DETERMINING VEHICULAR WHEEL POSITIONS FROM TIRE PRESSURE MONITORING SYSTEM SIGNALS

US 20180111430A1
Filed: 04/27/2017
Published: 04/26/2018
Est. Priority Date: 10/25/2016
Status: Active Grant

First Claim

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1. A method comprising:

determining a rotation period of a wheel on a vehicle at a sensor module associated with said wheel;

receiving at least one data packet at a receiver unit of said vehicle from said sensor module, said at least one data packet including said rotation period and a unique identifier for said sensor module; and

utilizing, at said receiver unit, said rotation period and said unique identifier to ascertain a first partial localization of said wheel, said first partial localization being one of a steered wheel and a non-steered wheel.

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Abstract

A system includes sensor modules, each associated with a wheel on a vehicle, and a receiver unit. Each sensor module calculates a rotation period associated with the wheel during turn mode vehicular motion and determines rotation direction of the associated wheel during straight vehicular motion. A data packet that includes a unique identifier for the sensor module, the rotation period, and the rotation direction are transmitted from each sensor module for receipt at the receiver unit. The receiver unit determines the steered wheels and non-steered wheels based on the rotation period, and the receiver unit can determine which wheels are on the right side or the left side of the vehicle based on the rotation direction. Knowledge of the steered and non-steered wheels and the rotation direction of the wheels, enables the receiver unit to assign locations of the sensor modules, and hence positions of the wheels of the vehicle.

5 Citations

19 Claims

1. A method comprising:
- determining a rotation period of a wheel on a vehicle at a sensor module associated with said wheel;
  
  receiving at least one data packet at a receiver unit of said vehicle from said sensor module, said at least one data packet including said rotation period and a unique identifier for said sensor module; and
  
  utilizing, at said receiver unit, said rotation period and said unique identifier to ascertain a first partial localization of said wheel, said first partial localization being one of a steered wheel and a non-steered wheel.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The method of claim 1, further comprising:
    - detecting that said vehicle is in a turn mode, said turn mode being one of a right turn and a left turn, wherein said at least one data packet includes said rotation period determined while said vehicle is in said turn mode.
  - 3. The method of claim 1, wherein said rotation period is a first rotation period, said wheel is a first wheel, said sensor module is a first sensor module, said unique identifier is a first unique identifier, said at least one data packet is a first data packet, and said method further comprises:
    - determining a second rotation period of a second wheel on said vehicle at a second sensor module associated with said second wheel; and
      
      receiving a second data packet at said receiver unit from said second sensor module, said second data packet including said second rotation period and a second unique identifier for said second sensor module, wherein said utilizing operation ascertains a second partial localization of said second wheel from said second rotation period and said second unique identifier, said second partial localization, being the other of said steered wheel and said non-steered wheel.
  - 4. The method of claim 3, wherein said utilizing operation comprises:
    - determining that said first rotation period is a shorter duration than said second rotation period; and
      
      ascertaining from said shorter duration of said first rotation period that that said first wheel is said steered wheel and said second wheel is said non-steered wheel.
  - 5. The method of claim 3, further comprising:
    - detecting that said vehicle is in a turn mode, said turn mode being one of a right turn and a left turn, wherein said first data packet includes said first rotation period and second data packet includes said second rotation period each of which are determined when said vehicle is in said turn mode.
  - 6. The method of claim 5, further comprising;
    - determining a third rotation period of a third wheel on said vehicle at a third sensor module associated with said third wheel;
      
      receiving a third data packet at said receiver unit from said third sensor module, said third data packet including said third rotation period and a third unique identifier for said third sensor module wherein said third data packet includes said third rotation period determined when said vehicle is in said turn modedetermining a fourth rotation period of a fourth wheel on said vehicle at a fourth sensor module associated with said fourth wheel; and
      
      receiving a fourth data packet at said receiver unit from said fourth sensor module, said fourth data packet including said fourth rotation period and a fourth unique identifier for said fourth sensor module, wherein said fourth data packet includes said fourth rotation period determined when said vehicle is in said turn mode.
  - 7. The method of claim 6,when said turn mode is said left turn, said utilizing operation further comprises:
    - identifying one of said first, second, third, and fourth rotation periods as having a longest duration;
      
