U.S. patent application number 14/335902 was filed with the patent office on 2014-11-06 for designer control devices.
This patent application is currently assigned to PERSONICS HOLDINGS, LLC. The applicant listed for this patent is PERSONICS HOLDINGS, LLC. Invention is credited to Steven Wayne Goldstein, John Usher.
Application Number | 20140327527 14/335902 |
Document ID | / |
Family ID | 39926112 |
Filed Date | 2014-11-06 |
United States Patent
Application |
20140327527 |
Kind Code |
A1 |
Goldstein; Steven Wayne ; et
al. |
November 6, 2014 |
DESIGNER CONTROL DEVICES
Abstract
A control device configurable to couple to one or more devices
having different control functions and a method of facilitating
remote control of at least one device having different control
functions includes a processor that receives an instruction for at
least one of the control functions and additional information from
the at least one device, the processor including a plurality of
processing algorithms, the additional information received from the
at least one device including at least a locally transmitted data
signal. The processor selectably processes the additional
information using at least one of the processing algorithms and
controls a touch sensitive display reconfigurable for the different
control functions, such that the at least one control function and
the selectably processed additional information are presented on
the touch sensitive display. The processor also generates at least
one control signal responsive to receiving the locally transmitted
data signal. Other embodiments are disclosed.
Inventors: |
Goldstein; Steven Wayne;
(Delray Beach, FL) ; Usher; John; (Beer,
GB) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
PERSONICS HOLDINGS, LLC |
Boca Raton |
FL |
US |
|
|
Assignee: |
PERSONICS HOLDINGS, LLC
Boca Raton
FL
|
Family ID: |
39926112 |
Appl. No.: |
14/335902 |
Filed: |
July 19, 2014 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
12111005 |
Apr 28, 2008 |
8788077 |
|
|
14335902 |
|
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60914319 |
Apr 27, 2007 |
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Current U.S.
Class: |
340/12.53 |
Current CPC
Class: |
A61B 5/6817 20130101;
A61B 5/0205 20130101; G06F 3/041 20130101; A61B 5/0022 20130101;
G08C 17/02 20130101 |
Class at
Publication: |
340/12.53 |
International
Class: |
G08C 17/02 20060101
G08C017/02; G06F 3/041 20060101 G06F003/041 |
Claims
1. A control device configurable to couple to one or more devices
having different control functions comprising: a touch sensitive
display reconfigurable for the different control functions of the
one or more devices; and a processor coupled to the touch sensitive
display, the processor including a plurality of processing
algorithms, the processor configured to receive at least one of the
control functions and additional information from among the one or
more devices, the processor configured to selectably process the
additional information using at least one of the processing
algorithms based on the respective device and to control the touch
sensitive display such that the at least one control function and
the selectably processed additional information peculiar to the
respective device of the one or more devices are presented on the
touch sensitive display, where the processor, responsive to an
indication by the touch sensitive display, generates at least one
control signal, where the processor sends the at least one control
signal to the corresponding device among the one or more devices
being controlled and sends the selectably processed additional
information to at least one of the plurality of devices, and where
the additional information received from among the one or more
devices includes a signal generated from at least one of the
plurality of processing algorithms including a locally transmitted
data signal.
2. The control device of claim 1, wherein the locally transmitted
signal is a signal resulting from analysis by an audio forensic
analysis system.
3. The control device of claim 1, wherein the processor processes
data from either a local biometric sensor or a remote biometric
sensor or both.
4. The control device of claim 1, wherein the processor processes
data from a biometric sensor to detect electro-cardiac signals.
5. The control device of claim 1, wherein the processor processes
data from a biometric sensor for presentation via an auditory
display.
6. The control device of claim 1, wherein the processor processes
data from a biometric sensor and sends data to a heart-rate logging
system using a memory on the control device or on the one or more
devices.
7. The control device of claim 1, wherein the locally transmitted
data signal is a signal from a nearby product vending machine
offering a product or from a particular location or event of
interest matching a user profile.
8. The control device according to claim 1, where the control
device is a piece of jewelry.
9. The control device according to claim 5, where the at least one
control function is received or sent by the processor via at least
one of a wired connection or a wireless connection.
10. The control device according to claim 1 where the processor
generates a plurality of control signals for the one or more
devices.
11. The control device according to claim 1, wherein the control
device includes a low battery warning system that provides a
remaining battery status of the control device or of the one or
more devices.
12. The control device of claim 1, wherein the processor provides
for bi-directional in-situ processing of audio signals by
controlling an ambient microphone coupled to the processor to
record an ambient sound field.
13. The control device of claim 1, wherein the processor
dynamically modifies a user interface of the control device based
on an operating mode of the control device.
14. The control device of claim 1, wherein the locally transmitted
data signal provides heart-rate information transmitted to a
headset system.
15. The control device of claim 14, wherein the heart-rate
information is auralized using head-related transfer function
processing.
16. The control device of claim 14, wherein the touch sensitive
display indicates an operational status of an earphone device
operationally coupled to the control device.
17. A method of facilitating remote control of at least one device
having different control functions comprising: receiving, by a
processor, an instruction for at least one of the control functions
and additional information from the at least one device, the
processor including a plurality of processing algorithms, the
additional information received from the at least one device
including at least a locally transmitted data signal; causing the
processor to selectably process the additional information using at
least one of the processing algorithms and to control a touch
sensitive display reconfigurable for the different control
functions of the at least one device, such that the at least one
control function and the selectably processed additional
information are presented on the touch sensitive display; and
generating at least one control signal by the processor responsive
to receiving the locally transmitted data signal.
