Motion detection systems and methodologies

US 9,188,487 B2
Filed: 11/15/2012
Issued: 11/17/2015
Est. Priority Date: 11/16/2011
Status: Active Grant

First Claim

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1. A motion detector system comprising:

at least first and second pairs of pyro-electric elements, said first pair of pyro-electric elements including first and second pyro-electric elements, said second pair of pyro-electric elements including third and fourth pyro-electric elements;

a housing enclosing said at least first and second pairs of pyro-electric elements and defining a window, only said first and said third pyro-electric elements viewing a motion detection field of view through said window, said second and fourth pyro-electric elements not viewing said motion detection field of view through said window;

said first and second pyro-electric elements in said first pair of pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said second pyro-electric element from the output of said first pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and second pyro-electric elements, thereby providing a first summed signal output representing activity at a first portion of said motion detection field of view and a first local temperature compensation therefor;

said third and fourth pyro-electric elements in said second pair of pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said fourth pyro-electric element from the output of said third pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said third and fourth pyro-electric elements, thereby providing a second summed signal output representing activity at a second portion of said motion detection field of view and a second local temperature compensation therefor, which second portion is different from said first portion of said motion detection field of view, said first local temperature compensation being independent of said second local temperature compensation; and

a signal processor electrically receiving said first output and said second output and providing an output indication of crossing said motion detection field of view in a given direction by an object having a temperature different from the ambient in said motion detection field of view.

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Abstract

A motion detector system including first and second pairs of pyro-electric elements, electrical interconnections between the pyro-electric elements in the first pair providing a first signal output and local temperature compensation for the elements in the first pair, electrical interconnections between the elements in the second pair providing a second signal output and local temperature compensation for the pyro-electric elements in the second pair, wherein the compensation for the first pair is independent of the compensation for the second pair, a housing enclosing the two pairs of pyro-electric elements and defining a window, only one of the pyro-electric elements in each pair viewing a motion detection field of view through the window, and a signal processor receiving the first and second signal outputs and providing an output indication of crossing the field of view by an object having a temperature different from the ambient in the field of view.

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23 Claims

1. A motion detector system comprising:
- at least first and second pairs of pyro-electric elements, said first pair of pyro-electric elements including first and second pyro-electric elements, said second pair of pyro-electric elements including third and fourth pyro-electric elements;
  
  a housing enclosing said at least first and second pairs of pyro-electric elements and defining a window, only said first and said third pyro-electric elements viewing a motion detection field of view through said window, said second and fourth pyro-electric elements not viewing said motion detection field of view through said window;
  
  said first and second pyro-electric elements in said first pair of pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said second pyro-electric element from the output of said first pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and second pyro-electric elements, thereby providing a first summed signal output representing activity at a first portion of said motion detection field of view and a first local temperature compensation therefor;
  
  said third and fourth pyro-electric elements in said second pair of pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said fourth pyro-electric element from the output of said third pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said third and fourth pyro-electric elements, thereby providing a second summed signal output representing activity at a second portion of said motion detection field of view and a second local temperature compensation therefor, which second portion is different from said first portion of said motion detection field of view, said first local temperature compensation being independent of said second local temperature compensation; and
  
