U.S. patent application number 14/257969 was filed with the patent office on 2014-08-14 for keyboard with increased control of backlit keys.
This patent application is currently assigned to Apple Inc.. The applicant listed for this patent is Apple Inc.. Invention is credited to Alex J. Crumlin, Duncan Kerr, Nicholas Vincent King, Chris Ligtenberg, James E. Orr, IV, Aleksandar Pance.
Application Number | 20140225835 14/257969 |
Document ID | / |
Family ID | 43219656 |
Filed Date | 2014-08-14 |
United States Patent
Application |
20140225835 |
Kind Code |
A1 |
Pance; Aleksandar ; et
al. |
August 14, 2014 |
Keyboard with Increased Control of Backlit Keys
Abstract
Methods and apparatuses are disclosed that provide increased
control of backlit keys for a keyboard. Some embodiments may
include controllers within the keyboard that are capable of
dynamically programming illumination of the keyboard based upon
interaction, where each key of the keyboard may be individually
programmed in a dynamic manner. For example, a spell checking
function may be executing on a computer system, and as the user
types various words, the keyboard may dynamically program the
illumination of keyboard controllers such that the next letter of
the word being typed is illuminated by the keyboard. Also,
different keyboard illumination schemes may be generated based upon
mouse movements by the user and/or based upon which application is
currently executing.
Inventors: |
Pance; Aleksandar;
(Saratoga, CA) ; Crumlin; Alex J.; (San Jose,
CA) ; King; Nicholas Vincent; (Cupertino, CA)
; Kerr; Duncan; (Cupertino, CA) ; Ligtenberg;
Chris; (Cupertino, CA) ; Orr, IV; James E.;
(Cupertino, CA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Apple Inc. |
Cupertino |
CA |
US |
|
|
Assignee: |
Apple Inc.
Cupertino
CA
|
Family ID: |
43219656 |
Appl. No.: |
14/257969 |
Filed: |
April 21, 2014 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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13770799 |
Feb 19, 2013 |
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14257969 |
|
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12476000 |
Jun 1, 2009 |
8378972 |
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13770799 |
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Current U.S.
Class: |
345/170 |
Current CPC
Class: |
G06F 3/0202 20130101;
H01H 2219/037 20130101; H01H 2219/016 20130101; H01H 2219/062
20130101; H01H 2217/038 20130101; G06F 3/0238 20130101; G06F 3/0237
20130101; H01H 2219/039 20130101; H01H 13/83 20130101 |
Class at
Publication: |
345/170 |
International
Class: |
G06F 3/02 20060101
G06F003/02 |
Claims
1-20. (canceled)
21. An input device, comprising: at least one input element; at
least one light source operative to selectively illuminate the at
least one input element; and a control component operative to
dynamically control a brightness, a color and an illumination
duration of the at least one light source.
22. The input device of claim 21, wherein the control component
dynamically operates the at least one light source based on an
application executing on a computing device coupled to the input
device.
23. The input device of claim 21, wherein the control component
dynamically operates the at least one light source based on a
detection of at least one input associated with an application
executing on a computing device coupled to the input device.
24. The input device of claim 21, further comprising: at least one
additional input element; and at least one additional light source
operative to illuminate the at least one additional input
element.
25. The input device of claim 24, wherein the control component is
operative to dynamically control a brightness, a color and an
illumination duration of the at least one additional light
source.
26. The input device of claim 25, wherein the control component
dynamically operates the at least one light source with a first
local control element and dynamically operates the at least one
additional light source with a second local control element.
27. The input device of claim 24, wherein the at least one light
source and the at least one additional light source are
independently controlled.
28. The input device of claim 21, wherein the at least one input
element comprises a key of a keyboard.
29. The input device of claim 21, wherein the color of the light
source comprises two or more colors.
30. A system, comprising: a computing device; at least one input
device coupled to the computing device, the at least one input
device comprising: at least one input element; at least one light
source operative to selectively illuminate the at least one input
element; and a control component operative to dynamically control a
brightness, a color and an illumination duration of the at least
one light source.
31. The system of claim 30, wherein the control component
dynamically operates the at least one light source based on an
application executing on the computing device.
32. The system of claim 30, wherein the control component
dynamically operates the at least one light source based on a
detection of at least one input associated with an application
executing on the computing device.
33. The system of claim 30, wherein the at least one input element
includes an assembly comprising a transparent piece.
34. The system of claim 33, wherein the at least one light source
comprises a two side-emitting LED coupled to the transparent
piece.
35. The system of claim 30, wherein the at least one input device
comprises a non-rigid keyboard.
36. The system of claim 30, wherein the at least one input device
is a mouse.
37. The system of claim 30, wherein the at least one input device
is a controller.
38. A method of selectively illuminating portions of an input
device, the method comprising: receiving a signal associated with
received input; and dynamically controlling illumination of a light
source associated with an input mechanism of the input device,
wherein the dynamically controlling illumination of the light
source comprises dynamically controlling a brightness, a color and
an illumination duration of the light source.
39. The method of claim 38, wherein the received input is input
associated with an application.
40. The method of claim 38, wherein the first light source is
outputs two or more colors substantially simultaneously.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. patent
application Ser. No. 12/476,000, entitled "Keyboard with Increased
Control of Backlit Keys," filed on Jun. 1, 2009, now U.S. Pat. No.
8,378,972, which is incorporated by reference in its entirety as if
fully disclosed herein.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0002] The following related patent applications are hereby
incorporated by reference in their entirety as if set forth fully
herein: U.S. patent application Ser. No. 12/476,067 titled "Light
Source With Light Sensor" and filed Jun. 1, 2009; U.S. patent
application Ser. No. 12/476,040 titled "User Interface Behaviors
For Input Device with Individually Controlled Illuminated Input
Elements" and filed Jun. 1, 2009; and U.S. patent application Ser.
No. 12/475,993 titled "White Point Adjustment For Multicolor
Keyboard Backlight" and filed Jun. 1, 2009.
