the step 234 to determine if
a user is carrying out a thumbpress operation. In the step 234 the
thumbpress being detected can come from a variety of sources,
including the fingerprint device in the barrier operator system 140
shown in FIG. 4, the mobile transmitter 100 (either installed in a
vehicle or hand held) or the wall mounted transmitter 120 shown in
FIG. 3. If the thumbpress is being carried out by an RF
transmitter, RF data verification and identification according to
step 226 (see FIG. 6) is carried out within the step 234.
[0056] A thumbpress detected in the step 234 indicates that a
thumbpress data set is being sent to the barrier operator system
140. In the step 236 determination is made as to whether the
received fingerprint data matches, within tolerance limits, one of
the LEARNED fingerprint data sets stored in non-volatile memory in
control circuit 150. A match in step 236 indicates that the
identity of an authorized user has been confirmed with a high level
of confidence according to biometric identification principles. The
user's control request is then transferred to a step 238 to perform
am appropriate change in operator state internal to the control
circuit 150. This in turn triggers internal routines to send an
appropriate control signal on the line 160 to the motor 162 to
physically carry out the user's request with respect to movement of
the garage door. In addition, in a step 238 it is preferred that a
flag be set within the control circuit 150 to ignore the photobeam
systems 42, 46, an optional feature which allows a user to
"override" damaged photo beam systems. If desired, a step 238 could
be modified so as to allow the photo beam protectors 42, 46 to
continue to operate autonomously to provide either a permissive
signal, an absence of a blocking signal, or a blocking signal on
line 172 to control circuit 150.
[0057] Control is then transferred to a step 242 to wait until the
thumbpress is released from the fingerprint device. According to
the preferred mode of a step 242, a user's command, is carried out
when thumb pressure is relieved from the fingerprint device being
actuated. If desired, radio frequency transmitted requests can be
made redundant, i.e., set at the transmitter to repeat a limited
predetermined number of times proven sufficient to ensure that a
properly operating transmitter/receiver set are able to complete
the necessary radio frequency communications. Alternatively, data
can be continuously transmitted from the radio frequency
transmitter which is remote from the barrier operator system.
Control is then transferred to a step 244 which clears the ignore
obstacle detection flag and control is thereafter passed to the
polling step 230.
[0058] As mentioned above, it is contemplated that NORMAL operation
of the barrier operator system can also be carried out at points
spaced from the transmitter, via remotely transmitted signals. With
reference to FIG. 1 the signals can come from a mobile transmitter,
either resident within a vehicle or hand held, a communication
panel located on the outside of the garage structure or a wall
mounted communication panel located within the garage or house to
which the garage is associated. With reference to FIG. 8, operation
of the barrier operator/receiver system 140 of FIG. 4 will now be
described.
[0059] In a step 250, the incoming line 148 in FIG. 4 is
continuously polled to determine if an RF data signal is being
received at the control circuit 150. Upon detection that RF data is
present on the line 148 and received in the control circuit 150,
control is transferred to the step 252 to separate the combined
fingerprint data and remainder of the rolling data. In a step 252
the fingerprint data portion is analyzed to determine if it matches
previous thumbprint data sets stored in non-volatile memory in
circuit 150. It is contemplated that, in a step 254 the criteria
for a match between data sets does not require complete identity of
data but rather contemplates that there is some tolerance, i.e.,
some degree of non-identity between the newly detected thumbpress
data set and the previously stored thumbpress data set(s). If a
match is not detected in the step 254, control is transferred to
the polling step 250.
[0060] Upon indicating that a satisfactory fingerprint match has
been detected in the step 254, control is transferred to the step
256 where analysis of the incoming data is performed to determine
if a satisfactory device match has been detected. As mentioned
above, it is preferred that the transmitting devices either hard
wired or coupled through radio frequency communication links
include device identification data to indicate at a minimum the
type of sending device employed. For example, it may be desirable
to carry out different operations when a user is located within a
garage structure rather than a vehicle located on a nearby street
or driveway. In particular, there has been found a need to provide
emergency "override" features should part of the overall system
become damaged.
[0061] One area of concern has been raised when photo beam obstacle
detectors become damaged in a manner such that further physical
operation of the garage door is blocked by the supervising control
circuit. It is desirable in such instances to provide the user with
an opportunity when located at a wall-mounted transmitter within
the garage to invoke commands to the supervising control circuit
while neglecting indications of the photo beam protector circuit.