18. The method according to claim 17, where the at least one device
includes at least one of a cell phone, a personal media player, a
computer device, a biometric sensor system or a headset.
19. The method according to claim 17, where the at least one
control signal is configured to control at least one of sound
reproduction, sound recording or sound exposure monitoring of the
corresponding device.
20. The method according to claim 17, wherein the locally
transmitted data signal is a signal from a biometric sensor
operatively coupled to the processor.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of U.S. application Ser.
No. 12/111,005 filed on 28 Apr. 2008 and further claims the benefit
of U.S. provisional patent application No. 60/914,319 filed on 27
Apr. 2007, the disclosure of which are both incorporated herein by
reference in their entirety.
FIELD
[0002] The present invention relates to designer control devices,
and in particular, though not exclusively, to a wearing
customizable remote control device.
BACKGROUND
[0003] Several methods and devices have been developed to monitor
the biometrics of a wearer. Additionally, several devices exist to
remotely control some electronic devices (e.g., a TV remote). No
device currently on the market exists that is externally wearer
customizable and configured to control an audio device.
SUMMARY
[0004] At least one exemplary embodiment is directed to a wearable
remote control assembly configured to control media devices and
which may promote brand loyalty, longevity and continuity of a
marketing message, such as a hearing-safety awareness campaign or
music artist. The remote control device may be worn as a finger
ring, badge, broche, or as a bracelet, and may have an appearance
customized by the user with a web-based program, and the appearance
may be dynamically changed using a programmable LED, LCD or plasma
display. The remote control device may contain transducers such as
microphones, loudspeakers, which may be detachable, as well as
biometric sensing systems to monitor user health such as user heart
rate, blood pressure or blood oxygen content. In some exemplary
embodiments, audio signal processing may be undertaken on the
remote control device with a microprocessor. Computer memory housed
in the remote control assembly may also store biometric data such
as personal or security clearance information or data for financial
transactions such as for wireless purchasing, and audio data may
also be stored in RAM computer memory on the remote control
device.
[0005] At least one exemplary embodiment of the present invention
provides for a functional marketing tool that serves as a remote
control device to operate different media devices such as a headset
for sound reproduction or recording. In some embodiments, the
remote control can receive data from biometric sensors such as
heart-rate monitors, and can transmit control data to audio devices
such as Portable Media Players (PMPs) and audio headsets.
[0006] At least one exemplary embodiment of the remote control
system is for a design comprising no user display and a small
number of control buttons. The remote control device in this
particular embodiment is intended to be worn as a finger ring or
bracelet, though could be worn as a pendant from a necklace, around
the user's ankles or upper arm. A marketing logo may be located on
the device, such as an engraving on a bracelet advertising a
particular brand, person, icon or campaign such as a hearing damage
awareness campaign.
[0007] In at least one exemplary embodiment, the remote control
device operates not just level control of reproduced audio content
(e.g. music audio from a PMP or voice audio from a
telecommunications network), but also recording operations using
one or more microphone signals in the headset device. If these
microphones are located substantially near the entrance to the
user's occluded or partly occluded ear canal, then a binaural
recording can be made. Sound recordings can also be made using
microphones housed within the remote control assembly, or connected
to the remote control assembly using a wired or wireless data
communication system.
[0008] At least one exemplary embodiment is directed to a remote
control device that can display a sound exposure profile that takes
into account the sound exposure at the user's eardrum over a recent
history (e.g. the last day). The sound pressure level (SPL) may be
measured empirically using microphones in the user's occluded ear
canal, or externally with microphones at or near to the entrance to
the user's ear canal. The remote control device can display the
"SPL Dose" as a numerical value corresponding to the accumulated
dose as a percentage before temporary or permanent threshold shift
may occur, or it can display a remaining time value, which informs
the user how long (e.g. in minutes) the user has until temporary or
permanent threshold shift may occur based on current ambient sound
levels and levels of reproduced audio content.
[0009] In at least one exemplary embodiment the appearance of the
remote control may be modified dynamically by the user
(customization) or automatically depending on the operating mode to
display different control interface screens or user-defined text
and/or logos or text and/or logos for marketing purposes. This is
accomplished by changing the display of the touch-screen, or
changing the display behind fixed buttons, or changing the colors
of the components used to create the remote control assembly. The
appearance may change dynamically in response to a locally
transmitted data signal, e.g. to inform the user of a nearby
product vending machine or particular location or event which may
be of interest to the user (e.g. a special offer on a product or a
nearby museum).
[0010] In at least one exemplary embodiment the remote control
assembly includes a low battery warning system to inform the user
of the remaining battery status of the remote control device, and
the remaining battery status of other audio devices that the remote
control device communicates with, such as audio headsets, PMPs,
mobile phone. Depending on user specifications, the system either:
presents a series of audio warning signals; updates a visual
display with information and a warning message; automatically
attenuates (attenuation) audio output using the DSP; stops audio
playback entirely; generates a tactile warning (vibration,
pressure, etc); or any combination of the methods described.