  a signal processor electrically receiving said first output and said second output and providing an output indication of crossing said motion detection field of view in a given direction by an object having a temperature different from the ambient in said motion detection field of view.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
- - 2. A motion detector system according to claim 1 and wherein said signal processor is operative to provide detection of crossing said field of view by an object at an angular velocity of between 1 and 2 degrees per second.
  - 3. A motion detection system according to claim 1 and wherein said signal processor is operative to disregard repeated crossing of said field of view in opposite directions by an object at an angular velocity less than 0.5 degrees per second.
  - 4. A motion detection system according to claim 1 and wherein said signal processor provides an output indication of direction of crossing said field of view by an object having a temperature different from the ambient in said field of view.
  - 5. A motion detection system according to claim 4 and wherein said signal processor provides an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a first general direction and not in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a second general direction opposite to said first general direction.
  - 6. A motion detection system according to claim 4 and wherein said signal processor provides a first output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a first general direction and a second output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a second general direction opposite to said first general direction.
  - 7. A motion detection system according to claim 4 and wherein said signal processor provides an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view and not in respect of a stationary object having a temperature different from the ambient in said field of view.
  - 8. A motion detection system according to claim 4 and wherein said signal processor provides an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view and not in respect of a stationary object outside of said field of view having a temperature different from the ambient in said field of view.
  - 9. A motion detection system according to claim 4 and wherein said signal processor provides an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view and not in respect of repeated back-and-forth crossings of said field of view by an object having a temperature different from the ambient in said field of view.
  - 10. A motion detection system according to claim 4 and wherein said signal processor provides an alarm output indication in respect of crossing said field of view by a human and not in respect of crossing said field of view by a pet.

11. A method for detecting motion, the method comprising:
- enclosing at least first and second pairs of pyro-electric elements, said first pair of pyro-electric elements including first and second pyro-electric elements, said second pair of pyro-electric elements including third and fourth pyro-electric elements;
  
  defining a window, only one of said pyro-electric elements in said first pair and only one of said pyro-electric elements in said second pair viewing a motion detection field of view through said window;
  
  electrically interconnecting between outputs of said first and second pyro-electric elements in said first pair of pyro-electric elements with opposite polarity therebetween, thereby subtracting the output of said second pyro-electric element from the output of said first pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and second pyro-electric elements, thereby providing a first summed signal output representing activity at a first portion of said motion detection field of view and a first local temperature compensation therefor;
  
  electrically interconnecting between outputs of said third and fourth pyro-electric elements in said second pair of pyro-electric elements with opposite polarity therebetween, thereby subtracting the output of said fourth pyro-electric element from the output of said third pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said third and fourth pyro-electric elements, and thereby providing a second summed signal output representing activity at a second portion of said motion detection field of view and a second local temperature compensation therefor, which second portion is different from said first portion of said motion detection field of view, said first local temperature compensation being independent of said second local temperature compensation; and
  
  electrically receiving said first output and said second output and providing an output indication of crossing said motion detection field of view in a given direction by an object having a temperature different from the ambient in said motion detection field of view.
- View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19, 20)
- - 12. A method according to claim 11 and wherein said providing an output indication is responsive to detection of crossing said field of view by an object at an angular velocity of between 1 and 2 degrees per second.
  - 13. A method according to claim 11 and also comprising disregarding repeated crossing of said field of view in opposite directions by an object at an angular velocity less than 0.5 degrees per second.
  - 14. A method according to claim 11 and also comprising providing an output indication of direction of crossing said field of view by an object having a temperature different from the ambient in said field of view.
  - 15. A method according to claim 14 and also comprising providing an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a first general direction and not in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a second general direction opposite to said first general direction.
  - 16. A method according to claim 14 and also comprising providing a first output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a first general direction and a second output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view in a second general direction opposite to said first general direction.
  - 17. A method according to claim 14 and also comprising providing an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view and not in respect of a stationary object having a temperature different from the ambient in said field of view.
  - 18. A method according to claim 14 and also comprising providing an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view and not in respect of a stationary object outside of said field of view having a temperature different from the ambient in said field of view.
  - 19. A method according to claim 14 and also comprising providing an alarm output indication in respect of crossing said field of view by an object having a temperature different from the ambient in said field of view and not in respect of repeated back-and-forth crossings of said field of view by an object having a temperature different from the ambient in said field of view.
  - 20. A method according to claim 14 and also comprising providing an alarm output indication in respect of crossing said field of view by a human and not in respect of crossing said field of view by a pet.