      assigning one of said first, second, third, and fourth wheels associated with said one of said first, second, third, and fourth rotation periods having said longest duration as being said non-steered wheel on a left side of said vehicle;
      
      identifying another one said first, second, third, and fourth rotation periods as having a shortest duration; and
      
      assigning another one of said first, second, third, and fourth wheels associated with said one of said first, second, third, and fourth rotation a having said shortest duration as being said steered wheel on a right side of said vehicle, orwhen said turn mode is said right turn, said utilizing operation further comprises;
      
      identifying one of said first, second, third, and fourth rotation periods as having a longest duration;
      
      assigning one of said first, second, third, and fourth wheels associated with said one of said first, second, third, and fourth rotation periods having said longest duration as being said non-steered wheel on a right side of said vehicle;
      
      identifying another one said first, second, third, and fourth rotation periods as having a shortest duration; and
      
      assigning another one of said first, second, third, and fourth wheels associated with said one of said first, second, third, and fourth rotation periods having said shortest duration as being said steered wheel;
      
      on a left side of said vehicle.
  - 8. The method claim 1, further comprising:
    - at said sensor module determining a rotation direction of said wheel, said at least one data packet including said rotation direction and said unique identifier for said sensor moduleutilizing, at said receiver unit said rotation direction, to determine a further partial localization of said wheel, said further partial localization being one of a first side of said vehicle and a second side of said vehicle; and
      
      assigning said wheel to a position on said vehicle based on said unique identifier for said sensor module and said first and further partial localizations.
  - 9. The method of claim 8, further comprising:
    - detecting that said vehicle is in a non-turning mode, and said at least one data packet includes said rotation direction while said vehicle is in said non-turning mode.
  - 10. The method of claim 8, wherein said utilizing said rotation direction comprises:
    - determining that said further partial localization of said wheel is said first side of said vehicle when said rotation direction of said wheel is a clockwise direction, said first side being a right side of said vehicle from within said vehicle and facing forward; and
      
      determining that said further partial localization of said wheel is said second side of said vehicle, when said rotation direction of said wheel is a counterclockwise direction, said second side being a left side of said vehicle from within said vehicle and facing forward.
  - 11. The method of claim 1, further comprising:
    - assigning said wheel to a position on said vehicle based at least in part on said unique identifier for said sensor module and said first partial localization.

12. A system, comprising:
- a plurality of sensor modules, each of said sensor modules being configured to determine a rotation period for an associated wheel of a plurality of wheels on a vehicle; and
  
  a receiver unit configured to receive data packets from said plurality of sensor modules, each of said data packets including said rotation period and a unique identifier for said sensor module associated with said associated wheel of said plurality of wheels, and said receiver unit-(2 being further configured to utilize said rotation period and said unique identifier within said data packets to ascertain a first partial localization of said associated wheel, said first partial localization being one of a steered wheel and a non-steered wheel.
- View Dependent Claims (13, 14, 15)
- - 13. The system of claim 12, wherein:
    - said each of said sensor includes an accelerometer configured to provide an acceleration signal said acceleration signal, being tangential to a rotational direction of said wheel, said acceleration signal-being utilized to determine said rotation period.
  - 14. The system of claim 12, wherein:
    - said each of said sensor modules a is further configured to determine a rotation direction for said associated one of said plurality of wheels on said vehicle; and
      
      said receiver unit is further configured to receive said rotation direction and said unique identifier for said sensor module, associated said one of said plurality of wheels, and said receiver unit being further configured to utilize said rotation direction to determine a further partial location a of said wheel said further partial localization being one of a first side of said vehicle and a second side of said vehicle, and assign said wheel to a position on said vehicle based on said unique identifier, for said sensor module and said first and further partial localizations.
  - 15. The system of claim 14, wherein said each of said sensor modules comprises:
    - a first accelerometer configured to provide a first acceleration signal, said first acceleration signal being tangential to a rotational direction of said wheel; and
      
      a second accelerometer configured to provide a second acceleration signal-said second acceleration signal corresponding to a radial direction of said wheel, said first and second acceleration signals being used to determine said rotation direction.