[0011] In at least one exemplary embodiment the remote control may
be worn as a wrist-strap bracelet or necklace. In these
embodiments, a provision is made for a biometric sensor, such as a
heart-rate sensor. This may function by detecting micro-electronic
modulations between sensors on either side of the remote control
caused by electro-cardiac signals. In the exemplary embodiment, the
user is provided with a visual display of the current heart-rate,
and a corresponding auditory display. Depending on the operating
mode, this auditory display may be as a simple beep synchronized
with the heart-beat, or it may be in the form of a spatialized
audio scene. For instance, if the user's ideal BPM is higher than
the present BPM, then a spatial sound image (e.g. a beep or
reproduced music) could be spatialized using HRTF processing to
seem in front of the user. Furthermore, the current invention
allows for transmission of the user's current blood-related health
(e.g. heart rate) to be logged and/or transmitted to a second
party, such as an emergency worker or military HQ to inform the
remote party of the health of the user.
[0012] In at least one exemplary embodiment there exists a
loudspeaker for monitoring audio signals transmitted from different
audio devices which are controlled, such as mobile-phones or PMPs.
This allows the user or other individuals to monitor such audio
content without necessarily wearing a headset. Loudspeaker driving
circuitry is housed within the remote control assembly, consisting
of a digital-to-analog converter and analog amplification and
frequency equalization circuitry to compensate for the sensitivity
of the loudspeaker driver. In some embodiments, the loudspeaker
assembly is detachable using a wired connection or self-powered
wireless assembly.
[0013] Yet another exemplary embodiment includes a microphone for
monitoring the local ambient sound field of the remote control
device, and for transmitting the resulting microphone audio signal
to different audio devices such as mobile-phones or PMPs. This
facilitates the user or other individuals to speak directly into a
microphone that may be mounted on the wrist-worn remote control
device, which is especially useful in high-noise environments to
bring the microphone closer to the individual's mouth. The
microphone receiving circuitry is housed within the remote control
assembly, consisting of a digital-to-analog converter and analog
amplification and frequency equalization circuitry to compensate
for the sensitivity of the microphone. In some embodiments, the
microphone assembly is detachable using a wired connection or a
wireless self-powered assembly.
[0014] Further areas of applicability of exemplary embodiments of
the present invention will become apparent from the detailed
description provided hereinafter. It should be understood that the
detailed description and specific examples, while indicating
exemplary embodiments of the invention, are intended for purposes
of illustration only and are not intended to limit the scope of the
invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0015] Exemplary embodiments of present invention will become more
fully understood from the detailed description and the accompanying
drawings, wherein:
[0016] FIG. 1 is an illustration of an earpiece in an ear;
[0017] FIG. 2 is a block diagram of a system in accordance with at
least one exemplary embodiment;
[0018] FIG. 3A is a block diagram of a system connected to an
internet in accordance with at least one exemplary embodiment;
[0019] FIG. 3B is a block diagram of a system that can control
several devices in accordance with at least one exemplary
embodiment;
[0020] FIG. 4A is a block diagram of a system that can control
several devices with access to an internet;
[0021] FIG. 4B is a block diagram of a system that can control
several devices with access to an internet and can access remote
audio data storage;
[0022] FIG. 5 illustrates an example of a wearer piece of jewelry
in accordance with at least one exemplary embodiment; and
[0023] FIG. 6 illustrates a Graphic User Interface (GUI) in
accordance with at least one exemplary embodiment.
DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS
[0024] The following description of exemplary embodiment(s) is
merely illustrative in nature and is in no way intended to limit
the invention, its application, or uses.
[0025] Exemplary embodiments are directed to or can be operatively
used to control various wired or wireless earpieces devices (e.g.,
earbuds, headphones, ear terminal, behind the ear devices or other
acoustic devices as known by one of ordinary skill, and
equivalents). Note that other non-earpiece devices can also be
controlled and the invention is not limited by controlling an
earpiece.
[0026] Processes, techniques, apparatus, and materials as known by
one of ordinary skill in the art may not be discussed in detail but
are intended to be part of the enabling description where
appropriate. For example specific computer code may not be listed
for achieving each of the steps discussed, however one of ordinary
skill would be able, without undo experimentation, to write such
code given the enabling disclosure herein. Such code is intended to
fall within the scope of at least one exemplary embodiment.
[0027] Additionally exemplary embodiments are not limited to
earpieces, for example some functionality can be implemented on
other systems with speakers and/or microphones for example computer
systems, PDAs, BlackBerry.RTM. smartphones, cell and mobile phones,
and any other device that emits or measures acoustic energy.
Additionally, exemplary embodiments can be used with digital and
non-digital acoustic systems. Additionally various receivers and
microphones can be used, for example MEMs transducers, diaphragm
transducers, for example Knowles' FG and EG series transducers.
[0028] Notice that similar reference numerals and letters refer to
similar items in the following figures, and thus once an item is
defined in one figure, it may not be discussed or further defined
in the following figures.
[0029] Encouraging usage of a high-visibility marketing tool for
consumers is enhanced by providing an incentive for the user. The
present invention discloses a marketing device in the form of a
user-wearable badge or item of jewelry that promotes wearability
based upon the device serving functional control of at least one
audio device. Additionally, the invention provides for
bi-directional in-situ processing of audio signals, and provides
the ability to record the user's ambient sound field using one or
more microphones housed within the remote control device, or to
monitor audio content user a loudspeaker that is housed in the
remote control device.
[0030] In at least one exemplary embodiment of the present
invention disclosed herein can undertake audio signal processing
from a first portable media device such as a PMP, and transmits the
processed audio to a second device, such as a headset.
[0031] In at least one exemplary embodiment of the present
invention, this audio signal processing can be bi-directional, i.e.
simultaneously processing audio from a first audio device to a
second whilst processing audio from the second device and then
transmitting this processed signal to the first device. The present
invention furthermore an be designed as a marketing tool whereby
the remote control unit undertaking the signal processing and
controlling the portable media player devices is used to display a
product logo or other insignia.