An example of this type of operation is provided in a step 260, as
will be discussed below. Thus, it is frequently necessary to
provide additional analysis of the incoming data, and suitable
analyses are therefore indicated as being performed on the
remainder of the incoming "rolling data", i.e., the remainder of
the rolling code data being transmitted. In a step 256, reference
is made to "matched LEARNED devices". The step 256 accordingly
contemplates that each device connected to the overall system be
initialized or "LEARNED" thereby requiring the supervising control
circuit (herein assumed to be located in the operator
barrier/receiver system 140 of FIG. 4. Once a device has been
interrogated and authenticated by a supervisory control circuit,
the required device identification data, or "LEARNED device" data
is stored in non-volatile memory for subsequent match-seeking
comparisons with incoming data, as may be required. As mentioned
above, the device identity data preferably includes at a minimum a
pre-arranged code identifying the type of device as defined by the
system manufacturer. Alternatively, the device identification data
can include a code or other information uniquely identifying the
particular device involved, thus providing information similar to
that offered by various serial number systems.
[0062] In a step 258 the device type data portion of the rolling
data is interrogated to determine if the device is wall mounted. An
example of a particular wall mounted transmitter device was
described above with respect to FIG. 3. It is assumed that any
necessary validation of the device type data has been previously
carried out in a step 256. If the sending device is determined to
be wall mounted, i.e., located internal to the garage structure,
the "ignore protector" flag internal to the supervising control
circuit is set in a step 260 and control is then passed to a step
262, otherwise control is transferred directly to the step 262. In
the step 262 the validity (and optionally level the of authority of
the user) is determined with a high degree of confidence and in the
step 262 the user's request is converted into an appropriate change
of state of the operator as determined by control circuit 150 with
the necessary control signals being sent on the line 160 to the
motor 162 (see FIG. 4). In a step 264 further operation is halted
until the RF data signal has ended. Control is then passed to a
step 266 in which the ignore obstacle detector flag is cleared and
control is thereafter passed to the polling step 250.
[0063] Referring now to FIGS. 9-15, a second embodiment of the
present invention will now be described. One feature of the second
embodiment is that match-seeking comparison operations are carried
out at the transmitter device to determine if incoming fingerprint
data is that of a previously authorized user. Thus, if the
transmitter should become lost or stolen or otherwise fall into
unauthorized hands, transmitter functions can be immediately
blocked.
[0064] Referring first to FIG. 9, a mobile transmitter, either
vehicle mounted or hand held, is indicated at 500. The transmitter
500 is similar to the aforementioned mobile transmitter 100 except
that certain features in a control circuit 502 are added to those
features described above with respect to the control circuit 108.
Previously learned thumbprint data sets that have been stored are
used to identify respective individual users.
[0065] The transmitter 500, unlike the transmitter 100, has a LEARN
mode of operation in which thumbpress data information is analyzed
and, if validly determined in a LEARN mode, is stored in
non-volatile memory in the fingerprint device 504 of the
transmitter. The LEARN node of operation for the transmitter will
be described in detail with reference to FIG. 12. Fingerprint
device 504 contains circuitry to perform a match-seeking comparison
between incoming thumbpress data information and previously learned
or stored thumbpress data information. The output on line 110 going
to control circuit 502 has a number of different possible features.
For example, the output of fingerprint device 504 can simply
indicate that a match has occurred, can additionally add
information as to the current user's identity and, if desired, can
also transmit the incoming thumbpress data set information to the
control circuit. Since non-volatile memory is provided in the
fingerprint device 504, as described above, the control circuit 502
need not be provided with non-volatile memory if a simpler, less
expensive commercial embodiment is desired. However, at times,
additional functionality is required, and accordingly the control
circuit of the transmitter in FIG. 9 can be provided with
non-volatile memory to perform functions other than biometric or
thumbprint data matching. For example, in control circuit 502,
non-volatile memory can be provided to store various data received
from another control circuit indicating the device type and
optionally the particular device of the transmitter involved, and
this can be stored with the entire set of fingerprint data
transmitted from the active fingerprint device 102.
[0066] Referring now to FIG. 10, a wall mounted transmitter is
generally indicated at 510 and is similar in certain respects to
the transmitter 120 described above. Wall mounted transmitter 510
includes a fingerprint device 504 which includes non-volatile
memory for match-seeking comparison purposes. Therefore, control
circuit 512 need not have non-volatile memory if a more cost
effective commercial embodiment is required. The data output of
fingerprint device 504 is transmitted to control circuit 512 and,
with the addition of any coded information, is passed to RF circuit
106 for radiated transmission from antenna 104.