BACKGROUND
[0003] 1. Technical Field
[0004] The present invention relates generally to lighting control
for keyboards, and more particularly to dynamic and individual
control of backlighting for keys within a keyboard.
[0005] 2. Background Discussion
[0006] Electronic devices are ubiquitous in society and can be
found in everything from wristwatches to computers. While
electronic devices such as computers operate in a world of ones and
zeros, human beings do not. Thus, many computers include
intermediary devices that allow human beings to interface to the
computer. One such device is a keyboard which allows the user to
interface with the computer by pressing certain keys. Optionally,
the user may view a display connected to the computer to determine
if the user's desired output was achieved, or input correctly
entered.
[0007] While most conventional approaches implement keyboards and
other intermediary devices as purely input devices, some
conventional approaches may convey output information to the user
of the computer via the keyboard. For example, when a user presses
the CAPS lock key, a light at the top of the keyboard may light up
to indicate that such a selection has been made. Alternatively,
some conventional approaches may provide a keyboard that associates
lights with its keys, where the keyboard may be statically
configured at boot time. Unfortunately, these conventional
approaches have several drawbacks. For example, most conventional
keyboards lack the ability to convey complex information to a user
(such as, for example, more information than just whether the CAPS
lock key is on). Also, while some conventional keyboards may
include backlit keys, conventional keyboards with backlighting do
not offer the ability to dynamically control lighting schemes for
each of the keys individually based upon interaction from the user
(e.g., typing on a keyboard, mouse movements, or based upon which
application is currently executing that is independent of a
particular input from the user). Accordingly, methods and
apparatuses that provide increased control of backlit keys for a
keyboard are useful.
SUMMARY
[0008] Methods and apparatuses are disclosed that provide increased
control of backlit keys for a keyboard. Some embodiments may
include controllers within the keyboard that are capable of
dynamically programming illumination of the keyboard based upon
interaction from a user, where each key of the keyboard may be
individually programmed in a dynamic manner. For example, a spell
checking function may be executing on a computer system, and as the
user types various words, the keyboard may dynamically program the
illumination of keyboard controllers such that the next letter of
the word being typed is illuminated by the keyboard. Also,
different keyboard illumination schemes may be generated based upon
mouse movements by the user and/or based upon which application is
currently executing.
[0009] Data for controlling the keys of the keyboard may be
generated as an array that may include such information as the
identifier associated with a particular key (e.g., the "A" key), a
brightness associated with this key (e.g., High, Medium, Low and so
on), a color associated with this key (e.g., red, green, and/or
blue), as well as a duration of illumination for this key (e.g.,
two seconds). The information in such a data array may be provided
to the keyboard in this format or further processed to create
different representations of the data based upon the sophistication
of the keyboard circuitry. For example, in some embodiments, the
keys of the keyboard may be light sources of any color, and may
result from a combination of two or more primary colors, such as
light sources capable of producing red, green, and/or blue (RGB)
light. In such embodiments, the array may include individualized
illumination information for each of the primary colors such as one
second for the red light source at a first power level and two
seconds for the green light source at a second power level. In
other embodiments, the keys of the keyboard may be light sources
that include a single color of illumination capable of producing
differing shades of the same color.
[0010] Some embodiments of the keyboard may include at least two
control circuits for controlling the illumination of the keys. For
example, the keyboard may include a global controller that receives
illumination information (such as data arrays of illumination
information) and conveys this information to local controllers,
where each local controller may independently control a group of
keys. In these embodiments, one local controller may control the
keys on the left hand side of the keyboard and another local
controller may control the keys on the right hand side of the
keyboard. Other embodiments may have different global/local
controller configurations, such as a single combined global/local
controller, any combination of global and local controllers, or a
number of independent local controllers without a global
controller.
[0011] Some embodiments may include a keyboard where the keyboard
further includes a plurality of keys, a plurality of light sources
coupled to the keys, and a global control circuit coupled to a
first local control circuit controlling a first light source in the
plurality and coupled to a second local control circuit controlling
a second light source in the plurality. In these embodiments, the
first and second local control circuits may be dynamically
programmed during operation of the keyboard. Other embodiments may
have different circuit configurations, such as a single combined
global/local circuit, any combination of global and local circuits,
or a number of independent local circuits without a global control
circuit.
[0012] Other embodiments may include a system that includes a
computer with a keyboard coupled to the computer. The keyboard may
include a plurality of keys, a keyboard controller coupled to the
plurality of keys, a plurality of light sources coupled to the
plurality of keys, and a lighting control circuit coupled to the
plurality of light sources. In these embodiments, the keyboard
controller may detect a keystroke of a user associated with an
application executing on the computer, and the lighting control
circuit may be dynamically programmed based upon the keystroke.
[0013] Still other embodiments may include a method of operating a
keyboard as an output device, where the method includes executing
an application on a computer system (the computer system coupled to
the keyboard), detecting a keystroke associated with the
application, and dynamically controlling illumination of a
plurality of light sources coupled to a plurality of keys of the
keyboard, where the dynamic control may be based upon the
keystroke, or alternatively, the dynamic control may be based upon
other system events, such as mouse movement or a currently
executing application.
BRIEF DESCRIPTION OF THE DRAWINGS
[0014] FIG. 1 illustrates a desktop computing system.
[0015] FIG. 2 illustrates a laptop computing system.
[0016] FIG. 3 illustrates a block diagram of the computing systems
shown in FIG. 1 and FIG. 2.
[0017] FIG. 4 illustrates a keyboard that may be used in the
computing system.
[0018] FIG. 5A illustrates one embodiment of a backlit key
structure.
[0019] FIG. 5B illustrates another embodiment of a backlit key
structure.
[0020] FIG. 5C illustrates a top view of one embodiment of a
transparent layer that may be used in the backlit key structures
shown in FIGS. 5A and 5B.
[0021] FIG. 6 illustrates one embodiment of a system that may
provide individual and dynamic control backlit keys in a
keyboard.
[0022] FIG. 7 illustrates another embodiment of a system that may
provide individual and dynamic control of backlit keys in a
keyboard.
