Force sensing resistor with calibration element and method of manufacturing same
First Claim
1. A force sensing resistor comprising:
- first and second substrates each having inner surfaces, wherein at least one of the substrates is flexible in order to move towards the other one of the substrates in response to an applied force;
a plurality of electrically conductive traces on the inner surface of the first substrate, the traces including a first finger, a common finger, and a calibration finger which together define a contact area on the inner surface of the first substrate;
wherein the first finger, the common finger, and the calibration finger are electrically separated from one another;
a spacer substantially surrounding the contact area and attaching the substrates together such that a cavity separates the inner surfaces of the substrates in the contact area;
a first resistive layer on the inner surface of the second substrate such that the first resistive layer is arranged within the cavity, wherein the common finger and the calibration finger are physically distinct from the first finger and the first resistive layer;
wherein, in response to a force applied to a flexible substrates, the first resistive layer contacts and electrically connects the first finger and the common finger together with a resistance dependent upon resistivity of the first resistive layer and the applied force in order to produce an electrical signal indicative of the applied force; and
a second resistive layer arranged within the cavity such that the second resistive layer contacts and electrically connects the calibration finger and the common finger together with a resistance dependent upon resistivity of the second resistive layer in order to produce an electrical signal indicative of the resistivity of the second resistive layer.
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Accused Products
Abstract
A force sensing resistor includes two substrates. Conductive traces including first, common, and calibration fingers are on the first substrate and define a contact area. A spacer surrounds the contact area and attaches the substrates together such that a cavity separates the substrates in the contact area. A first resistive layer is on the second substrate and arranged within the cavity. In response to a force moving one substrate, the first resistive layer electrically connects the first and common fingers with a resistance dependent upon resistivity of the first resistive layer and the applied force to produce an electrical signal indicative of the applied force. A second resistive layer is arranged within the cavity and electrically connects the calibration and common fingers with a resistance dependent upon resistivity of the second resistive layer to produce an electrical signal indicative of the resistivity of the second resistive layer.
80 Citations
27 Claims
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1. A force sensing resistor comprising:
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first and second substrates each having inner surfaces, wherein at least one of the substrates is flexible in order to move towards the other one of the substrates in response to an applied force; a plurality of electrically conductive traces on the inner surface of the first substrate, the traces including a first finger, a common finger, and a calibration finger which together define a contact area on the inner surface of the first substrate; wherein the first finger, the common finger, and the calibration finger are electrically separated from one another; a spacer substantially surrounding the contact area and attaching the substrates together such that a cavity separates the inner surfaces of the substrates in the contact area; a first resistive layer on the inner surface of the second substrate such that the first resistive layer is arranged within the cavity, wherein the common finger and the calibration finger are physically distinct from the first finger and the first resistive layer; wherein, in response to a force applied to a flexible substrates, the first resistive layer contacts and electrically connects the first finger and the common finger together with a resistance dependent upon resistivity of the first resistive layer and the applied force in order to produce an electrical signal indicative of the applied force; and a second resistive layer arranged within the cavity such that the second resistive layer contacts and electrically connects the calibration finger and the common finger together with a resistance dependent upon resistivity of the second resistive layer in order to produce an electrical signal indicative of the resistivity of the second resistive layer. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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11. A method of forming a force sensing resistor, the method comprising:
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depositing a plurality of electrically conductive traces on an inner surface of a first substrate, the traces including a first finger, a common finger, and a calibration finger which together define a contact area on the inner surface of the first substrate, wherein the first finger, the common finger, and the calibration finger are electrically separated from one another; depositing a first resistive layer on an inner surface of a second substrate, wherein at least one of the first and second substrates are flexible, and wherein the common finger and the calibration finger are physically distinct from the first finger and the resister layer; depositing a second resistive layer on the inner surface of the first substrate such that the second resistive layer contacts and electrically connects the calibration finger and the common finger together with a resistance dependent upon resistivity of the second resistive layer in order to produce an electrical signal indicative of the resistivity of the second resistive layer; attaching an adhesive spacer to the inner surface of one of the substrates such that the adhesive spacer substantially surrounds the contact area; and attaching the first and second substrates together using the adhesive spacer such that a cavity separates the inner surfaces of the first and second substrates in the contact area with the first and second resistive layers being arranged within the cavity such that, in response to a force applied to a flexible one of the substrates, the first resistive layer contacts and electrically connects the first finger and the common finger together with a resistance dependent upon resistivity of the first resistive layer and the applied force in order to produce an electrical signal indicative of the applied force. - View Dependent Claims (12, 13, 14, 15, 16, 17)
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18. A method of forming a plurality of force sensing resistors at a given time, for each force sensing resistor the method comprising:
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depositing a plurality of electrically conductive traces on a bottom portion of a flexible substrate, the traces including a first finger, a common finger, and a calibration finger which together define a contact area and which are electrically separated from one another; depositing a first region of a resistive ink on a top portion of the substrate;
wherein the common finger and the calibration finger are physically distinct from the first finger and the first region of the resistive ink;substantially at the same time as depositing the first region, depositing a second region of the resistive ink on the common finger and the calibration finger such that the second resistive ink region intimately and substantially permanently connects the common finger and the calibration finger with a resistance dependent upon resistivity of the resistive ink in order to produce an electrical signal indicative of the resistivity of the resistive ink; attaching an adhesive spacer to one of the bottom and top portions of the substrate such that the adhesive spacer substantially surrounds the contact area when the bottom and top portions of the substrate are attached together; and attaching the bottom and top portions of the substrate together using the adhesive spacer such that a cavity separates the bottom and top portions of the substrate in the contact area with the first and second resistive ink regions being arranged within the cavity such that, in response to a force applied to a substrate, the first resistive ink region contacts and electrically connects the first finger and the common finger together with a resistance dependent upon the resistivity of the resistive ink and the applied force in order to produce an electrical signal indicative of the applied force. - View Dependent Claims (19, 20)
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21. A force sensing resistor comprising:
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first and second substrates, wherein at least one of the substrates is flexible in order to move in response to an applied force; a plurality of electrically conductive traces on the first substrate, the traces including a first finger, a common finger, and a calibration finger which together define a contact area on the first substrate, wherein the first finger, the common finger, and the calibration finger are electrically separated from one another; a spacer substantially surrounding the contact area and attaching the substrates together such that a cavity separates the substrates in the contact area; a first resistive layer on the second substrate such that the first resistive layer is arranged within the cavity, wherein the common finger and the calibration finger are physically distinct from the first finger and the first resistive layer; wherein, in response to a force applied to a flexible one of the substrates, the first resistive layer contacts and electrically connects the first finger and the common finger together with a resistance; and a second resistive layer arranged within the cavity such that the second resistive layer contacts and electrically connects the calibration finger and the common finger together with a resistance. - View Dependent Claims (22, 23, 24, 25, 26, 27)
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Specification