[0032] At least one exemplary embodiment of the present invention
is designed to promote enhanced visibility for a marketing
campaign, while it can control media devices, and is further
designed to affect functionality of audio devices such as audio
reproduction and recording with a user-worn headset.
[0033] At least one exemplary embodiment of the present invention
allows for activation of recording and subsequent playback of a
user's local ambient sound field using microphones mounted near or
at the entrance to the user's occluded eardrum (in other words; a
binaural recording) or microphones housed within the remote control
device itself.
[0034] At least one exemplary embodiment of the present invention
may simultaneously operate a plurality of devices, and at least one
exemplary embodiment of the present invention can be designed to
operate at least one headset for purposes such as audio recording,
monitoring and reproduction, using loudspeakers and microphones
embedded in the headset and/or loudspeakers and microphones
embedded in the remote control device.
[0035] Furthermore, at least one exemplary embodiment the present
invention can be designed to be worn by the user as jewelry, such
as in the form of a wrist strap or necklace. Also, the remote
control device in the present invention allows for user
customization, such as different colors, different clasp mechanisms
(such as fabric or metallic straps) using a web-based customization
process.
[0036] At least one exemplary embodiment of the present invention
provides for heart-rate information (e.g. beats-per-minute) to be
transmitted to the user-worn headset system and to (optionally)
auralize the auditory display using personalized or
non-personalized head-related transfer function (HRTF) processing.
This could give the effect of spatializing a target or optimum
heart-rate feature (e.g. BPM or blood pressure) so as to act as an
incentive for the user. For instance, if the user's ideal BPM is
higher than the present BPM, then a spatial sound image (e.g. a
beep or reproduced music) could be spatialized using HRTF
processing to seem in front of the user. Furthermore, at least one
exemplary embodiment of the current invention allows for
transmission of the user's current blood-related health (e.g. heart
rate) to be logged and/or transmitted to a second party, such as an
emergency worker or military HQ to inform the remote party of the
health of the user.
[0037] At least one exemplary embodiment is directed to a headset
which can be used with the present invention as is illustrated in
FIG. 1. The embodiment is a small headphone that is inserted in the
ear of the user. The headphone can include the sound-attenuating
earplug 100 inserted into the ear canal. At the inner
(eardrum-facing) surface of the plug, an ear-canal loudspeaker
receiver (ECR) 102 is located for delivering the audio signal to
the listener. At the outer (environment-facing) surface of the
plug, an ambient-sound microphone (ASM) 104 is located. Both the
loudspeaker 102 and the microphone 104 are connected to the
electronic signal processing unit 106. The signal processing unit
106 also has a connector 108 for input of the audio signal. This
connector medium 108 may be a wireless signal such as a
conventional radio or Bluetooth protocol. Additionally, an
ear-canal microphone (ECM) 110 is placed at the inner
(eardrum-facing) surface of the plug and an external loudspeaker
112 is placed on the outer (environment-facing) surface of the plug
for performing other functions of the headphone system not
described here (such as monitoring of sound exposure and ear health
conditions, headphone equalization, headphone fit testing, noise
reduction, and customization).
[0038] FIG. 2 gives an overview of the User Wearable Remote Control
device showing components that may be present or absent depending
on the particular embodiment. The remote control device can
include, as its principle components, a user interface 134, which
may include a miniature keyboard, one or more scroll wheels, push
buttons, or (in the exemplary embodiment) a touch-sensitive screen
that can also be used as a visual display 136, or a combination of
the above. The central processing unit 144 is a general purpose
processor and in some embodiments is combined with an
Application-Specific Integrated Circuit (ASIC) (not shown), or in
some other combination involving a general purpose processor and an
ASIC combined in one unit (such as an FPGA). The processor 144
undertakes control of the transmission of audio input and output
signals to and from the computer memory RAM unit 138, signal
processing for the low battery warning system 140, control and
processing of data from the local (wired) biometric sensor (e.g.
heart-rate detector) 142 or remote, second biometric sensor 143,
and control of the audio and control data communication assembly
146. The processor 144 detects the presence of a power (battery)
charging device such as an inductance or wired charging unit, and
may initiate charging of the built-in battery with system 141.
Computer memory in RAM form 138 for containing user data or audio,
and computer memory in ROM form 139 for storing program code, are
housed in the remote control device assembly.
[0039] In some embodiments there exists a loudspeaker 147 for
monitoring audio signals transmitted from different audio devices
which are controlled, such as mobile-phones or PMPs. This allows
the user or other individuals to monitor such audio content without
necessarily wearing a headset. Loudspeaker driving circuitry 145 is
housed within the remote control assembly, consisting of a
digital-to-analog converter and analog amplification and frequency
equalization circuitry to compensate for the sensitivity of the
loudspeaker driver. In some embodiments, the loudspeaker assembly
is detachable using a wired connection or self-powered wireless
assembly.
[0040] Another embodiment includes a microphone 151 for monitoring
the local ambient sound field of the remote control device, and for
transmitting the resulting microphone audio signal to different
audio devices such as mobile-phones or PMPs. This allows the user
or other individuals to speak directly into a microphone that may
be mounted on the wrist-worn remote control device, which is
especially useful in high-noise environments to bring the
microphone closer to the individual's mouth. The microphone
receiving circuitry 149 is housed within the remote control
assembly, consisting of a digital-to-analog converter and analog
amplification and frequency equalization circuitry to compensate
for the sensitivity of the microphone. In some embodiments, the
microphone assembly is detachable using a wired connection or
wireless self-powered assembly.