[0067] As with the transmitter 500, it is preferred that
transmitter 510 include an identification code indicating the type
of transmitter device (i.e., wall mounted as opposed to mobile) and
optionally can also include coded information identifying the
unique transmitter device employed (similar to the information
provided by a serial number system).
[0068] Referring now to FIG. 11, barrier operator system 530 shares
similar features with the barrier operator system described above
with reference to FIG. 4. For example, radio frequency signals are
accepted by antenna 144, operated upon by RF receiver circuit 146
and transmitted to control circuit 536 via input line 148. A
fingerprint device 504 is connected to control circuit 536 via two
input lines, the first input line 156 being reserved for NORMAL
operation and the second input line 178 being reserved for LEARN
mode of operation. A LEARN button 180 is connected by line 202 to
control circuit 536 and photo beam protectors 42, 46 are connected
to control circuit 536 by input line 172. On verification of the
user's identify, optional authorization level, on valid formatting
of user's instructions, control circuit 536 transmits suitable
instructions to motor 162 via line 160.
[0069] Referring now to FIG. 12, the preferred LEARN procedure for
either transmitter 500 or 510 will be described. In step 540 a
fingerprint device 504 is continuously polled for presence of a
thumbpress. When a thumbpress is received, control is transferred
to step 542 which determines if a LEARN mode of operation has been
made active. For example, a dedicated button can be provided with
either transmitter 500 or 510 or the fingerprint device 504 can be
programmed to recognize two or more short pressure pulses or as
unusually long sustained "pulse" applied to the fingerprint device
as a pre-arranged method of triggering a LEARN mode signal
transmitted to the respective control circuit 502 or 512. In any
event, if the LEARN mode is made active, control is transferred to
step 544 where the thumbprint is LEARNED, i.e., a digital
thumbprint data set representative of the thumbprint image is
stored in a next available non-volatile memory location, with
control then being passed to polling step 540.
[0070] If the LEARN mode is not active as determined by step 542,
control is transferred to step 548 where determination is made as
to whether the incoming fingerprint data constitutes, within
tolerance limits, a "match" with a previously learned thumbprint
data set. If a match, within tolerance is not observed, control is
transferred to polling step 540.
[0071] If the thumbprint data set is matched in step 548 to a
previously learned thumbpress data set, then control is transferred
to step 552 where the match is identified to sub-portions of the
control circuit 502 or 512. Control is then transferred to step 554
in which the control circuit 502 or 512 outputs a radio frequency
data signal indicating that a match has occurred. The radio
frequency data signal, as mentioned above, can indicate simply that
a match has been made, can additionally indicate the previously
stored identity for the particular thumbprint data set (e.g., user
number 1, user number 2 or user number 3) and, in addition, the
thumbprint data set itself can be incorporated in the RF data
signal. In step 554, any required properly formatted instruction
set is combined with the RF data signal, and such combination is
preferably made in rolling code format according to previously
assigned U.S. Pat. No. 5,949,349. Control is then transferred to
the polling step 540.
[0072] Referring now to FIG. 13, the preferred LEARN mode of
operation for the barrier operator system of FIG. 11 is described.
As indicated in FIG. 13, the first step 600 the control circuit 536
polls input line 602 to determine if the LEARN switch 180 is
depressed. Upon detection of a key press at switch 180, the LEARN
mode is set within control circuit 536 as indicated by step 606 and
is confirmed in step 608. As indicated above, the present invention
provides heretofore unattainable convenience by requiring a user to
only execute a simple thumbpress to provide the necessary
individual data input to the barrier operator system. In the LEARN
mode, the system expects a thumbpress at fingerprint device 102 of
FIG. 11 (causing a data transmission therefrom) concurrent with
actuation with LEARN switch 180. Accordingly, program control is
transferred to step 610 to confirm that thumbpress information has
been processed by fingerprint device 102 and the output data is
being communicated on line 178 to an appropriate input port of
control circuit 536 (see FIG. 11). As mentioned above, the present
invention also contemplates that fingerprint data may be
transmitted via a radio frequency communications link and, in the
absence of thumbpress data from the fingerprint device 102 in FIG.
11, control is transferred to step 612 to determine if RF data is
being received by antenna 144 and RF receiver 146.
[0073] In order to carry out step 612, it is preferred that control
device 536 poll the input line 148 during the LEARN operation. If
radio frequency data and thumbpress data is not detected by control
circuit 536, control is transferred to step 616 to determine if a
"LEARN mode timer" internal within control circuit 536 has expired.
