US2017296773A1PendingUtilityA1
Vibrating pillow strip and operating methods
Est. expiryJun 5, 2034(~7.9 yrs left)· nominal 20-yr term from priority
A61B 2505/07A61M 2230/63A61B 5/4812A61B 2560/0475G05D 23/1393A61B 5/01A61M 2205/3584A61M 2230/50A61M 2205/3306A47G 9/0238G16H 40/67A61M 2205/3592A61B 5/0022G05B 19/0428A61B 5/11A61B 5/4266A47C 31/123A61M 2230/42A61M 2021/0083G08B 6/00A61M 2205/505G05B 2219/2614A61M 2021/0022A61B 5/0816A61M 2230/06A61M 21/02A61M 2205/3368A61M 2205/3673A61M 2205/3303A61M 16/161A61M 2205/3375A61M 2205/50A61M 2205/18A61B 2562/0271A61B 5/7455A61B 5/024A61B 5/6892A61B 2560/0242A47C 21/048A47C 21/00A61B 5/117H05B 1/0272A61M 2205/0294A61M 21/00A61B 2562/063A61B 5/02055A61M 2021/0066A47C 21/044
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Claims
Abstract
Introduced are methods and systems for: gathering human biological signals, such as heart rate, respiration rate, or temperature; analyzing the gathered human biological signals; and controlling a vibrating pillow strip based on the analysis.
Claims
exact text as granted — not AI-modified1 . A system for automatically activating a vibrating pillow strip in response to an alarm setting, said system comprising:
a database configured to store a history of biological signals associated with a user; said vibrating pillow strip, coupled to a pillow associated with said user, said vibrating pillow strip configured to receive a control signal and to vibrate based on said control signal; a computer processor communicatively coupled to said vibrating pillow strip, and said database, said computer processor configured to:
receive a biological signal associated with said user, said biological signal comprising a heart rate associated with said user, a respiration rate associated with said user, a motion associated with said user, or a temperature associated with said user;
identify said user based on at least one of: said heart rate associated with said user, said respiration rate associated with said user, said motion associated with said user, or said temperature associated with said user;
based on said user identification, obtain a wake-up time associated with said user;
based on said history of biological signals and said biological signal, identify a sleep phase associated with said user, said sleep phase comprising a wakefulness phase, a light sleep phase, a deep sleep phase, or a rapid eye movement sleep phase; and
when said sleep phase comprises said light sleep phase and a current time is at most one hour before said wake-up time, send said control signal to said vibrating pillow strip, said control signal comprising an instruction to vibrate.
2 . The system of claim 1 , wherein said history of biological signals comprises a normal heart rate range associated with each sleep phase, a normal respiration rate range associated with each sleep phase, a normal motion range associated with each sleep phase, and a normal temperature range associated with each sleep phase.
3 . A vibrating alarm system comprising:
a vibrating pillow strip, coupled to a pillow associated with a user, said vibrating pillow strip configured to receive a control signal and to vibrate based on said control signal, said vibrating pillow strip comprising:
a plurality of vibrating mini motors, wherein each vibrating mini motor is configured to tend to be unnoticeable when said user rests user's head on said vibrating pillow strip, and further wherein said plurality of vibrating mini motors is configured to tend to wake up the user;
a computer processor communicatively coupled to said vibrating pillow strip, said computer processor configured to:
obtain a wake-up time associated with said user; and
at said wake-up time associated with said user, send said control signal to said vibrating pillow strip.
4 . The system of claim 3 , wherein said vibrating mini motor in said plurality of vibrating mini motors is configured to be at most 100 millimeters 2 in area, and at most 3 mm in thickness.
5 . The system of claim 3 , wherein said vibrating mini motor in said plurality of vibrating mini motors configured to be at least 1 mm away from a neighboring vibrating mini motor.
6 . The system of claim 3 , wherein said vibrating mini motor in said plurality of vibrating mini motors is configured to vibrate at least at 11,000 rotations per minute at 5 volts.
7 . The system of claim 3 , wherein said vibrating pillow strip is coupled to said computer processor via a wireless communication channel.
8 . The system of claim 3 , wherein each vibrating mini motor in said plurality of vibrating mini motors is configured to vibrate synchronously.
9 . The system of claim 3 , said vibrating pillow strip comprising a plurality of zones corresponding to a plurality of users, wherein each zone in said plurality of zones is configured to vibrate independently.
10 . The system of claim 9 , wherein said control signal comprises an identification associated with said zone in said plurality of zones.
11 . The system of claim 3 , said computer processor configured to:
receive a biological signal associated with said user, said biological signal comprising a heart rate associated with said user, a respiration rate associated with said user, a motion associated with said user, or a temperature associated with said user; identify said user based on at least one of: said heart rate associated with said user, said respiration rate associated with said user, said motion associated with said user, or said temperature associated with said user; based on said user identification, obtain said wake-up time associated with said user; based on said biological signal, detect when said user is in a light sleep phase; and when said user is in said light sleep phase and a current time is at most one hour before said wake-up time, send said control signal to said vibrating pillow strip, said control signal comprising an instruction to vibrate.
12 . The system of claim 11 , wherein said computer processor is configured to detect when said user is in said light sleep phase by detecting: a slowdown in said heart rate, a drop in said temperature, and a regular respiration rate.
