WEARABLE SYSTEM FOR MONITORING STRENGTH TRAINING

US 20110092337A1
Filed: 10/17/2009
Published: 04/21/2011
Est. Priority Date: 10/17/2009
Status: Active Grant

First Claim

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1. An exercise monitoring system comprising:

a communications network;

a wearable transducer configured to generate physiologic data associated with movement of a wearer, and to form a communication link with the communications network;

a system memory in which command instructions are stored;

a user interface operably connected to the computer; and

a system processor configured to execute the command instructions to receive the generated physiologic data,analyze the received physiologic data with a multilayer perceptron/support vector machine/hidden Markov (MSH) model,model the analyzed physiologic data, andgenerate feedback based on a comparison of the model and a stored exercise object.

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Abstract

An exercise monitoring method and system in one embodiment includes a communications network, a wearable transducer configured to generate physiologic data associated with movement of a wearer, and to form a communication link with the communications network, a system memory in which command instructions are stored, a user interface operably connected to the computer, and a system processor configured to execute the command instructions to receive the generated physiologic data, analyze the received physiologic data with a multilayer perceptron/support vector machine/hidden Markov (MSH) model, model the analyzed physiologic data, and generate feedback based on a comparison of the model and a stored exercise object.

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20 Claims

1. An exercise monitoring system comprising:
- a communications network;
  
  a wearable transducer configured to generate physiologic data associated with movement of a wearer, and to form a communication link with the communications network;
  
  a system memory in which command instructions are stored;
  
  a user interface operably connected to the computer; and
  
  a system processor configured to execute the command instructions to receive the generated physiologic data,analyze the received physiologic data with a multilayer perceptron/support vector machine/hidden Markov (MSH) model,model the analyzed physiologic data, andgenerate feedback based on a comparison of the model and a stored exercise object.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The system of claim 1, wherein the wearable transducer is activated in response to the wearable transducer sensing movement of the wearer.
  - 3. The system of claim 1, the wearable transducer includes:
    - an actuator interface configured to provide the generated feedback to the wearer;
      
      at least one sensor configured to sense physiologic data associated with movement of the wearer;
      
      a signal processing circuit configured to pre-process data from the at least one sensor and to post-process data for the actuator;
      
      a transducer processor configured to process the pre-processed sensor data and to provide processed feedback data to the signal processing circuit; and
      
      a network interface configured to provide communication with the communications network.
  - 4. The system of claim 3, wherein the transducer processor is further configured to transmit the processed sensor data via the network interface to the system processor and to receive the feedback data from the system processor via the network interface.
  - 5. The system of claim 4, wherein the actuator interface provides the generated feedback data by at least one of a tactile-vibrational scheme, an audible scheme, and a thermal feedback scheme.
  - 6. The system of claim 3, the wearable transducer further includes:
    - a transducer memory in which configuration information of the at least one sensor is stored; and
      
      a radio frequency communication circuit configured to link the wearable transducer to a plurality of other wearable transducers over an industrial, scientific, and medical frequency band.
  - 7. The system of claim 6, wherein the radio frequency communication circuit is configured to use a BLUETOOTH protocol.
  - 8. The system of claim 1, wherein the MSH model is configured to:
    - determine a change in a x-axis orientation of the wearable transducer;
      
      determine a change in a y-axis orientation of the wearable transducer;
      
      determine a change in a z-axis orientation of the wearable transducer; and
      
      determine a change in a three dimensional velocity of the wearable transducer.
  - 9. The system of claim 8, wherein the MSH model is further configured to:
    - determine parameters of human motion kinematics based on the physiologic data generated by the wearable transducer; and
      
      determine parameters of human motion dynamics based on the physiologic data generated by the wearable transducer.
  - 10. The system of claim 9, wherein the generated feedback data is based on a difference between the modeled analyzed physiologic data and an optimal performance data associated with an exercise routine.
  - 11. The system of claim 10, wherein the difference includes a quantitative comparison and a qualitative comparison.