[0041] The data communications assembly 146 undertakes control of
audio and non-audio (control) data between the central processor
and other audio devices such as a PMP 148 (FIG. 3B) and one or more
headsets such as that described in FIG. 1. The audio data may be
relayed directly from one device to the other, or may be processed
first by the central processor 144. The communication assembly 146
may consist of either or both wired and wireless communication
devices; such as radio transceivers for Bluetooth or conventional
radio audio and non-audio data transmission and associated signal
processing assemblies (such as ADC and DACs, signal amplifiers etc.
familiar to those skilled in the art), or assemblies for directly
transceiving analog audio signals such as with one or more
conventional stereo 1/8'' input jacks or optical SPDIF input
jacks.
[0042] FIG. 3A gives an overview of the User Wearable Remote
Control device 116 in relation to various audio technology devices
and systems it is intended to be used with. The connections to
these devices and systems are shown as bi-directional or
single-ended arrows. As shown in box legend 132, these arrows may
be double-walled (A, B) or single walled (C,D). The notation used
through the drawings is that mixed audio and control signals are
represented with double-walled arrows, and control-only signals
with single walled. Control signals mean any signal that does not
directly represent audio signals. The direction of the arrow
indicates the direction of audio or control signal flow from one
unit to the other, as familiar to those skilled in the art. Typical
audio devices the remote control device is used with in its
exemplary embodiment are: cell phones 112, headset systems 114 and
122 such as that described in FIG. 1 (but conventional headphone
systems could also be used); user biometric sensors 118; Portable
Media Players 120 such as hard-drive or RAM-chip mp3 players,
digital radio players, portable DVD players or portable electronic
gaming units; and computer devices 124 such as laptops, PDAs, or
desktop computers. The audio devices in the previous list may be
used simultaneously with remote control device 116 and at least one
headset 114, or in any combination thereof. The computer devices
124 may be connected to the internet 126 allowing the user to
upload audio content (from audio content server 129) to a PMP
device 120 via the remote control device 116 or directly from the
computer device 124 to the PMP 120. Audio content may also be
downloaded via computer device 124, the internet 126 to a back-up
audio data server 130. Such audio content may be from recordings
made with ASM signals (from ASM 104 (FIG. 1)), microphones 151
(FIG. 2) housed in the remote control assembly or Ear Canal
Microphone signals (from ECM 110 (FIG. 1)) with one or more
headsets 114, 122. These recorded audio signals may also be
analyzed by an audio forensic analysis system 128 for purposes such
as speech-to-text analysis, or accident determination. Data
analysis by forensic system 128 may be presented to the user via a
visual or auditory display with the remote control device 116. The
optional loudspeaker 147 and microphone 151 housed shown in FIG. 2
are not shown in this figure.
[0043] FIG. 3B gives a more detailed overview of user wearable
remote control device and some particular audio devices described
in the embodiment presented in FIG. 3A, as well as biometric data
analysis system 145. The central processing unit 144 may undertake
audio signal processing on input signals from a number of devices,
such as a cell-phone 112 and/or PMP 148 (e.g. mp3 player, portable
DVD player). FIG. 3B also illustrates that headsets 114, 122 may
include respective input/output (IO) and CPU 150, sound generator
(receiver) 152 and sound sensor (microphone) 154.
[0044] FIGS. 4A and 4B show another embodiment of the remote
control device shown in FIGS. 3A and 3B. The difference between the
two embodiments is that in FIGS. 4A and 4B there is no transmission
of audio signals through the remote control device itself; in this
embodiment the audio signals are transmitted directly between audio
devices such as a PMP 120 and headset 114.
[0045] FIG. 5 shows example artwork of the current invention in a
particular embodiment as a tool for increasing awareness of a
non-commercial listening awareness campaign. In the particular
example, the logo "keep listening" 160 is engraved on the remote
control device bracelet 161, and shows that the user endorses this
campaign and advertises the campaign with a fashionably pleasing
aesthetic. The controls for the device in this particular
embodiment consist of two simple buttons 156, 158 which may be used
to control volume level, power (e.g. by pressing the two buttons
together), or controlling the currently auditioned song track (e.g.
advancing track by holding down button 158). Signal processing and
battery power may be contained within the body of the bracelet 161,
and the control data transmission circuitry may use a wireless
system with the wireless aerial embedded in the user-worn remote
control.
[0046] FIG. 6 gives an overview of a combined user-interface
display and response screen, as might be worn on a wrist band (the
screen may wrap around with a flexible or articulated joint), or as
a necklace pendant. Alternatively, a smaller screen may be used as
shown in the lowest figure. In some embodiments, the screen may be
non touch sensitive, and scrolling wheels and buttons used to
select different operating modes and system control parameters.
ADDITIONAL EXEMPLARY EMBODIMENTS
Exemplary Embodiment Example 1
[0047] 1. At least one exemplary embodiment of the remote control
system for controlling reproduction of audio from a first media
device (such as a PMP) with a second sound reproduction device
(such as a headset). The remote control device can be worn anywhere
on the user's body or attached to the user's clothes. For instance,
the remote control could be worn as a finger ring, arm or leg
bracelet, a pendant for a necklace, or on a waist-belt. A marketing
logo can be incorporated in the device, such as an engraving on a
bracelet advertising a particular brand or public awareness
campaign. Audio signal processing from the first media device may
be undertaken on the remote control device with an embedded ASIC,
and this processed signal transmitted to a second audio
reproduction and/or recording device whilst simultaneously
processing signals from the second device before transmission to
the first device. This user-worn functional jewelry can include:
[0048] A. An attaching device such as a metallic or plastic ring
which may be flexible or contain elastic components to fix the
remote control device to the user's arm, leg or finger, or contain
a clasp to fix to a necklace or waist-belt. [0049] B. A user
interface for controlling media devices such as Portable Media
Players (PMPs) to affect control of these media devices, such as
level of Audio Content, navigation of audio playback and recording
(for example; pause, stop, play, next track, previous track etc.).