[0023] FIG. 8 illustrates a system configuration that may provide
individual and dynamic control of backlit keys in a backlit
keyboard.
[0024] FIG. 9 illustrates operations that may be implemented to
provide individual and dynamic control of backlit keys in a backlit
keyboard.
[0025] FIG. 10 illustrates an exploded view of one sample physical
layout of various layers that may be used to construct part of a
keyboard having independently-lighted keys.
[0026] The use of the same reference numerals in different drawings
indicates similar or identical items.
DETAILED DESCRIPTION OF THE INVENTION
[0027] Embodiments are disclosed that allow individual and dynamic
control of backlit keys in a backlit keyboard. Some embodiments may
include controllers within the keyboard that are capable of
dynamically programming illumination of the keyboard based upon
interaction from a user, where each key of the keyboard may be
individually programmed in a dynamic manner.
[0028] Although one or more of these embodiments may be described
in detail in the context of a computer system, the embodiments
disclosed should not be interpreted or otherwise used as limiting
the scope of the disclosure, including the claims. In addition, one
skilled in the art will understand that the following description
has broad application. Accordingly, the discussion of any
embodiment is meant only to be exemplary and is not intended to
suggest that the scope of the disclosure, including the claims, is
limited to these embodiments.
[0029] FIG. 1 illustrates a desktop computing system 100 capable of
dynamic configuration of backlighting of a keyboard 125, where the
system 100 may include a display 105 coupled to a computer 110.
Note that although embodiments are disclosed herein where the
computing system 100 is discussed in the context of a desktop or
laptop computing system, the computing system 100 may take a
variety of forms, such as a personal digital assistant, a cellular
telephone, a portable gaming system, and so on. Furthermore,
although the backlighting is discussed in the context of the
keyboard 124, the backlighting concepts may be applied to a variety
of peripheral devices, such as mice, gaming controllers, and so
on.
[0030] The computer 110 may couple to one or more input devices
such as a keyboard 125 and/or mouse 126. (The keyboard 125 is shown
in greater detail below in FIG. 4). During operation, the computing
system 100 generally executes application programs and/or operating
system (OS) software under the direction of a user. The user may
interact with the application programs or OS software via the
keyboard 125. As will be described in further detail below, while
the keyboard 125 and/or mouse 126 are conventionally used as input
devices, the keyboard 125 and/or mouse 126 may be dynamically
configured to provide output data to users, such as by illuminating
the keys of the keyboard 125 in response to keystrokes from a
user.
[0031] Depending upon the embodiment, the keyboard 125 and mouse
126 may take a variety of forms. For example in some embodiments,
the keyboard 125 may be a 101-key US traditional keyboard
configured to support the English language while the mouse may be a
PS2 style. However, in alternative embodiments, the keyboard 125
may be a 102/105-key International keyboard configured to support
non-English languages. In still other embodiments, the keyboard 125
may provide multimedia support, with dedicated keys for accessing
and controlling multimedia files, or providing other specialized
functionality.
[0032] While FIG. 1 depicts the keyboard 125 and mouse 126 coupled
to the computer 110 via a hardwired connection, it should be
appreciated that the keyboard 125 and mouse 126 may couple to the
computer wirelessly, such as via an Infrared and/or Bluetooth
connection. Also, optional input devices, such as a redundant
keyboard 130, may be used to provide greater flexibility in
operation of the computer 110. For example, the keyboard 125 and
the keyboard 130 may be used by separate users, both of whom may be
concurrently using the computing system 100.
[0033] Some embodiments may implement the computer 110 as a
Macintosh.RTM. computer manufactured by Apple Inc. For example, the
computer 110 may be a Mac.RTM. Mini and the OS may be Mac OS.RTM.
X. FIG. 2 illustrates an alternative embodiment where the computing
system 100 is implemented as a laptop system, such as the
MacBook.RTM. Pro, where the keyboard 125 and mouse 126 are
integrated in the computing system 110. As will be described in
greater detail below, in the embodiments where the computer 110 is
implemented as a laptop, the keyboard illumination scheme may be
dynamically controlled according to a specified power budget.
[0034] Alternative embodiments are possible where the computing
system 100 is not a personal computer. For example, the computing
system 100 may be a gaming system, such as the XBox.RTM. gaming
system manufactured by Microsoft, Inc., the Playstation.RTM. gaming
system manufactured by Sony, Inc., and/or the Wii.RTM. gaming
system manufactured by Nintendo. As will be appreciated by one of
skill in the art, the input devices, such as the keyboard 125 and
mouse 126, may take a variety of forms depending upon the actual
implementation of the computing system 100. For example, in the
embodiments where the computing system 100 is a gaming system, the
input devices may be game controllers with dynamic illumination
operations akin to the keyboard 125 and mouse 126 (which are
described in further detail below).
[0035] FIG. 3 illustrates a sample block diagram of the computer
system 100 described above in the context of FIGS. 1 and 2. The
system 100 may include a video memory 300, a main memory 302 and a
mass storage 303, all coupled to a system bus 305 along with the
keyboard 125, mouse 126 and processor 310. The mass storage 303 may
include both fixed and/or removable media, such as magnetic,
optical or magnetic optical storage systems and any other available
mass storage technology. The bus 305 may provide, for example,
address lines for addressing video memory 300 or main memory 302.
The system bus 305 also may provide, for example, a data bus for
transferring data between and among the components, such as
processor 310, main memory 302, video memory 300, and mass storage
303. The video memory 300 may be a dual-ported video random access
memory. One port of the video memory 300, in one example, is
coupled to a video amplifier 315, which is used to drive the
display 105. The display 105 may be any type of monitor suitable
for displaying graphic images, such as a cathode ray tube monitor
(CRT), flat panel, a liquid crystal display (LCD) monitor, a
organic light emitting diode (OLED), or any other suitable data
presentation device.
[0036] In some embodiments, processor 310 is a microprocessor
manufactured by Motorola, such as the 680XX0 processor, or a
microprocessor manufactured by Intel, such as the X86 line of
processors. Any other suitable microprocessor or microcomputer may
be utilized, however.