16. A method comprising:
- determining a rotation period of a wheel on a vehicle at a sensor module associated with said wheel;
  
  determining a rotation direction of said wheel at said sensor module;
  
  receiving at least one data packet at a receiver unit of said vehicle from said sensor module, said at least one data packet including a unique identifier for said sensor module, said rotation period, and said rotation direction, said at least one data packet including said rotation period determined while said vehicle is in a turn mode, said turn mode being one of a right turn and a left turn, and said at least one data packet including said rotation direction while said vehicle is in a non-turning mode;
  
  utilizing, at said receiver unit, said rotation period and said unique identifier to ascertain a first partial localization of said wheel, said first partial localization being one of a steered wheel and a non-steered wheel of said wheel;
  
  utilizing, at said receiver unit, said rotation direction and said unique identifier to determine a further partial localization of said wheel, said further partial localization being one of a first side of said vehicle and a second side of said vehicle; and
  
  assigning said wheel to a position on said vehicle based on said unique identifier for said sensor module and said first and further partial localizations.
- View Dependent Claims (17, 18, 19)
- - 17. The method of claim 16 wherein said rotation period is a first rotation period, said wheel is a first wheel, said sensor module is first sensor module, said unique identifier is a first unique identifier, and said method further comprises:
    - determining a second rotation period of a second wheel on said vehicle at a second sensor module associated with said second wheel; and
      
      receiving a second data packet at said receiver unit from said second sensor module, said second data packet including said second rotation period and a second unique identifier for said second sensor module, wherein said utilizing said rotation period includes;
      
      determining that said first rotation period is a shorter duration than said second rotation period;
      
      ascertaining from said shorter duration of said first rotation period that that said first wheel is said steered wheel and said second wheel is said non-steered wheel.
  - 18. The method of claim 16 wherein said utilizing said rotation direction comprises:
    - determining that said further partial localization of said wheel is said first side of said vehicle when said rotation direction of said wheel is a clockwise direction, said first side being a right side of said vehicle from within said vehicle and facing forward; and
      
      determining that said further partial localization of said wheel is said second side of said vehicle, when said rotation direction of said wheel is a counterclockwise direction, said second side being a left side of said vehicle from within said vehicle and facing forward.
  - 19. The method of claim 16 wherein said sensor module includes a first accelerometer and a second accelerometer, said first accelerometer being configured to provide a first acceleration signal, said first acceleration signal being tangential to a rotational direction of said wheel, and said second accelerometer being configured to provide a second acceleration signal, said second acceleration signal corresponding to a radial direction of said wheel, and wherein:
    - said determining said rotation period comprises utilizing successive instances of said first acceleration signal to determine said rotation period; and
      
      said determining said rotation direction comprises utilizing successive instances of said first acceleration signal and said second acceleration signal to determine said rotation direction.

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Current Assignee
NXP USA, Inc. (NXP Semiconductors NV)
Original Assignee
NXP USA, Inc. (NXP Semiconductors NV)
Inventors
Muddiman, Matthew Wayne, Chekanov, Albert Stanislavovich, Saint-Jean, Camille Maryse, Baranski, Zbigniew, Munsinger, David Blake

Granted Patent

US 10,259,276 B2
Time in Patent Office

Days
Field of Search
US Class Current
CPC Class Codes

B60C 2019/004   Tyre sensors other than for...

B60C 23/0416   allocating a corresponding ...

B60C 23/0435   Vehicle body mounted circui...

B60C 23/0488   Movement sensor, e.g. for s...

B60C 23/061   by monitoring wheel speed m...

G01M 17/013   Wheels

G01M 17/06   Steering behaviour; Rolling...

DETERMINING VEHICULAR WHEEL POSITIONS FROM TIRE PRESSURE MONITORING SYSTEM SIGNALS

First Claim

1 Assignment

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Accused Products

Abstract

5 Citations

19 Claims

Specification

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DETERMINING VEHICULAR WHEEL POSITIONS FROM TIRE PRESSURE MONITORING SYSTEM SIGNALS

First Claim

1 Assignment

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Subscription Required

0 Petitions

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Accused Products

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Abstract

5 Citations

19 Claims

Specification

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Solutions

Use Cases

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