[0050] C. A user interface for affecting processing of audio
signals from media devices such as PMPs for purposes such as
frequency equalization, level control, adaptive noise control
filtering. [0051] D. A user interface for controlling audio
reproduction and/or sound recording devices such as at least one
headset worn by either the user or by multiple people including the
user. [0052] E. At least one application-specific integrated
circuit (ASIC) or a general-purpose IC housed within the body of
the user wearable remote control device to undertake either or both
audio signal processing and Control Data processing such as
decision logic and processing the user interface signals. [0053] F.
A Control Data communication system such as a wireless or wired
data transmitter to transfer data. [0054] G. An optional Audio Data
transmission system for controlling audio playback on a first audio
device, or between a plurality of audio devices such as a PMP and a
headset. [0055] H. A Control Data transmission system for functions
such as playback, recording or activation of audio devices such as
PMPs (see part C). [0056] I. A battery power system that can be
recharged using a wireless induction or wired system. [0057] J.
Non-volatile and/or volatile RAM type computer memory. [0058] K.
Non-volatile and/or volatile ROM type computer memory.
Exemplary Embodiment Example 2
[0058] [0059] 2. Another exemplary embodiment includes the system
of embodiment 1, wherein a user visual or auditory display exists
to inform the user of the functional status of the remote control
device and (in some embodiments) the functional status of other
audio devices. This visual display provides the following
functionality; [0060] A. A user display to inform the user of the
audio recording status of the user worn headset, such as the
remaining record time, audio signal bit rate, number of audio
channels, audio signal level and frequency content. This may be as
a visual indicator on a user display and/or an auditory display
system whereby speech or non-speech sounds are generated with
increasing perceptual intrusion (e.g. increasing level) as the
remaining computer memory or hard-disc level of one of these audio
devices decreases. [0061] B. A user display to inform the user of
the audio playback status of the user worn headset, such as audio
signal bit rate, number of audio channels, audio signal level and
frequency content. [0062] C. A visual display to inform other
individuals (i.e. other than the user) that the remote control
device user is listening to Audio Content (Audio Data, e.g. music
or a voice audio signal) and may therefore not wish to be disturbed
or may not be able to hear the other individuals. A different
colored light may be used to represent different user listening
states.
Exemplary Embodiment Example 3
[0062] [0063] 3. Another exemplary embodiment includes the system
of embodiment 1, wherein the at least one sound reproduction device
of part (D) comprises: [0064] A. An earplug that forms a seal in
the ear canal of the user. [0065] B. An earphone body that may be
separate from the earplug that houses the electronic components of
the earphone device. [0066] C. One or more optional pressure
equalization tubes to equalize the pressure on the ear-drum side of
the earplug relative to the ambient pressure. [0067] D. An assembly
to monitor the acoustic field in a user's immediate environment
using one or more Ambient Sound Microphones (ASMs) to monitor sound
at the entrance to one or both occluded ear canals. [0068] E. A
signal processing circuit to amplify the signal from the ASM(s) and
to equalize for the frequency sensitivity of the microphones.
[0069] F. An optional diaphragm to cover the ASM and provide the
following exemplary capabilities: [0070] Passive beam-forming using
holes aligned in a predetermined direction. These holes may be
filled with a material different from the material of the
diaphragm. The directional sensitivity of the ASM may therefore by
increased; e.g. in the direction of the user's mouth or
perpendicular to the direction of the user's head so as to maximize
the degree of electronic separation between ASM signals in opposite
earphone devices (i.e. the left and right earphone of a pair worn
by the same user). [0071] Acoustically tuned sound absorbers to
compensate for the frequency response of the ASM transducers. For
instance, the diaphragm may be configured so as to transmit those
frequencies that the ASM is less sensitive to with less
attenuation. [0072] Wind, headwear-abrasion, dust and debris shield
to protect the ASM. [0073] Use as a marketing tool for displaying a
product brand or logo. [0074] Use as a user interface, e.g. a
button for activating a particular "sound pass-through" mode.
[0075] Use as a display to indicate operational status of the
earphone device using front-lit or backlit illuminating means e.g.
a multicolored LED. [0076] Use as a diaphragm for creating sound to
be monitored by other individuals near the earphone user, using a
sound-creating object coupled to the diaphragm. [0077] G. An
assembly to monitor the acoustic field in an occluded ear canal
consisting of a microphone mounted in an earplug that forms an
acoustic seal of one or both ear canals of a user. (This is the Ear
Canal Microphone; ECM.) [0078] H. A signal processing circuit to
amplify the signal from the ECM and to equalize for the frequency
sensitivity of the ECM. [0079] I. An optional signal processing
circuit to amplify and process an Audio Content input signal (e.g.
from a Personal Media Player, cell phone, or
automatically-generated auditory warning signal). [0080] J. A
microprocessor assembly to undertake digital or analog signal
processing on the ECM and ASM signals for the VOX. [0081] K. A
battery, low-battery warning, and battery charging assembly to
power the electronic circuits in the earphone device. [0082] L. A
wired or wireless communications assembly to transmit audio and/or
control signals to a remote control device. [0083] M. A wired or
wireless communications assembly to transmit audio signals and
control data signals from the ECM and ASM signals from one earphone
device to the other earphone device. [0084] N. A wired or wireless
communications assembly to transmit audio and/or control signals
and control data signals from both earphone devices to an external
system, such as a voice communication system or a second signal
processing unit.
