Computer graphics processing and selective visual display system – Display peripheral interface input device – Including keyboard
Reexamination Certificate
2000-06-27
2003-09-16
Saras, Steven (Department: 2675)
Computer graphics processing and selective visual display system
Display peripheral interface input device
Including keyboard
C345S169000, C341S026000
Reexamination Certificate
active
06621484
ABSTRACT:
TECHNICAL FIELD
The present invention relates generally to keypad or keyboard data input devices (collectively referred to herein as “keyboards”) used with general purpose computers and in a wide variety of application specific electronic devices, e.g., appliances, tools, calculators, etc. The invention has particularly useful application in connection with keyboards, e.g., computer keyboards, employing printed membrane switch structures.
BACKGROUND OF THE INVENTION
To a large extent, the computer industry has settled on using a n×m matrix of sense lines/drive lines for carrying out keyboard key switch discrimination. Such a matrix provides a means for an integrated circuit (IC) micro-controller device to decode (n×m) keyboard keys, with (n+m) electrical interface pins. The micro-controller device sequentially drives a voltage on a plurality of drive lines of the matrix. Keyboard key depression will effect a closure of an associated switch creating an electrical connection between a particular drive line and one of a plurality of sense lines, with the result that the micro-controller device will detect this voltage on the sense line and determine therefrom a corresponding alphanumeric character or function.
Typically, a membrane switch structure is used to form the keyboard key switch matrix. Referring to
FIG. 1
, a conventional computer keyboard
1
may utilize a conventional membrane switch structure
3
, as shown in
FIG. 2
, which is installed underneath a set of keyboard keys
5
. Membrane switch structure
3
generally has three layers
7
,
9
and
11
. Outer layers
7
and
11
sandwich intermediate layer
9
. The three layers are generally made out of a thin insulative sheet of polyester (e.g., Mylar™) or other insulative material. Outer layers
7
and
11
each have, on their respective opposing inside surfaces
13
and
15
, switch circuit patterns (
17
and
19
, respectively) which may be printed (e.g., silk-screened).
Circuit patterns
17
and
19
are appropriately laid out to provide contact points and lines of conduction for each of keyboard keys
5
, within a conventional key switch matrix. The circuit patterns may be printed with suitable conductive inks, e.g., a polymer-based conductive ink having silver and/or carbon particles in suspension. Typically, each keyboard key
21
is coupled to a resilient or spring loaded plunger
23
positioned to make contact with a backside of upper outer layer
7
of membrane switch structure
3
. Depression of selected ones of keyboard keys
5
causes a corresponding plunger
23
to exert pressure on upper outer layer
7
. The resulting pressure causes a portion of electrical circuit
17
(e.g., a sense line) printed on the inner face of layer
7
to come resiliently into electrical contact with a portion of circuit
19
(e.g., a drive line) printed on the inner face of bottom outer membrane layer
11
. This contact occurs through contact apertures
24
(one shown) provided in intermediate layer
9
. The electrical contact allows passage of a drive signal on a particular sense line for input to an IC micro-controller device. By recognizing the sense line on which the signal is generated, and the timing of the appearance of the generated signal on the sense line, the IC can discriminate which of keyboard keys
5
has been depressed. The micro-controller device, in turn, provides a digital output signal readable by an associated computer.
FIG. 3
schematically illustrates a conventional arrangement of a computer keyboard switch circuit matrix
25
electrically connected with an IC die package
27
(typically mounted within the keyboard housing). In the conventional arrangement, a total of 17 drive lines
29
extend from IC die package
27
to corresponding drive lines
31
of switch circuit matrix
25
. Drive lines
31
are laid-out in intersecting relationship with a total of eight sense lines
33
. As previously described, and shown in
FIG. 2
, the drive lines are typically arranged on a first outer layer of a membrane switch structure, and the sense lines are typically arranged on a second outer layer of a membrane switch structure. This conventional arrangement requires IC die package
27
to accommodate a total of twenty-five (8+17=25) pin connections
35
spaced about the periphery of die package
27
, for the signal (drive and sense) lines alone. Additional pin connections (not shown) must also be provided, e.g., for V
cc
, Gnd, Osc, HostData and HostClk.
A silicon chip
37
centrally located within die package
27
contains IC logic (including the micro-controller device) for carrying out keyboard key discrimination and related functions. The logic circuitry integrated onto chip
37
is small relative to the available surface area of chip
37
and the high levels of integration attainable with available photolithographic IC fabrication techniques. A much smaller chip (and hence less silicon) could be utilized if it were not for the fact that a certain minimum size of chip
37
is required in order to accommodate pin connections
39
about the periphery of chip
37
. Also, the area of chip
37
is small relative to the overall size of die package
27
, due to the relatively large space requirements for making the pin connections
35
on the outer periphery of die package
27
, as well as pin connections
39
located around the periphery of chip
37
. But for the space required to accommodate the large number of required pin connections, the size of die package
27
could be reduced considerably, thus reducing the printed circuit board space required within the keyboard for accommodating die package
27
. In addition, a reduction in the number of pin connections would reduce the materials, and manufacturing costs associated with making, as well as testing, the pin connections.
SUMMARY OF THE INVENTION
In a first aspect, the invention provides a keyboard switch matrix for use in keyboard key discrimination. The matrix includes a plurality of drive lines and a plurality of sense lines. A plurality of switches are provided for selectively causing contact between the drive lines and sense lines upon actuation of associated keyboard keys. At least one of the switches is arranged to bring into contact, upon actuation of an associated key, at least one of a combination of plural drive lines with a sense line; and a combination of plural sense lines with a drive line.
In a second related aspect, the invention provides an integrated circuit (IC) including a switch matrix and logic circuitry for sequentially driving signals, in timed relationship with each other, on a plurality of drive lines in a cyclical manner. The IC senses signals that appear on one or more of a plurality of sense lines as a result of at least one of a combination of plural drive lines contacting the one or more sense lines, and a combination of plural sense lines contacting the one or more drive lines. An actuated key is discriminated based on a time relationship of the driving of signals and a sensing of the signals appearing on the one or more sense lines.
In a third aspect, the invention is embodied in a method for keyboard key discrimination by time division multiplexing. Signals are sequentially driven in timed relationship with each other on a plurality of drive lines in a cyclical manner. Signals appear on one or more sense lines as a result of at least one of a combination of plural drive lines contacting the one or more sense lines and plural sense lines contacting one or more of the drive lines. These signals are sensed, and an actuated key is discriminated from among a plurality of keys, based upon a time relationship of the driving of signals and a sensing of the signals appearing on the one or more sense lines.
In accordance with the invention, keyboard key discrimination by time division multiplexing may be used to reduce the size of an integrated circuit (IC), and the overall size of an IC die package, by reducing the total number of pins required to interface with a keyboard key switch matrix. The invention p
Awad Amr
Banner & Witcoff , Ltd.
Microsoft Corporation
Saras Steven
LandOfFree
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