[0037] Depending upon the embodiment, the bus 305 may include
multiple busses. For example, the bus 305 may include a Northbridge
bus coupled between the processor 310 and the main memory 302 and
video memory 300, as well as a Southbridge bus coupled between the
processor 310 and the keyboard 125, mouse 126, and/or other
peripheral devices.
[0038] During operation, code received by system 100 may be
executed by the processor 310 as it is received, and/or stored in
the mass storage 303, or other non-volatile storage for later
execution. In this manner, system 100 may obtain application
programs or OS software in a variety of forms. Application programs
may be embodied in any form of computer program product such as a
medium configured to store or transport computer readable code or
data, or in which computer readable code or data may be embedded.
Examples of computer program products include CD-ROM discs, ROM
cards, floppy disks, magnetic tapes, computer hard drives, servers
on a network, and solid state memory devices.
[0039] FIG. 4 illustrates a n exploded view of the keyboard 125
shown in FIGS. 1 and 2. For ease of discussion, FIG. 4 shows only
the keyboard 125. However, as was mentioned previously, alternative
input devices may be illuminated in the manner described herein.
Thus, the disclosure equally may apply to each of the numerous
input devices in addition to the keyboard 125.
[0040] Referring to FIG. 4, the keyboard 125 may include a top
portion 400 and a bottom portion 405 that come together in a
sandwich-like fashion. The top portion 400 may include a plurality
of keys 410 for data entry. As mentioned previously, the actual key
configuration may be a 101-key US traditional keyboard configured
to support the English language while other embodiments may include
a 102/105-key International keyboard configured to support
non-English languages. Although the top portion 400 is discussed
herein in the context of mechanically actuated keys, alternative
embodiments may include keys that are not mechanically actuated,
such as capacitive, inductive, resistive or pressure sensing keys
and/or keyboards. Also, while the keyboard 125 is shown as a rigid
structure including top and bottom portions 400 and 405, alternate
embodiments are possible where the keyboard 125 is a pliable
material and the keyboard 125 may be folded into portions or may be
rigid but still separated into portions and/or folded.
[0041] As shown in FIG. 4, the keyboard 125 also may include a
plurality of lights 415 each placed adjacent to one or more of the
keys 410. In some embodiments, the lights 415 may exist in an array
of lights integrated within a structural grid 420 that is
interposed between the top and bottom portions 400 and 405 as the
keyboard 125 is manufactured. Each of the keys 410 may have a first
portion that is transparent to light shining from underneath the
keys 410 and a second portion that is opaque to light shining from
underneath the keys 410. By lighting each of the keys 410
individually or in groups, the keyboard 125 may be advantageously
used as an output device as well as the more conventional use as an
input device. For example, in some embodiments, the keyboard 125
may be used to train new users on how to operate an application
program and provide customized feedback based upon the user's key
entries. As will be described in further detail below, various
embodiments may provide for dynamic configurability of the keys 410
on an individual or grouped basis. This may allow, for example,
hotkeys associated with a particular application program to be
dynamically lit whenever that particular application program is
running on the computer 110. In addition, the output on the
keyboard 125 may be based upon interaction from the user. For
example, a spell check function may be implemented where different
colored lights may indicate the next possible letter in the word
being typed by the user (e.g., green for the next most probable
letter in the word, red for the second most probable letter in the
word, and blue for the third most probable letter in the word). In
other embodiments, the output of the keyboard 125 may be based upon
interaction with the user that is independent of any particular
input from the user. For example, in some embodiments, the output
to the keyboard 125 may occur in response to OS events or states or
some other system event (e.g., a low power state).
[0042] In some embodiments, each of the lights 415 may be one or
more light emitting diodes (LEDs) of differing colors. For example,
in some embodiments, a single LED containing red, green, and blue
(RGB) LEDs may be positioned underneath each of the keys 410. In
other embodiments, the single LED may contain other light
combinations such as cyan, yellow, and magenta (CYM), or
amber-green to name but a few. Alternatively, three separate LEDs
may be used to provide a mixture of primary colors. By mixing these
three primary colors, a wide variety of resulting colors may be
generated individually for each of the keys 410. In other
embodiments, the lights 415 may be organic LEDs (OLEDs), and may
generate a wide variety of display patterns and colors on each of
the keys 410.
[0043] Other embodiments may place the lights 415 within the keys
410. For example, FIG. 5A illustrates a key 500 where a light
source 505 is integrated within the key 500. The key 500 may be
used in place of the keys 410 shown in FIG. 4, thereby eliminating
the need for the mechanical grid 420 and still providing for
individual lighting control of each of the keys 410. As shown in
FIG. 5A, the key 500 may include a keycap 510 seated over a key
depression assembly 515 and key light housing 520. The keycap 510
may include portions that are transparent to light from the source
505 and portions that are opaque to light from the source 505. For
example, the keycap 510 shown in FIG. 5A illustrates the "A" key of
a 101-key US traditional keyboard, where the "A" portion is
transparent and the remainder of the keycap 510 is opaque. In this
manner, as the source 505 emits light, the "A" portion may
illuminate while the remaining portions of the keycap 510 are dark,
which may provide the user of the keyboard 125 with the appearance
of a glowing "A" key. Alternate embodiments are possible where
other portions of the keys are illuminated. For example, the "A"
portion may be dark while the remaining portions of the keycap 510
illuminate. Also, in some embodiments, rather than a single key
having one or more light sources, a single light source may be
associated with multiple keys. Thus, the light source 505 may be
part of a light source that is shared among multiple keys.
[0044] The depression assembly 515 may detect key depressions, such
as the user pressing the keycap 510. In some embodiments, such as
those shown in FIG. 5A, the depression assembly may include a
transparent top pad 525 that mates to the keycap 510. As the keycap
510 is depressed, the top pad 525 may compress one or more flexible
springs 530 to signal that the key 500 has been pushed. An
electrical circuit (not shown) may detect the compression of the
springs 530 and thereby indicate that the key 500 has been pressed.