If so, control is transferred to step 618 to clear the "LEARN mode"
previously set. Control is then transferred to step 600, thus
requiring the user to release and re-actuate the LEARN switch 180
to initiate further processing of the LEARN mode.
[0074] If the control circuit 536 detects fingerprint data on line
178 in step 610, control is transferred to step 622 which directs
the incoming fingerprint data on line 178 to be stored into the
next non-volatile memory location internal to control circuit 536.
Step 622 contains routines to verify that the thumbprint data on
line 178 is properly formatted and within a predetermined range of
values. As an added feature, in step 622, previously stored
fingerprint data can be compared to determine if there is a match
with the newly acquired fingerprint data.
[0075] Assuming a thumbpress is not detected in fingerprint device
102 of the barrier operator system shown in FIG. 11, control is
transferred to step 612, as indicate above. Assuming radio
frequency data, proven to be valid, is being received on line 148,
control is transferred to step 626.
[0076] In step 626, the incoming RF data signals are interrogated
for valid format, it being generally preferred that the incoming
coded information be provided in multiple portions (e.g., a rolling
code portion and a fixed code portion) according to commonly
assigned U.S. Pat. No. 5,949,349 which, as mentioned, is
incorporated as if fully set forth herein. As previously indicated,
in step 186 (see FIG. 5) the fingerprint data, i.e., the thumbpress
data set, is combined with rolling code date, either the rolling
code portion thereof or the fixed code portion thereof. In step 622
the incoming radio frequency data is disassembled and after various
formatting tests and other verification procedures, the thumbprint
data set information is identified and stored in the next open
volatile memory location internal to control circuit 536. The
remaining rolling data is also stored in non-volatile memory within
control circuit 536, either with the disassembled thumbpress data
set, or in a separate memory location.
[0077] The LEARN mode is then cleared and program control is
transferred to step 608 for confirmation. In normal operation,
control is then transferred to the polling step 600.
[0078] Turning now to FIG. 14, NORMAL (i.e., non-LEARN) operation
of the barrier operator system 530 of FIG. 11 will now be
described. It should be understood that the NORMAL operation
indicated in FIG. 14 is concurrently active with the LEARN
procedure shown in FIG. 13. Accordingly, in step 630 the
determination is appropriately made to determine if the LEARN mode
has been "set", i.e., made active. A "true" response in step 630
indicates that the LEARN switch 180 has been depressed as indicated
in step 600 (see FIG. 13) and the LEARN mode has accordingly been
set in step 606 (also shown in FIG. 13). If the LEARN mode has been
determined to have been set in step 630, a LEARN mode flag internal
to the control circuit is continuously polled until it is
determined that the LEARN mode is no longer active.
[0079] Control is then transferred to step 634 to determine if a
user is carrying out a thumbpress operation. In step 634 the
thumbpress being detected can come from a variety of sources,
including the fingerprint device in the barrier operator system 530
shown in FIG. 11, the mobile transmitter 100 (either installed in a
vehicle or hand held) or the wall mounted transmitter 120 shown in
FIG. 3. If the thumbpress is being carried out by an RF
transmitter, RF data verification and identification according to
step 626 (see FIG. 13) is carried out within step 634.
[0080] A thumbpress detected in step 634 indicates that a
thumbpress data set is being sent to barrier operator system 530.
In step 636 determination is made as to whether the received
fingerprint data, within tolerance limits, matches one of the
learned fingerprint data sets stored in non-volatile memory in
control circuit 536. A match in step 636 indicates that, according
to biometric identification principles, the identity of an
authorized has been confirmed with a high level of confidence. The
user's control request is then transferred to step 638 to perform
am appropriate change in operator state internal to control circuit
536. This in turn triggers internal routines to send an appropriate
control signal on line 160 to motor 162. In addition, in step 638
it is preferred that a flag be set within control circuit 536 to
ignore the photo beam protectors 42, 46. If desired, step 638 could
be modified so as to allow the photo beam protectors 42,46 to
continue to operate autonomously to provide a permissive signal, in
absence of a blocking signal, or a blocking signal on line 172 to
control circuit 536.
[0081] Control is then transferred to step 642 to wait until the
thumbpress is released from the fingerprint device. In step 642, a
user's command is carried out when thumb pressure is relieved from
the fingerprint device being actuated. If desired, radio frequency
transmitted requests can be set at the transmitter to repeat a
limited predetermined number of times, prove insufficient to ensure
that a properly operating transmitter/receiver set are able to
carry out the necessary radio frequency communications.
Alternatively, data can be continuously transmitted from the radio
frequency transmitter remote to the barrier operator system.