Exemplary Embodiment Example 4
[0084] [0085] 4. Another exemplary embodiment of the present
invention of embodiment 1 additionally comprises sound reproduction
means, such as a loudspeaker, for monitoring audio signals
transmitted from different audio devices that are controlled, such
as mobile-phones or PMPs. This allows the user or other individuals
to monitor such Audio Content without necessarily wearing a
headset. Loudspeaker driving circuitry may be housed within the
remote control assembly. In some exemplary embodiments, the
loudspeaker assembly is detachable using a wired connection or
wireless self-powered assembly.
Exemplary Embodiment Example 5
[0085] [0086] 5. Another exemplary embodiment of the present
invention of embodiment 1 additionally comprises a microphone for
monitoring the local ambient sound field of the remote control
device, and for transmitting the resulting microphone audio signal
to different audio devices such as mobile-phones, computing devices
or PMPs, or for storing the recorded microphone signal on RAM
computer memory embedded within the remote control device. This
allows the user or other individuals to speak directly into a
microphone that may be mounted on the wrist-worn remote control
device, which is especially useful in high-noise environments to
bring the microphone closer to the individual's mouth. The
microphone receiving circuitry is housed within the remote control
assembly, consisting of a digital-to-analog converter and analog
amplification and frequency equalization circuitry to compensate
for the sensitivity of the microphone. In some exemplary
embodiments, the microphone assembly is detachable using a wired
connection or wireless self-powered assembly.
Exemplary Embodiment Example 6
[0086] [0087] 6. Another exemplary embodiment includes the system
of embodiment 1, wherein the system includes a low battery warning
system to inform the user of the remaining battery status of the
remote control device, and the remaining battery status of other
audio devices which the remote control device communicates with,
such as audio headsets, PMPs, mobile phone. Depending on user
specifications, the system either: [0088] A. Presents a series of
audio warning signals. These signals may be stored on computer
memory or on a hard drive in the remote control device or on a
separate media storage device such as a PMP. The signals may be
speech, such as a verbal message indicating remaining battery time
for a particular device, or may be non-speech, such as a bleep. The
auditory warning sound may become increasingly intrusive as the
battery of the particular device loses charge. [0089] B. Updates a
visual display with information and a warning message; [0090] C.
Automatically attenuates (attenuation) audio output using the DSP;
[0091] D. Stops audio playback entirely; [0092] E. Generates a
tactile warning (vibration, pressure, etc); [0093] F. Or any
combination of the methods described above.
Exemplary Embodiment Example 7
[0093] [0094] 7. Another exemplary embodiment for the present
invention embodiment is contrary to the system of embodiment 1 in
that audio signals are not communicated through the remote control
device from a first audio device (e.g. PMP, mobile phone) to a
second, but rather the audio signal is transmitted directly from
the first device to the second, and the remote control affects
audio reproduction by transmitting and receiver audio control
signals (i.e. not Audio Data signals).
Exemplary Embodiment Example 8
[0094] [0095] 8. Another exemplary embodiment for the present
invention embodiment is a mix of the systems of embodiments 1 and 7
whereby some audio signals are communicated through the remote
control device from one audio device (e.g. PMP, mobile phone) to
the headset, but other audio signals may be communicated directly
between audio devices.
Exemplary Embodiment Example 9
[0095] [0096] 9. Another exemplary embodiment of the remote control
device is for controlling the reproduction of audio from a Personal
Media Player (PMP) and the recording of audio signals to the same
PMP. Although only one PMP is used in this embodiment, a plurality
of headsets may be used to reproduce the PMP audio from and to
sample the personal sound field of the headset user(s).
Exemplary Embodiment Example 10
[0096] [0097] 10. Another exemplary embodiment of the remote
control device is for a permanent message to be visible on the
device to increase visibility and show the user's support of a
public service campaign such as hearing-loss awareness or another
health-related campaign.
Exemplary Embodiment Example 11
[0097] [0098] 11. Another exemplary embodiment of the remote
control device is for a user-customizable style, whereby the colors
of components comprising the wearable remote control can be
customized using an online web-based program.
Exemplary Embodiment Example 12
[0098] [0099] 12. Another exemplary embodiment of the remote
control device is for a dynamically changing physical appearance,
whereby a text message and/or audio message and/or logo may be
displayed on a screen on the remote control device. The screen can
be programmed and altered dynamically and may use a plasma screen
display, LED or LCD display. The screen may be dynamically changed
by sensing a signal transmitted from, for example, a vending
machine, a retail store, or a museum.
Exemplary Embodiment Example 13
[0099] [0100] 13. Another exemplary embodiment of the remote
control device is for a detecting a transmitted radio signal from a
"transmitting beacon" and informing the user with an auditory
message transmitted from the remote control device to the headset.
The signal may be transmitted from, for example, a vending machine,
a retail store, or a museum, and the user may be informed using
either a speech-message or non-speech message (e.g. music or a
product signature "Ear-con"). The user may be informed of the
location of the transmitting beacon using either a verbal message
(e.g. informing the user of the street address with an auditory or
visual display message), or with an auditory message which may be
spatialized to help the user locate the transmitting beacon.