The depression assembly 515 may be situated on top of a transparent
layer 535 that allows light from the source 505 to emanate through
the layer 535, through the top pad 525, and ultimately emanate out
through the transparent pattern in the keycap 510 as described
above. The transparent layer 535 may be one or more clear
transparent layers of plastic material, such as Plexiglass.RTM.,
tempered glass, plastic or the like. FIGS. 5B and 5C illustrate
side and top views of alternate embodiments of the layer 535, that
may consolidate space underneath the keycap 510. For example, in
some embodiments, the layer 535 may be 0.6 millimeters thick, which
may be several millimeters thinner than the thickness of
conventional keys and thereby reduce the overall height of the key
500 shown in FIG. 5A. Also, depending upon the embodiment, the
light source 505 may take a variety of forms, such as multiple
LEDs, a single RGB LED, one or more side-emitting LEDs as shown in
FIGS. 5B and 5C, and so on. The embodiments shown in FIGS. 5A-5C
are merely illustrative, and alternate embodiments may include
non-mechanically actuated keys, such as capacitive, inductive,
pressure, and/or resistively actuated keys. Also, depending upon
the embodiment, the transparent layer 535 may take on a variety of
forms. For example, in the embodiments where the LEDs may be top
firing, such as the embodiment shown in FIG. 5A, then the
transparent layer 535 may be a diffuser or lens focusing mechanism
that allows light to be shaped into a desired pattern, such as a
Fresnel lens or elliptical lens. In other embodiments where the
LEDs may be side firing, such as the embodiments shown in FIGS. 5B
and 5C, the transparent layer 535 may be a light guide that
receives light in the X-Y plane and redirects it in the Z
plane.
[0045] Regardless of whether lights for the keyboard 125 are
integrated within the keys as shown in FIGS. 5A-C or in a larger
assembly as shown in FIG. 4, the keyboard 125 may include a
lighting controller 425 as shown in FIG. 4. Although the lighting
controller 425 is shown with respect to the keyboard 125, similar
implementations may be used in other portions of the computing
system 100, such as the computer 110 or the mouse 126. FIGS. 6 and
7 illustrate potential embodiments for the lighting controller 425
in greater detail.
[0046] Referring to FIG. 6, the controller 425 may include a global
controller 600 coupled to one or more local controllers 605A-N.
While FIG. 6 illustrates but one embodiment of the controller 425,
it should be appreciated that other embodiments may have different
global/local controller configurations, such as a single combined
global/local controller, any combination of global and local
controllers, or a number of independent local controllers without a
global controller.
[0047] In some embodiments, the global controller 600 and/or the
local controllers 605A-N may be microcontrollers, such as a model
8742 manufactured by Intel Corporation, or a PIC16F84 manufactured
by Microchip, Inc. In other embodiments, the global controller 600
may be part of a larger integrated circuit, such as a
microprocessor, capable of running in either master or slave mode.
The global controller 600 may couple to a keyboard controller 610,
which, as indicated by the dashed lines in FIG. 6, may be external
to the keyboard 125. For example, it may be located within the
computer 110 in some embodiments. During operation, the keyboard
controller 610 may communicate desired lighting schemes to the
global controller 600 thereby allowing the global controller 600 to
dynamically control the keys 410 individually or in one or more
groups. In the embodiments where power consumption is a concern,
such as when the computer 110 is a laptop, the keyboard controller
610 also may communicate a desired power budget to the global
controller 600 and allow the global controller 600 to dynamically
control the keys 410 individually or in groups based upon the power
budget constraints. For example, in these embodiments, the global
controller 600 may establish a maximum number of keys that may be
illuminated at any one time when the laptop is being powered off of
the battery (e.g., five keys) and have no maximum number of keys
that may be illuminated when the laptop is plugged into wall
power.
[0048] The connection 615 between the keyboard controller 610 and
the global controller 600 may take the form of any of a variety of
multiple connection bussing protocols. For example, in some
embodiments, the connection 615 may be a Universal Serial Bus (USB)
protocol and/or a PS/2 protocol.
[0049] The global controller 600 may communicate with the local
controllers 605A-N via a multiple connection electrical bus, such
as a serial peripheral interface (SPI) bus 620, which is a
synchronous serial data link capable of operating in full duplex
mode. Other embodiments may implement the bus 620 as an
inter-integrated circuit (1.sup.2C) bus or a system management bus
(SMBus). In the event that the bus 620 is implemented as a SPI bus,
it may include four separate electrical connections: a serial clock
(CLK) output provided by the global controller 600, a data in (DI)
connection used by the global controller 600 for supplying data to
the local controllers 605A-N, and a data out (DO) connection used
by the local controllers 605A-N to communicate data to the global
controller 600. As indicated by the dashed line in FIG. 6, an
optional chip select (CS) connection signal from the global
controller 600 to each of the local controllers 605A-N may be
implemented, such as when the local controllers 605A-N are
independently addressed.
[0050] Because the local controllers 605A-N may share the DO
connection, the outputs of the local controllers 605A-N may be
tri-state outputs. In this manner, when a particular local
controller 605A-N is not selected, its outputs may be high
impedance, thereby allowing multiple local controllers 605A-N to be
electrically isolated from the local controller 605A-N that is
currently in use and allow for individual control of the light
sources coupled to the local controllers 605A-N.
[0051] During operation, the global controller 600 and the local
controllers 605A-N may communicate in a master/slave fashion where
the global controller 600 initiate communication between the global
controller 600 and the local controllers 605A-N in the form of
frames of data. To initiate a connection, the global controller 600
may configure the CLK signal to operate at a frequency that can be
commonly supported by all of the local controllers 605A-N. In some
embodiments, the local controllers 605A-N may be capable of
operating in the range of 1-70 MHz. Thus, in the event that the
local controllers 605A-N do not employ the same HW and/or have
different operating frequencies, then the global controller 600 may
select a frequency that is commonly supported by each of the local
controllers 605A-N. For example, the local controller 605A may
operate at 1 MHz while the local controller 605N may operate at 70
MHz. In such a situation the global controller 600 may adjust the
CLK signal to operate at 1 MHz to accommodate both local
controllers. In some embodiments, in addition to adjusting the CLK
signal frequency, the global controller 600 may adjust the signal's
polarity and/or phase to vary the behavior of signal transmission
between the global controller 600 and the local controllers
605A-N.