12. A method of monitoring physiologic data associated with an exercise routine performed by a user, comprising:
- generating physiologic data;
  
  receiving the generated physiologic data;
  
  analyzing the received physiologic data;
  
  modeling the analyzed physiologic data; and
  
  generating feedback based on a comparison of the model and a stored exercise object.
- View Dependent Claims (13, 14, 15, 16)
- - 13. The method of claim 12, wherein analyzing the received physiologic data comprises:
    - analyzing the received physiologic data with a multilayer perceptron/support vector machine/hidden Markov (MSH) model.
  - 14. The method of claim 13, wherein analyzing the received physiologic data with the MSH model comprises:
    - determining a change in a x-axis orientation of the plurality of parts of a user;
      
      determining a change in a y-axis orientation of the plurality of parts of the user;
      
      determining a change in a z-axis orientation of the plurality of parts of the user;
      
      determining a change in a three dimensional velocity of the plurality of parts of the user;
      
      determining a range of motion based on the physiologic data;
      
      determining the strength of a muscle based on the physiologic data; and
      
      recommending a corrective action.
  - 15. The method of claim 12, wherein generating feedback based upon the model comprises:
    - generating feedback based on a difference between the modeled analyzed physiologic data and an optimal performance data associated with an exercise routine.
  - 16. The model of claim 15, wherein the difference includes a quantitative comparison and a qualitative comparison.

17. A method of monitoring physiologic data associated with an exercise routine performed by a user, comprising:
- selecting an exercise routine;
  
  receiving an exercise object for a model exercise routine associated with the selected exercise routine;
  
  transmitting physiologic data associated with sensed physiologic conditions of a user;
  
  analyzing the transmitted physiologic data;
  
  generating a model based on the analyzed transmitted physiologic data;
  
  comparing the exercise object with the model; and
  
  generating selective feedback based on the comparison.
- View Dependent Claims (18, 19, 20)
- - 18. The method of claim 17, wherein analyzing the transmitted physiologic data comprises:
    - analyzing the transmitted physiologic data with a multilayer perceptron/support vector machine/hidden Markov (MSH) model.
  - 19. The method of claim 18, wherein analyzing the transmitted physiologic data with the MSH model comprises:
    - determining a change in a x-axis orientation of the plurality of parts of the user;
      
      determining a change in a y-axis orientation of the plurality of parts of the user;
      
      determining a change in a z-axis orientation of the plurality of parts of the user;
      
      determining a change in a three dimensional velocity of the plurality of parts of the user;
      
      determining a range of motion based on the physiologic data; and
      
      determining the strength of a muscle based on the physiologic data.
  - 20. The method of claim 17, wherein generating selective feedback based on the comparison comprises:
    - generating selective feedback based on a difference between the modeled analyzed physiologic data and an optimal performance data associated with an exercise routine, wherein the difference includes a quantitative comparison and a qualitative comparison.

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Current Assignee
Robert Bosch GmbH
Original Assignee
Robert Bosch GmbH
Inventors
Kapoor, Rahul, Andrews, Burton W., Heit, Juergen, Gacic, Aca, Srinivasan, Soundararajan

Granted Patent

US 8,500,604 B2
Time in Patent Office

Days
Field of Search
US Class Current

482/8
CPC Class Codes

A63B 2024/0012   Comparing movements or moti...

A63B 2024/0068   Comparison to target or thr...

A63B 2024/0071   Distinction between differe...

A63B 2024/0078   Exercise efforts programmed...

A63B 2071/0625   Emitting sound, noise or music

A63B 2071/0647   Visualisation of executed m...

A63B 2071/0655   Tactile feedback

A63B 2220/12   Absolute positions, e.g. by...

A63B 2220/17   Counting, e.g. counting per...

A63B 2220/18   Inclination, slope or curva...

A63B 2220/20   Distances or displacements

A63B 2220/30   Speed

A63B 2220/40   Acceleration

A63B 2220/51   Force

A63B 2220/58   Measurement of force relate...

A63B 2220/836   Sensors arranged on the bod...

A63B 2225/20   with means for remote commu...

A63B 2225/50   Wireless data transmission,...

A63B 2230/00   Measuring physiological par...

A63B 2230/06   heartbeat rate only

A63B 2230/207 : P-O2, i.e. partial O2 value

A63B 2230/42 : rate

A63B 2230/50 : temperature

A63B 2230/75 : calorie expenditure

A63B 24/0006 : Computerised comparison for...

A63B 24/0062 : Monitoring athletic perform...

A63B 24/0075 : Means for generating exerci...

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WEARABLE SYSTEM FOR MONITORING STRENGTH TRAINING

First Claim

1 Assignment

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Abstract

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20 Claims

Specification

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WEARABLE SYSTEM FOR MONITORING STRENGTH TRAINING

First Claim

1 Assignment

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Accused Products

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Abstract

Citations

20 Claims

Specification

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