Exemplary Embodiment Example 14
[0100] [0101] 14. Another exemplary embodiment of the remote
control device provides for the monitoring and display of the
device-user's heart rate using electro-cardiac sensors mounted on
the device assembly or on a separate assembly. The display uses an
auditory beacon whereby a beep-like pulse is sounded synchronously
with the user's heartbeat. This particular embodiment can include:
[0102] A. A biometric sensor to detect electro-cardiac signals on
the users skin, such as with sensors mounted on either side of the
wrist band housing the remote control device, or on a chest or
upper-arm strap. [0103] B. A visual display to inform the user of
their current cardiac status (e.g. heart rate or blood pressure).
[0104] C. Alternative to or complimentary to the visual display, an
auditory display may be used to inform the user of the heart rate.
This could be with a verbal message informing the user of the heart
rate at a time interval which may be user defined (e.g. every
minute), or the heart rate may be related to a frequency pitch of a
non-verbal message, e.g. a beep (short sine wave) with a pitch that
increases with increasing pulse rate. [0105] D. A heart-rate
logging system whereby the user's heart-rate profile is stored in
computer memory in either the remote control device or on a
separate assembly such as a PMP. [0106] E. A heart-rate data log
communication system, whereby the heart rate profile may be
transmitted using a wired or wireless data communication system
directly to a computing device for analysis and for prognosis and
advice to the user to seek medical consultation if any indication
of cardiac health problems are detected.
Exemplary Embodiment Example 15
[0106] [0107] 15. Another exemplary embodiment includes a spatial
auditory display whereby signal filtering of an audio signal using,
for instance, personalized or semi-personalized Head Related
Transfer Functions (HRTF), may be undertaken to act as an auditory
beacon indicating the user's current and target heart rate. In
addition to the previous embodiment, this particular embodiment
includes: [0108] A. An optional HRTF acquisition process whereby
the user's personal or non-personal HRTF is acquired. There are
many methods for acquiring personalized HRTFs disclosed in prior
art such as using the reciprocity technique. Non-personalized HRTFs
may be acquired by asking the user to select HRTF mixes of audio
recordings according to particular sound characters, such as
perceived separation of audio images or perceived naturalness or
intelligibility (which may be measured with standard
intelligibility tests known to those skilled in the art). [0109] B.
Audio signal processing circuitry to filter audio signals (e.g. a
speech message, music, or beep-pulse which is synchronized with the
user's heart beat) so that the perceived sound image is located at
an ego-centric distance related to the discrepancy between the
user's actual and target heart rate. For instance, if the target
and actual heart-rate are the same, the audio signal processing may
be such that the image is located within the user's head. If the
target is greater than the actual heart-rate, the audio signal
processing may be such that the auditory image is located in front
of the user's head. Such audio signal processing may include
processing the Audio Content with HRTFs measured at different
distances (i.e. ego-centric range) to the user's head. Other
methods of controlling auditory image distance include affecting
the ratio of artificial sound reflections (such as reverberation)
to direct sound (i.e. the original Audio Content).
Exemplary Embodiment Example 16
[0109] [0110] 16. A particular embodiment of the above systems
includes an application-specific integrated circuit (ASIC) within
the remote control assembly for undertaking DSP such as audio
signal filtering for active noise control (familiar to those
skilled in the art), equalization, voice recognition, and non-voice
signal recognition on audio signals from, for instance, microphones
on the user-worn headset, input Audio Content from a PMP or
mobile-phone.
Exemplary Embodiment Example 17
[0110] [0111] 17. Another exemplary embodiment of the present
invention is for controlling video media players, such as portable
DVD players, in addition to simultaneously controlling and
processing audio signals.
Exemplary Embodiment Example 18
[0111] [0112] 18. Another exemplary embodiment includes the system
of embodiment 2, wherein a user visual or auditory display informs
the user of a personal sound exposure history. The sound pressure
level (SPL) may be measured using microphones in the user's
occluded ear canal, or externally with microphones at or near to
the entrance to the user's ear meatus, or in some embodiments using
microphones housed in the remote control device. The remote control
device may display the "SPL Dose" as a numerical value
corresponding to the accumulated dose as a percentage before
temporary or permanent threshold shift may occur, or it may display
a remaining time value, which informs the user how long (e.g. in
minutes) the user has until temporary or permanent threshold shift
may occur based on current ambient sound levels and levels of
reproduced Audio Content.
[0113] While the present invention has been described with
reference to exemplary embodiments, it is to be understood that the
invention is not limited to the disclosed exemplary embodiments.
The scope of the following claims is to be accorded the broadest
interpretation so as to encompass all modifications, equivalent
structures and functions of the relevant exemplary embodiments. For
example, if words such as "orthogonal", "perpendicular" are used
the intended meaning is "substantially orthogonal" and
"substantially perpendicular" respectively. Additionally although
specific numbers may be quoted in the claims, it is intended that a
number close to the one stated is also within the intended scope,
i.e. any stated number (e.g., 90 degrees) should be interpreted to
be "about" the value of the stated number (e.g., about 90
degrees).
[0114] Thus, the description of the invention is merely exemplary
in nature and, thus, variations that do not depart from the gist of
the invention are intended to be within the scope of the exemplary
embodiments of the present invention. Such variations are not to be
regarded as a departure from the spirit and scope of the present
invention.
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