[0052] In the example of FIG. 6, the bus 620 is implemented as an
SRI bus. In this example, the global controller 600 may include a
global register 625 and each of the local controllers 605A-N may
include a local register 630A-N. The global register 625 may couple
to each of the local registers 630A-N via the DI and DO signal
lines, where data is sent to the local registers 630A-N via the DI
signal line and data is received from the local registers via the
DO signal line. Some embodiments may daisy chain input and output
signals between the several local registers 630A-N such that the DI
signal from the global controller 600 couples to the local
controller 605A; the DO signal of the local controller 605B couples
to the DI signal of the next local controller 605B, and so on until
the DO of the local controller 605N couples back to the global
controller 600.
[0053] In the embodiment shown in FIG. 6, the global register 625
and the local registers 630A-N may form an inter-chip circular
buffer where bits of data in the global register 625 are shifted
out of the global register 625 and received in the local register
630A-N in a bit-by-bit fashion beginning with the most significant
bit (MSB) and ending with the least significant bit (LSB). Data
signals that indicate individualized lighting schemes for the LEDs
640 (described in more detail below) may be communicated between
the global controller 600 and the local controllers 605A-N by
shifting this data from the global controller 600 one or more of
the local controllers 605A-N. Once the global controller 600 has
configured the CLK signal line, the global controller 600 may
indicate, via the CS line, which of the local controllers 605A-N is
being sent data.
[0054] During a cycle of the CLK signal, assuming the local
controller 605A has been initiated with the CS signal, the global
controller 600 may send a bit of data on the DI signal line and the
local controller 605A may read the data from the DI line. Further,
the local controller 605A may send a bit of data on the DO line,
and the global controller 600 may read this data from the DO line.
(Note that in some embodiments, one or more of these operations may
be combined or eliminated.) Because the local controller 605A has
been indicated with the CS line, the other local controllers 605B-n
will disregard the CLK signal and signals on the DI and DO signal
lines.
[0055] As shown in FIGS. 6 and 7, each of the local controllers
605A-N may be coupled to a group of light sources 635A-N. Although
FIGS. 6 and 7 illustrate implementing the light sources as an array
of LEDs 640A-N separated into groups 635A-N, any type of light
source may be used in practice. Each of the groups 635A-N may be
coupled to a separate local controller 605A-N, and therefore, each
of the local controllers 605A-N may be capable of separately
controlling the light sources 640A-N. For example, the local
controller 605A may control the lights 640A in the group 635A while
the local controller 605N may separately control the lights 640N in
the group 635N.
[0056] Each LED 640 in the groups 635A-N may be separately coupled
to a key of the keyboard 125. For example, the LED 640 may be
implemented as the light source 505 as shown in FIGS. 5A-C.
Furthermore, each of the LEDs 640 may be coupled to a network of
resistors 645, 655A-C that regulate the current driven through the
LEDs 640. In some embodiments, the combination of the resistors
645, and 655A may have a different resistive value than the
combination of the resistors 645 and 655B and the combination of
the resistors 645 and 655C. The local controllers 605A-N may
therefore control the intensity of light emanating from the LEDs
640 by controlling which of the resistors 655A-C is active at any
time. For example, the local controllers 605A-N may couple the
resistors 655A-C to ground during activation. In some embodiments,
one or more of the resistors 655A-C may be active at any one time
to mix and match the resistive values, thereby producing different
light intensities. Control of light intensity emitted by an LED may
also be achieved or enhanced by selectively coupling one of the
resistors 655A-C to ground while keeping other resistors in the
group at high impedance.
[0057] In some embodiments, the lighting controller 425 (an example
of which is shown in FIG. 4) may be implemented as a single
integrated circuit rather than as the global and local controllers
600, 605A-N shown in FIG. 6. For example, FIG. 7 illustrates an
embodiment where the controller 425 may be implemented as a single
LED driver 700 thus eliminating or reducing the network of
resistors 645, 655A-C. The driver 700 may include a plurality of
switching devices, such as a first transistor 705A, coupled to an
accompanying LED 640A. For the sake of discussion, the transistors
shown in FIG. 7 are discussed as if they were n-type
metal-oxide-semiconductor (NMOS) devices, however it should be
appreciated that the transistors may be implemented with a variety
of alternative electrical devices, such as p-type
metal-oxide-semiconductor (PMOS) devices. The first transistor 705A
may couple, via its gate connection, to a second transistor 710A
that has its gate connection connected to its drain connection,
which is sometimes referred to as a diode-connected transistor.
Both the first and second transistors 705A and 710A may connect to
ground through their source connections. Because the first and
second transistors 705A and 710A have the same gate and source
connections, they will share the same gate-source voltage, and as a
result, will conduct a proportional amount of current. This
arrangement is sometimes referred to as a "current-mirror".
Depending upon the relatively sizing of the first and second
transistors 705A and 710A, the amount of current flowing in the
first transistor 705A may differ from the amount of current flowing
in the second transistor 710A. For example if the first transistor
705A is half the size of the second transistor 710A, then the first
transistor 705A may conduct half the amount of current flowing in
the second transistor 720A (i.e., half of the current supplied by
the current source 715A). Also, when the first and second
transistors 705A and 710A are substantially the same size, they may
conduct the same amount of current (i.e., a current substantially
equal to the current flowing in the current source 715A). Thus,
current flowing through the first transistor 705A may match the
current flowing through the second transistor 710A, which may be
set to a desired value by current source 715A that is connected to
the drain of the second transistor 710A via a third transistor
720A.