13 . The system of claim 11 , wherein said computer processor is configured to detect when said user is in said light sleep phase by detecting an end of a rapid eye movement sleep phase.
14 . The system of claim 11 , further comprising a database configured to store a history of biological signals associated with said user, wherein said history of biological signals comprises a normal heart rate range associated with each sleep phase, a normal respiration rate range associated with each sleep phase, a normal motion range associated with each sleep phase, and a normal temperature range associated with each sleep phase.
15 . The system of claim 14 , wherein said computer processor is further configured to:
based on said user identification, retrieve from said database, said history of biological signals associated with said user; and based on said biological signal and said history of biological signals, determine said sleep phase associated with said user.
16 . A method for automatically activating a vibrating pillow strip in response to a biological signal associated with a user, said method comprising:
receiving said biological signal associated with said user, said biological signal comprising a heart rate associated with said user, a respiration rate associated with said user, a motion associated with said user, or a temperature associated with said user; retrieving a history of biological signals associated with said user from a database; identifying said user based on at least one of: said heart rate associated with said user, said respiration rate associated with said user, said motion associated with said user, or said temperature associated with said user; based on said user identification, obtaining a wake-up time associated with said user; based on said history of biological signals and said biological signal, identifying a sleep phase associated with said user, said sleep phase comprising a wakefulness phase, a light sleep phase, a deep sleep phase, or a rapid eye movement sleep phase; and when said sleep phase comprises said light sleep phase and a current time is at most one hour before said wake-up time, sending a control signal to said vibrating pillow strip, said control signal comprising an instruction to vibrate.
17 . The method of claim 16 , comprising configuring said vibrating pillow strip to attach to a pillow, to receive said control signal and to vibrate based on said control signal, said vibrating pillow strip comprising a plurality of zones corresponding to a plurality of users, wherein each zone in said plurality of zones is configured to vibrate independently.
18 . The method of claim 16 , wherein said history of biological signals comprises a normal heart rate range associated with each sleep phase, a normal respiration rate range associated with each sleep phase, a normal motion range associated with each sleep phase, and a normal temperature range associated with each sleep phase.
19 . A method for automatically activating a vibrating alarm system, said method comprising:
configuring a vibrating pillow strip to couple to a pillow associated with a user; configuring said vibrating pillow strip to receive a control signal and to vibrate based on said control signal; coupling a plurality of vibrating mini motors to said vibrating pillow strip, wherein each of vibrating mini motor in said plurality of vibrating mini motors tends to be unnoticeable when a user rests user's head on said vibrating pillow strip, and further wherein said plurality of vibrating mini motors tends to wake up said user; communicatively coupling a computer processor to said vibrating pillow strip; configuring said computer processor to:
obtain a wake-up time associated with said user; and
at said wake-up time associated with said user, send said control signal to said vibrating pillow strip.
20 . The method of claim 19 , wherein said vibrating mini motor in said plurality of vibrating mini motors is configured to be at most 10 mm in diameter, and at most 2.7 mm in thickness.
21 . The method of claim 19 , wherein said vibrating mini motor in said plurality of vibrating mini motors is configured to vibrate at least at 11,000 rotations per minute at 5 volts.
22 . The method of claim 19 , wherein said vibrating mini motor in said plurality of vibrating mini motors is configured to vibrate synchronously.
23 . The system of claim 19 , wherein said vibrating pillow strip is coupled to said computer processor via a wireless personal area network.
24 . The method of claim 19 , said vibrating pillow strip comprising a plurality of zones corresponding to a plurality of users, wherein each zone in said plurality of zones is configured to vibrate independently.
25 . The method of claim 24 , wherein said control signal comprises an identification associated with said zone in said plurality of zones.
26 . The method of claim 19 , said computer processor configured to:
receive a biological signal associated with said user, said biological signal comprising a heart rate associated with said user, a respiration rate associated with said user, a motion associated with said user, or a temperature associated with said user; identify said user based on at least one of: said heart rate associated with said user, said respiration rate associated with said user, said motion associated with said user, or said temperature associated with said user; based on said user identification, obtain said wake-up time associated with said user; based on said biological signal, detect when said user is in a light sleep phase; and when said user is in said light sleep phase and a current time is at most one hour before said wake-up time, send said control signal to said vibrating pillow strip, said control signal comprising an instruction to vibrate.
27 . The method of claim 26 , wherein said computer processor is configured to detect when said user is in said light sleep phase by detecting: a slowdown in said heart rate, a drop in said temperature, and a regular respiration rate.
28 . The method of claim 26 , wherein said computer processor is configured to detect when said user is in said light sleep phase by detecting an end of a rapid eye movement sleep phase.
29 . The method of claim 26 , further comprising a database configured to store a history of biological signals associated with said user, wherein said history of biological signals comprises a normal heart rate range associated with each sleep phase, a normal respiration rate range associated with each sleep phase, a normal motion range associated with each sleep phase, and a normal temperature range associated with each sleep phase.
30 . The method of claim 29 , wherein said computer processor is further configured to:
based on said user identification, retrieve from said database, said history of biological signals associated with said user; and based on said biological signal and said history of biological signals, determine said sleep phase associated with said user.Cited by (0)
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