21. A pyro-electric sensor comprising:
- at least first and second pairs of pyro-electric elements, said first pair of pyro-electric elements including first and second pyro-electric elements, said second pair of pyro-electric elements including third and fourth pyro-electric elements;
  
  a housing enclosing said at least first and second pairs of pyro-electric elements and defining a window, only said first and said third pyro-electric elements viewing a motion detection field of view through said window, said second and fourth pyro-electric elements not viewing said motion detection field of view through said window;
  
  said first and second-pyro-electric elements in said first pair of pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said second pyro-electric element from the output of said first pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and second pyro-electric elements, thereby providing a first summed signal output representing activity at a first portion of said motion detection field of view and a first local temperature compensation therefor; and
  
  said third and fourth-pyro-electric elements in said second pair of pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said fourth pyro-electric element from the output of said third pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said third and fourth pyro-electric elements, thereby providing a second summed signal output representing activity at a second portion of said motion detection field of view and a second local temperature compensation therefor, which second portion is different from said first portion of said motion detection field of view, said first local temperature compensation being independent of said second local temperature compensation.

22. A method for pyro-electric sensing, the method comprising:
- enclosing at least first and second pairs of pyro-electric elements, said first pair of pyro-electric elements including first and second pyro-electric elements, said second pair of pyro-electric elements including third and fourth pyro-electric elements;
  
  defining a window, only one of said pyro-electric elements in said first pair and only one of said pyro-electric elements in said second pair viewing a motion detection field of view through said window;
  
  electrically interconnecting between outputs of said first and second pyro-electric elements in said first pair of pyro-electric elements with opposite polarity therebetween, thereby subtracting the output of said second pyro-electric element from the output of said first pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and second pyro-electric elements, thereby providing a first summed signal output representing activity at a first portion of said motion detection field of view and a first local temperature compensation therefor;
  
  electrically interconnecting between outputs of said third and fourth pyro-electric elements in said second pair of pyro-electric elements with opposite polarity therebetween, thereby subtracting the output of said fourth pyro-electric element from the output of said third pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said third and fourth pyro-electric elements, thereby providing a second summed signal output representing activity at a second portion of said motion detection field of view and a second local temperature compensation therefor, which second portion is different from said first portion of said motion detection field of view, said first local temperature compensation being independent of said second local temperature compensation.

23. A motion detector system comprising:
- first and second pyro-electric elements, viewing a motion detection field of view;
  
  at least a third pyro-electric element, not viewing said motion detection field of view;
  
  a housing enclosing said first, second and third pyro-electric elements and defining a window, only said first and said second pyro-electric elements viewing said motion detection field of view through said window;
  
  said first and at least third pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said at least third pyro-electric element from the output of said first pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and said at least third pyro-electric elements, thereby providing a first summed signal output representing activity at a first portion of said motion detection field of view and a first local temperature compensation therefor;
  
  said second and at least third pyro-electric elements being electrically connected with opposite polarity therebetween, thereby subtracting the output of said at least third pyro-electric element from the output of said second pyro-electric element and thereby cancelling out temperature changes taking place within said housing, which are simultaneously sensed by said first and said at least third pyro-electric elements, thereby providing a second summed signal output representing activity at a second portion of said motion detection field of view and a second local temperature compensation therefor, said first local temperature compensation being independent of said second local temperature compensation; and
  
  a signal processor electrically receiving said first output and said second output and providing an output indication of crossing said motion detection field of view by an object having a temperature different from the ambient in said motion detection field of view.

Specification

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Litigation Campaign Assessment

Current Assignee
Tyco Fire & Security GmbH (Johnson Controls International plc)
Original Assignee
Tyco Fire & Security GmbH (Johnson Controls International plc)
Inventors
Zhevelev, Boris, Kotlicki, Yaacov, Lahat, Michael
Primary Examiner(s)
Makiya, David J
Assistant Examiner(s)
Jo, Taeho

Application Number

US13/677,851
Publication Number

US 20130119253A1
Time in Patent Office

1,097 Days
Field of Search

250/338.3
US Class Current

1/1
CPC Class Codes

G01J 5/34 using capacitors, e.g. pyro...

G08B 13/191 using pyroelectric sensor m...

Motion detection systems and methodologies

First Claim

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23 Claims

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Motion detection systems and methodologies

First Claim

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Abstract

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Specification

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