A monitoring system includes a Doppler radar formed with an IEEE 802 protocol transmitter and an IEEE 802 protocol receiver to detect motion, wherein frequency waves are transmitted by the IEEE 802 protocol transmitter and reflected waves are received by the IEEE protocol 802 receiver; and an analyz
A monitoring system includes a Doppler radar formed with an IEEE 802 protocol transmitter and an IEEE 802 protocol receiver to detect motion, wherein frequency waves are transmitted by the IEEE 802 protocol transmitter and reflected waves are received by the IEEE protocol 802 receiver; and an analyzer to perform Doppler operations using the IEEE 802 protocol transmitter and receiver, wherein the analyzer calibrates a training Doppler radar signal during a training phase to develop a model and wherein the analyzer applies the model with the Doppler radar signal during an operational phase to determine position.
대표청구항▼
1. A monitoring system, comprising: a Doppler radar formed with an IEEE 802 protocol transmitter and an IEEE 802 protocol receiver to detect body motion of a person, wherein frequency waves are transmitted by the IEEE 802 protocol transmitter and reflected waves are received by the IEEE 802 protocol
1. A monitoring system, comprising: a Doppler radar formed with an IEEE 802 protocol transmitter and an IEEE 802 protocol receiver to detect body motion of a person, wherein frequency waves are transmitted by the IEEE 802 protocol transmitter and reflected waves are received by the IEEE 802 protocol receiver as part of a multiple input, multiple output (MIMO) wireless adapter chip set coupled to a plurality of antennas and a plurality of radios which send data over two transceivers simultaneously, wherein the Doppler radar is configured to generate an operational Doppler radar signal; andan analyzer configured to perform Doppler operations using the IEEE 802 protocol transmitter and receiver, wherein the analyzer calibrates a training Doppler radar signal with a training body position during a training phase to develop a model and wherein the analyzer is configured to use the model with the operational Doppler radar signal during an operational phase to determine a body position of the person. 2. The system of claim 1, further comprising non-transitory computer medium configured to identify one person from another based on heart rate signature characteristics. 3. The system of claim 1, further comprising one of: an EMG detector, EEG detector, an electromagnetic detector, an ultrasonic detector, an optical detector, a Hidden Markov Model (HMM) recognizer, a dynamic time warp (DTW) recognizer, a neural network, a fuzzy logic engine, or a Bayesian network. 4. The system of claim 1, further comprising a non-transitory computer medium configured to detect patient physical activity patterns and recognize body motion patterns for falls. 5. The system of claim 1, further comprising an in-door positioning system coupled to one or more mesh network appliances to provide location information. 6. The system of claim 1, further comprising a call center coupled to the analyzer to provide a human response. 7. The system of claim 1, wherein the 802 protocol comprises one of: an 802.11_protocol, an 802.15 protocol, an 802.16 protocol, a WiFi protocol, or a WIMAX® (Worldwide Interoperability for Microwave Access) protocol. 8. The system of claim 1, further comprising a wireless router and wherein the wireless router comprises one of: an 802.11 router, an 802.16 router, a WiFi router, a WiMAX® router, a Bluetooth® router, or an X10 router. 9. The system of claim 1, further comprising a mesh network appliance coupled to a power line to communicate X10 data to and from a mesh network. 10. The system of claim 1, further comprising a non-transitory computer medium configured to cause the IEEE 802 transmitter to transmit voice. 11. The system of claim 1, further comprising wireless sensors configured to be positioned on the person that allow a reflected signal to be isolated from radar clutter, and that sense additional body data not derived from the operational Doppler radar signal. 12. The system of claim 1, further comprising a security alarm coupled to the Doppler radar. 13. The system of claim 1, further comprising a non-transitory computer medium to reconstruct an image of a moving object on an opposite side of a wall from the analyzer. 14. The system of claim 1, wherein the analyzer is configured to track arm and leg movements to determine muscle weakness reflective of a health problem. 15. A monitoring system for a person, comprising: a wireless local area network (WLAN) transceiver operating as a Doppler radar to wirelessly detect body movement of the person as part of a multiple input, multiple output (MIMO) wireless adapter, wherein the WLAN transceiver is configured to generate an operational Doppler radar signal; anda processor coupled to the WLAN transceiver to monitor body position, wherein the processor calibrates a training Doppler radar signal with a training body position during a training phase to develop a model and wherein the processor is configured to use the model with the operational Doppler radar signal during an operational phase to estimate body position of the person. 16. The system of claim 15, wherein the processor is configured to detect body movements due to breathing or to heart movement. 17. The system of claim 15, wherein the processor is configured to identify one person from another using each person's rib cage signature. 18. The system of claim 15, wherein the processor is configured to monitor the person for physical activity patterns and recognize body motion patterns leading to falls.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (208)
Siegel John H. (Baltimore MD) Nikias Chrysostomos L. (Needham MA), Advanced signal processing methodology for the detection, localization and quantification of acute myocardial ischemia.