Control is then transferred to step 644 which clears the "ignore
protector" flag and control is thereafter passed to the polling
step 630.
[0082] As mentioned above, it is contemplated that NORMAL operation
of the barrier operator system can also be commended via remotely
transmitted signals. As indicated in FIG. 1 the signals can come
from a mobile transmitter, either resident within a vehicle or hand
held, a communication panel located on the outside of the garage
structure or a wall-mounted communication panel located within the
garage or house to which the garage is associated.
[0083] Referring now to FIG. 15, NORMAL operation of the barrier
operator receiver of FIG. 11 will now be described. In a first step
650, incoming line 148 in FIG. 11 is continuously polled to
determine if an RF data signal is being received at control circuit
536. Upon detecting that RF data is present on the line 148 and
received in the control circuit 536, control is transferred to a
step 652 to separate the combined fingerprint data and remainder of
the rolling data. In a step 654 the fingerprint data portion is
analyzed to determine if it matches previous thumbprint data sets
stored in non-volatile memory in circuit 536. We have contemplated
that, in step 654 the criteria for a match between data sets does
not require complete identity of data but rather contemplates that
some tolerance, i.e., some degree of non-identity between the newly
detected thumbpress data set and the previously stored thumbpress
data set(s). If a match is not detected in the step 654, control is
transferred to the polling step 650.
[0084] Upon indicating that a match has been detected in the step
654, control is transferred to the step 656 where the so-called
"rolling data", i.e., the remainder of the rolling code data
transmitted, is deemed as acceptable for the data sets previously
learned, and stored within the control circuit 536. Preferably, in
the step 656 a matching operation is carried out for the rolling
data, comparing the incoming rolling data set to previously stored
device data sets. As previously mentioned, it is generally
preferred that each unit sending instructions to the barrier
operator system 530 include or generate a code which identifies the
type and optionally also the unique identify of the sending
device.
[0085] In a step 658 the device type data portion of the rolling
data is interrogated to determine if the device is wall-mounted. An
example of a wall mounted device was described above with respect
to FIG. 3. It is assumed that any necessary validation of the
device type data has been previously carried out in the step 656.
If the sending device is determined to be wall mounted, i.e.,
located internal to the garage structure, the ignore obstacle
detector flag is set in a step 660 and control is then passed to a
step 662, otherwise control is transferred directly to step 662. In
the step 662 the validity and optional level of authority of the
user is determined with a high degree of confidence. In the step
662 the user's request is converted into an appropriate change of
state of the operator as determined by the control circuit 536 and
the necessary control signals are sent on the line 160 to the motor
162 (see FIG. 11). In the step 664 further operation is halted
until the RF data signal has ended. Control is then passed to the
step 666 in which the ignore obstacle detector flag is cleared and
control is thereafter, passed to the polling step 650.
[0086] As has been noted above, the garage door operator control
system according to principles of the present invention includes
provisions for learning, i.e., recognizing and saving various types
of information, including individual user's identity (via biometric
information) and device information, (both by type and by
individual device identity). Certain procedures have been described
for carrying out the LEARN mode. In addition to these,
consideration has been given to the following methods of learning
critical information, according to principles of the present
invention.
[0087] As a first method, enablement of the LEARN mode is
automatically established upon initial contact with the wall
control unit or other previously designated device. Alternatively,
the LEARN mode can be enabled upon the first contact with a
recognized serial port device.
[0088] As a second general method for initiating LEARN mode, the
first person accessing the transmitter with a thumbpress is
designated as the key user who identifies other people to be
LEARNED by the system, by pressing a dedicated button and placing
their finger onto the fingerprint device.
[0089] As a third learning method, the LEARN mode can be set upon
initial bidirectional communication with the supervisory control
circuit via a radio frequency link. The LEARN mode can be initiated
from the remote transmitter device by sending an initial LEARN code
to the supervisory control circuit in the receiver unit.
[0090] As a fourth learning mode, a special learning session is
instituted upon entering a special dealer code into the supervisory
control circuit. In this learning method, the control circuit is
programmed to await the next user to access the system,
automatically entering the user identification data in the
afore-described LEARN modes of operation.
[0091] The drawings and the foregoing descriptions are not intended
to represent the only forms of the invention in regard to the
details of its construction and manner of operation. Changes in
form and in the proportion of parts, as well as the substitution of
equivalents, are contemplated as circumstances may suggest or
render expedient; and although specific terms have been employed,
they are intended in a generic and descriptive sense only and not
for the purposes of limitation, the scope of the invention being
delineated by the following claims.
* * * * *