[0058] The drain of the third transistor 720A may be connected to
the current source 715A while the source of the third transistor
720A may be connected to the second transistor 710A. In this
manner, the current source 715A may be connected between the drain
connection of the third transistor 720A and a voltage supply, such
as V.sub.DD. During operation, the third transistor 720A may
control the current supplied to the second transistor 710A by being
turned on and off, for example by using a pulse width modulated
(PWM) signal coupled to the gate connection of the third transistor
720A. The PWM signal may be generated within the driver 700, or
alternatively, received from the keyboard controller 610 via the
bus 615. As the third transistor 720A switches on and off per the
PWM signal, the current flowing in the second transistor 710A may
be mirrored to the first transistor 705A. For example, when the
first and second transistors 705A and 710A are substantially the
same size, and the third transistor 720A is on, then the current in
the first transistor 705A may be substantially equal to the current
supplied by the current source 715A. In some embodiments, the value
of the current supplied by the current source 715A may be 20-25
milliamperes (mA). As a result of the second transistor 710A
alternating between conducting current and not conducting current,
the first transistor 705A may alternate between conducting and
non-conducting states. The drain connection of the first transistor
705A may couple to the LED 640A so that the current flowing in the
first transistor 705A may control the current in the LED 640A. By
controlling the PWM signal, by virtue of the current mirror, the
current flowing in the first transistor 705A and the LED 640A may
be controlled, and therefore, the intensity of the light emanating
from the LED 640A may be controlled.
[0059] As shown, the electrical devices within the driver 700 that
are coupled to the LED 640A may be replicated and coupled to other
LEDs in the array in a similar fashion. For example, the
transistors 705N, 710N, and 720N and current source 715N may couple
to the LED 640N in the same way that the transistors 705A, 710A,
and 720A and current source 715A are coupled to the LED 640A. In
this manner, the current flowing in each of the LEDs 640A-N may be
uniform, thereby allowing the intensity of the light emanating from
each of the LEDs 640A-N to be individually adjusted in a uniform
manner. The ability to individually and uniformly adjust the light
emanating from each of the LEDs 640A-N may be beneficial in many
ways, such as by producing a more aesthetically pleasing output
signal from the keyboard 125 to the user, or allowing output
information to be conveyed to the user through the keyboard 125
more accurately.
[0060] FIG. 8 illustrates one of several potential configurations
for various software and/or hardware elements 800 of the computer
system 100 described above and FIG. 9 illustrates sample operations
900 of the software and/or hardware components 800 in one such
embodiment. For ease of discussion, FIGS. 8 and 9 refer only to the
keyboard 125. However, as was mentioned previously, numerous input
devices are possible. While conventional keyboards are often used
as input devices, it is possible to configure the computer system
100 such that the keyboard 125 may convey output data to the user.
For example, if certain key combinations are entered while
operating the keyboard, the computer system 100 may cause certain
lights associated with keys of the keyboard 125 to dynamically
control lights associated with the keys. As was mentioned
previously, the dynamic control may be in response to user input
(e.g., spell check functionality, teaching hotkey functionality,
etc.).
[0061] Referring now to FIGS. 8 and 9, at least a portion of the OS
running on the computer 110 may include a keyboard driver 805 that
handles the individual color control of the keys 410 of the
keyboard 125. The keyboard driver 805 may dynamically associate a
key event from the keyboard 125 to a key lighting event. A "key
lighting event" refers generally to the act of illuminating a key
in response to a user input. In some embodiments, this input may be
in the form of typical interaction with an application being
executed on the computer 110. As one example of a key lighting
event, if the user types all but the last letter of a word, a spell
checker function may couple to the keyboard driver 805 to light the
most probable last letter of the word being typed by the user. This
is shown in FIG. 9 as operation 905 where the application or OS
sends a request to the keyboard driver 805 to dynamically configure
the keyboard 125 according to a particular lighting scheme.
[0062] As shown in FIG. 8, the keyboard driver 805 may couple to a
backlight driver 810, which may be part of the OS in some
embodiments. During operation, the keyboard driver 805 may send
data to the backlight driver 810 in array form, such as an
identifier associated with a particular key, a brightness
associated with this key, a color associated with this key, as well
as a duration of illumination for this key. Table 1 illustrates a
potential array with this information for two keys of a sample
keyboard.
TABLE-US-00001 TABLE 1 Key Brightness Color Duration A Medium Red 2
seconds B High Blue 1 second
[0063] Although Table 1 illustrates potential signals for two keys,
the array generated by the keyboard driver 810 may contain many
entries. For example, in the event that the keyboard 125 is a
101-key US traditional keyboard, then the array may contain 101
entries each having a brightness, color, and/or duration.
Furthermore, although Table 1 illustrates potential signals color
illumination, non-color illumination signals (e.g., luminance only)
are also possible. Generation of the array data for Table 1 may
occur during operation 910 in FIG. 9.
[0064] The backlight driver 810 may couple to a backlight
controller 815. In some embodiments, the backlight controller 815
may exist as a discrete integrated circuit within the keyboard 125.
In other embodiments, the backlight controller 815 may exist as
firmware stored in a read only memory (ROM) within another portion
of the keyboard 125, such as the lighting controller 425.
Regardless of the implementation of the backlight controller 815,
during dynamic configuration of the keyboard 125, the backlight
driver 810 may generate data signals for programming the backlight
controller 425. This is shown in operation 915.
[0065] In some embodiments, the data signals generated by the
backlight driver 810 may be in array form as shown in Table 2,
which is akin to the array shown in Table 1, yet more rudimentary
than the array of data shown in Table 1. The more rudimentary
nature of the data signals in Table 2 may be beneficial, for
example, in the embodiments where the driver 810 is less complex
and unable to directly process the data of Table 1. Again, although
Table 2 illustrates potential signals for but a few keys, the array
generated by the driver 810 may contain many entries, such as when
the keyboard 125 is a 101-key US traditional keyboard. In the
embodiments where the registers 625 and 630A-N (shown in FIG. 6)
are implemented, for example, when the bus 625 is an SPI bus, then
the elements of the arrays shown in Tables 1 and 2 may be the
values in each of the registers 625 and 630A-N.
[0066] As shown in Table 2, each individual key may have customized
RGB values, current levels, and/or firing durations each red,
green, and/or blue LEDs of each key of the keyboard 125. Notably,
these customized values may vary as the keyboard 125 is dynamically
controlled based upon user inputs.