David Daniel (52 Hashalom St. Ranana ILX) David Zipora (52 Hashalom St. Ranana ILX), Ambulatory patient health monitoring techniques utilizing interactive visual communication.
Unger John David (Windham NH) Kolnsberg Mark Edward (Beverly MA) Scholz Wolfgang (Beverly MA), Apparatus and method for providing dual output signals in a telemetry transmitter.
Mickle, Marlin; Gorodetsky, Dimitry; Mats, Leonid; Neureuter, Lorenz; Mi, Minhong; Taylor, Carl; Emahizer, Chad, Apparatus for energizing a remote station and related method.
Jeong, Hyuk; Kim, Hyun Bin; Kim, Ki Ho; Kim, Ki Hong; Kim, Hong Kee; Myung, Hyun; Ghyme, Sang Won; Lee, Ki Suk; Kim, Yong Wan; Choi, Jin Sung, Apparatus for positioning and marking a location of an EMG electrode.
Cox Michael W. (Lincroft NJ) Levin Richard I. (New York NY) Cohen David J. (Sag Harbor NY) Frisbie William R. (East Hampton NY), Cardiac signal real time monitor and method of analysis.
Finneran, Mark T.; Alexander, Kathryn E.; Alexander, B. Russell; Wickham, Jr., Charles E.; Hitchcock, Richard L.; Howard, Scott D., EMG electrode apparatus and positioning system.
Launey Reuel O. (Arlington VA) Grendler Peter A. (Silver Spring MD) Packham Donald L. (Fort Lauderdale FL) Battaglia James M. (Kettering MD) Levine Howard E. (Adelphi MD), Expandable home automation system.
Varshneya, Deepak; Maida, Jr., John L.; Jeffers, Larry A., Fiber optic interferometric vital sign monitor for use in magnetic resonance imaging, confined care facilities and in-hospital.
Braun Jeffrey C. ; Jacobus Charles J. ; Booth Scott ; Suarez Michael ; Smith Derek ; Hartnagle Jeff ; Leprell Glenn, General-purpose medical instrumentation.
Jeffrey C. Braun ; Charles J. Jacobus ; Scott Booth ; Michael Suarez ; Derek Smith ; Jeff Hartnagle ; Glenn Leprell, General-purpose medical istrumentation.
Todd D. Alleckson ; Energy Cruse, II ; Karyn Grant ; Robert C. Leichner ; Gaurang C. Mehta ; James M. Rueter ; Thomas A. Shoup ; Alexander L. Tudor ; Ronald T. Yamada, Home hub for reporting patient health parameters.
Cusimano MaryRose (1050 Whitney Ranch Dr. #3023 Henderson NV 89014) Potorti Michael A. (1050 Whitney Ranch Dr. #3023 Henderson NV 89014), Integrated movement analyzing system.
Kruse John M. (Columbia Heights MN), Low amplitude pacing artifact detection amplifier circuit with driven right leg for filtering high frequency noise cause.
Lang Philipp (San Francisco CA) Wendland Michael (Benicia CA) Saeed Maythem (Novato CA) Gindele Alexander (San Francisco CA), Magnetic resonance imaging technique for tissue characterization.
Garfield Robert E. (Friendswood TX), Method and apparatus for analyzing uterine electrical activity from surface measurements for obstetrical diagnosis.
Garfield Robert E. ; Boyle Mary B., Method and apparatus for analyzing uterine electrical activity from surface measurements for obstetrical diagnosis.
Gelvin, David C.; Girod, Lewis D.; Kaiser, William J.; Merrill, William M.; Newberg, Fredric; Pottie, Gregory J.; Sipos, Anton I.; Vardhan, Sandeep, Method and apparatus for distributed signal processing among internetworked wireless integrated network sensors (WINS).
Jingping Xu CA; Philippe Pibarot CA; Louis-Gilles Durand CA, Method and apparatus for estimating systolic and mean pulmonary artery pressures of a patient.
Tuan Bui ; Thomas Cooper ; Clint Deckert ; Doron Levitas ; Emil S. Macha ; Shan Padda ; Arthur Schulze, Method and apparatus for providing patient care.
Squires Wilber D. (Fountain Valley CA) Bachman John A. (Dana Point CA) Laney Bryan L. (Lakewood CA), Method and apparatus for screening electrocardiographic (ECG) data.
Hoctor, Ralph Thomas; Maalouf, Khalil John; Zheng, Yibin, Method and apparatus for uterine contraction monitoring using linear predictive modeling of abdominal surface EMG signals.
Paul D. Frelburger ; Sankaralingam Ramraj ; Aaron J. Schuman, Method and system for using personal digital assistants with diagnostic medical ultrasound systems.
Toomim Hershel (Los Angeles CA) Kasten John D. (Laguna Niguel CA) Appel Gerald D. (Beverly Hills CA) Levendowski Daniel (Los Angeles CA), Method for determining muscle dysfunction.
Weber Jean-luc M. (Salon de Provence FRX) Confort ; wife Gouny Sylviane M. M. (Marseille FRX), Monitoring system for the remote supervision of a plurality of gravity perfusion sets.
Slovut David P. (Golden Valley MN) Bolman ; III R. M. (Minneapolis MN) Bianco Richard W. (Minneapolis MN) Wenstrom John C. (Salida CO), Noninvasive detection of rejection in heart transplant patients.
Sawchuck Diane J.,CAX ITX V6S 1V2 ; Pinder Kenneth L.,CAX ITX V6S 1W1, Perineometer for domestic use in prevention of urinary incontinence and method of using the same.
Villa-Real Antony-Euclid C. (2512 Capistrano Ave. Las Vegas NV 89121), Pocket-size electronic cuffless blood pressure and pulse rate calculator with optional temperature indicator, timer and.
Jackson Sandra R. (424 W. End Ave. ; Apt. 11B New York NY 10024) Jackson Harry E. (424 W. End Ave. ; Apt. 11B New York NY 10024), Portable blood pressure measuring device and method of measuring blood pressure.
Costello Kevin J. ; Nair Chandra ; Roth Cynthia ; Mitchell Dennis A., Portable electronic data collection apparatus for monitoring musculoskeletal stresses.
Decupper Jean (Les Sous-Bois de Sansovino ; 39 Chemin de Caldana 06400 Cannes FRX), Process and device for monitoring apparatus for emission of electro-magnetic radiations.
Fuchs Wolfgang,DEX ; Hebestreit Klaus,DEX ; Tummler Hanns-Peter,DEX, Process and device for the monitoring and control of the flow of material in a hospital.
Mlynash, Michael D.; Groenewegen, Arne Sippens; Lesh, Michael D., QRST subtraction using an adaptive template for analysis of TU wave obscured atrial activity.
Chen Yunquan (1000-2725 Melfa Road Vancouver ; British Columbia ; V6T 1N4 CAX) Laszlo Charles A. (4750 Belmont Road Vancouver ; British Columbia ; V6T 1A9 CAX) Hershler Cecil (6370 Alma Street Vancou, Recording biological signals using Hilbert transforms.
Wallace Clifford G. (Alameda CA) von Isenburg Carl (Westfield NJ) Chun Michael D. (Bud Lake NJ) Holmberg Kenneth G. (Oakland CA) Bryant Robert T. (San Leandro CA), System & method for monitoring & diagnosing faults in environmentally controlled containers, such system and method bein.
Groenewegen, Arne Sippens, System and method for developing a database of body surface ECG flutter wave data maps for classification of atrial flutter.
Steuer Robert R. ; Miller David R., System and method for measuring blood urea nitrogen, blood osmolarity, plasma free hemoglobin and tissue water content.
Steuer, Robert R.; Miller, David R., System and method for measuring blood urea nitrogen, blood osmolarity, plasma free hemoglobin and tissue water content.
Kutzik David M. ; Glascock Anthony P. ; Chute Douglas L. ; Hewett Thomas T. ; Hornum Barbara G., System for generating periodic reports generating trend analysis and intervention for monitoring daily living activity.
Kutzik David M. (Philadelphia PA) Glascock Anthony P. (Newtown Square PA) Chute Douglas L. (Devon PA) Hewett Thomas T. (Wallingford PA) Hornum Barbara G. (Philadelphia PA), System for generating periodic reports, generating trend analysis, and intervention in accordance with trend analysis fr.
Teller, Eric; Stivoric, John M.; Kasabach, Christopher D.; Pacione, Christopher D.; Moss, John L.; Liden, Craig B.; McCormack, Margaret A., System for monitoring health, wellness and fitness.
Currie, John F.; Paranjape, Makarand; Peck, Carl C.; White, Robert; Schneider, Thomas W., Systems and methods for monitoring health and delivering drugs transdermally.
Peifer John W. ; Hopper Andrew ; Burrow Michael ; Sudduth Barry ; Panchal Samir ; Quay Andy ; Price W. Edward ; Searle John R., Telemedicine system using voice video and data encapsulation and de-encapsulation for communicating medical informatio.
Trivedi Sushma S. (Sunnyale CA) Gur Raquel E. (Philadelphia PA) Gur Ruben (Philadelphia PA), Topographical mapping of brain functionality from neuropsychological test results.
Agre Jonathan R. ; Clare Loren P. ; Marcy ; 5th Henry O. ; Twarowski Allen J. ; Kaiser William ; Mickelson Wilmer A. ; Yakos Michael D. ; Loeffelholz Christian J. ; Engdahl Jonathan R., Wireless integrated sensor network using multiple relayed communications.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.