TABLE-US-00002 TABLE 2 KeyID R, G, and/or B Current Level Duration
A Red - 20% Red - 5 mA Red - 1 second Green - 50% Green - 12.5 mA
Green - 2 seconds Blue - 10% Blue - 2.5 mA Blue - 3 seconds B Red -
70% Red - 17.5 mA Red - 7 seconds Green - 50% Green - 12.5 mA Green
- 0.5 seconds Blue - 60% Blue - 15 mA Blue - 2 seconds
[0067] In some embodiments, the values and/or settings shown in
Table 2 may be implemented by the combination of the keyboard
controller 610 in combination with the global controller 600 and
local controllers 605A-N (shown in FIG. 6). In other embodiments,
the values and/or settings shown in Table 2 may be implemented by
the combination of keyboard controller 610 and the LED driver 700
(shown in FIG. 7). This is shown in operation 920, where the RGB
backlights of the keyboard 125 may be individually controlled by
dedicated hardware that is dynamically updated from the OS
drivers.
[0068] Note that although Tables 1 and 2 illustrate potential
signals for controlling key illumination, other embodiments are
possible. For example, while Tables 1 and 2 include information
regarding the duration of the illumination, other embodiments may
control the LEDs with a pulse-width-modulated (PWM) for each of the
individual colors. Each of the PWM signals may have a frequency of
N, where the frequency of the PWM signal N may be chosen such that
it is above the flicker detection threshold of the human eye (e.g.,
60 Hz). In these embodiments, the computer 110 may determine values
for the RGB backlights N times per second to determine an
instantaneous desired color based upon the duty cycle of the PWM
signal. For example, the RGB backlight may be off when each of the
red, green, and blue backlights have a PWM signal with a duty cycle
of 0%, and the RGB backlight may be a teal color when the red PWM
signal duty cycle is 0%, the green PWM signal duty cycle is 100%,
and the blue PWM signal duty cycle is 100%.
[0069] The keyboard controller 610 also may include firmware 820
capable of detecting keystrokes and conveying this information back
to the computer 110 to allow dynamic control of the lighting
schemes. In some embodiments, however, separate circuitry 820 may
be included in the keyboard 125 to report keystroke information
back to the computer 110. This reporting is shown in FIG. 9 as
operation 925.
[0070] Regardless of whether reporting occurs via firmware or via
dedicated circuitry, the keyboard driver 805 described above also
may process data reported from the firmware or circuitry 820 and
report depressed key sequences back to the OS or applications
running on the computer 110. This is shown in operation 930.
Reporting the depressed keys and/or key sequences back to the OS
and/or applications running on the computer 110 may allow dynamic
control of the keyboard 125 that is interactively based upon inputs
by the user. Thus, per operation 935, in the event that the user's
inputs require a modification of the current lighting scheme,
control may flow to operation 905 where the OS or application may
request dynamic key lighting re-configuration. On the other hand,
if the user's inputs do not require a modification of the current
lighting scheme, then control may flow to operation 960 where it
may be determined whether the illuminating scheme is finished. In
the event that the illumination scheme is not finished, control may
flow to operation 910 where the keyboard driver 805 may continue to
generate data arrays based upon the current lighting scheme. In the
event that the illumination scheme is finished, then control may
flow to operation 965, where the sample operations 900 may end.
[0071] FIG. 10 generally depicts one sample physical layout of
various layers that may be used to construct part of a keyboard 125
having independently-lighted keys. That is, the elements shown in
exploded view in FIG. 10 generally underlie the mechanical keys
themselves. It should be understood that FIG. 10 displays only a
segment underlying six keys of such a keyboard purely for the sake
of simplicity. The entire layer of the keyboard may be constructed
in the fashion and from the layers shown in FIG. 10.
[0072] Generally, a printed circuit board (PCB) forms a base layer
1000. Beneath each key, a multicolor LED (or multiple LEDs, each of
which may emit a single color) are secured to the PCB 1000 and
wired to a controller. A frame 1110 made of polycarbonate or
another suitable material may overlay the base layer 1000. As shown
in FIG. 10, the frame 1110 generally has a hole or opening defined
above each LED package.
[0073] A separate lightguide 1120 is used for each key. In this
fashion, each lightguide 1120 may distribute light from the
underlying LED(s) to the corresponding key. The lightguides rest in
the apertures formed in the frame 1110. When the frame, lightguide
and PCB 1000 are affixed to one another, the LEDs rest in a notch
defined in each opening in the frame with the lightguides adjacent
the LEDs. In this manner, the LEDs may emit light into the side of
the lightguides and the guides, in turn, may redirect the emitted
light upward as well as diffuse it. For example, the lightguide may
diffuse the light emitted by one or more associated LEDs across its
entire upper surface and therefore across the entire upper surface
of a key or may concentrate the emitted light in an area
corresponding to an etched or transparent part of the key, as
discussed with respect to FIG. 5. In one embodiment, the lightguide
may be a microlens that diffuses and redirects light entering in a
horizontal direction into a vertical direction. In the embodiment
of FIG. 10, the LEDs are side-firing. The lightguide is typically
made from an acrylic or like material.
[0074] A mask 1130 overlays the frame and PCB. The mask 1130
exposes at least portions of the upper surfaces of the lightguides
1120 but conceals the LEDs. The mask also holds the lightguides
1120 in place within the frame and atop the PCB 1000. As stated
above, these layers, when assembled, are generally fitted within a
keyboard and beneath the keys themselves.
[0075] While the present disclosure has been described with
reference to various examples, it will be understood that these
examples are illustrative and that the scope of the disclosure is
not limited to them. Many variations, modifications, additions, and
improvements are possible. More generally, examples in accordance
with the present disclosure have been described in the context or
particular embodiments. Functionality may be separated or combined
in blocks differently in various embodiments of the disclosure or
described with different terminology. These and other variations,
modifications, additions, and improvements may fall within the
scope of the disclosure as defined in the claims that follow.
* * * * *