Abstract: A fingerprint sensor may include a substrate, and a finger sensing IC on the substrate and including a finger sensing area on an upper surface thereof for sensing an adjacent finger. The fingerprint sensor may include an encapsulating material on the finger sensing IC and covering the finger sensing area, and a bezel adjacent the finger sensing area and on an uppermost surface of the encapsulating layer.

Abstract: A fingerprint sensor may include a substrate, and a finger sensing IC on the substrate and including a finger sensing area on an upper surface thereof for sensing an adjacent finger. The fingerprint sensor may include an encapsulating material on the finger sensing IC and covering the finger sensing area, and a bezel adjacent the finger sensing area and on an uppermost surface of the encapsulating layer.

Abstract: A finger sensor may include a finger sensing integrated circuit (IC) having a finger sensing area and at least one bond pad adjacent thereto, and a flexible circuit coupled to the IC finger sensor. More particularly, the flexible circuit may include a flexible layer, and at least one conductive trace carried thereby and coupled to the at least one bond pad. The sensor may also include at least one Electrostatic Discharge (ESD) electrode carried by the flexible layer. The ESD electrode may be positioned adjacent a beveled edge, for example, of an IC carrier and thereby exposed through a small gap between an adjacent portion of a frame.

Abstract: A finger sensor may include a finger sensing integrated circuit (IC) having a finger sensing area and at least one bond pad adjacent thereto, and a flexible circuit coupled to the IC finger sensor. The flexible circuit may include a flexible layer covering both the finger sensing area and the at least one bond pad, and at least one conductive trace carried by the flexible layer and coupled to the at least one bond pad. The flexible layer may permit finger sensing therethrough. The flexible circuit may include at least one connector portion extending beyond the finger sensing area and the at least one bond pad. For example, the connector portion may include a tab connector portion and/or a ball grid array connector portion. A fill material, such as an epoxy, may be provided between the IC finger sensor and the flexible circuit.

Abstract: A finger sensor may include a finger sensing integrated circuit (IC) having a finger sensing area, an IC carrier having a cavity receiving the finger sensing IC therein and having at least one beveled upper edge, and a frame surrounding at least a portion of an upper perimeter of the IC carrier and having at least one inclined surface corresponding to the at least one beveled upper edge of the IC carrier. The finger sensor may also include a biasing member for biasing the IC carrier into alignment within the frame. The biasing member may include at least one resilient body for biasing the IC carrier upward within the frame. In other embodiments, the finger sensor may include an IC carrier having a cavity receiving the finger sensing IC therein and having at least one laterally extending projection.

Abstract: A finger sensor may include a finger sensing integrated circuit (IC) having a finger sensing area, an IC carrier having a cavity receiving the finger sensing IC therein and having at least one beveled upper edge, and a frame surrounding at least a portion of an upper perimeter of the IC carrier and having at least one inclined surface corresponding to the at least one beveled upper edge of the IC carrier. The finger sensor may also include a biasing member for biasing the IC carrier into alignment within the frame. The biasing member may include at least one resilient body for biasing the IC carrier upward within the frame. In other embodiments, the finger sensor may include an IC carrier having a cavity receiving the finger sensing IC therein and having at least one laterally extending projection.

Abstract: A finger sensor may include a finger sensing integrated circuit (IC) having a finger sensing area, an IC carrier having a cavity receiving the finger sensing IC therein and having at least one beveled upper edge, and a frame surrounding at least a portion of an upper perimeter of the IC carrier and having at least one inclined surface corresponding to the at least one beveled upper edge of the IC carrier. The finger sensor may also include a biasing member for biasing the IC carrier into alignment within the frame. The biasing member may include at least one resilient body for biasing the IC carrier upward within the frame. In other embodiments, the finger sensor may include an IC carrier having a cavity receiving the finger sensing IC therein and having at least one laterally extending projection.

Abstract: A fingerprint sensor may include a plurality of electrostatic discharge (ESD) electrodes carried by a dielectric layer of a fingerprint sensing portion. The fingerprint sensing portion is for sensing a fingerprint of a user. The fingerprint sensing portion may include the dielectric layer, and, in some embodiments, may also include an array of sensing electrodes also carried by the dielectric layer. Accordingly, each ESD electrode may be interposed between adjacent sensing electrodes. The ESD electrodes attract ESD events and dissipate the energy therein to avoid damaging adjacent sensing electrodes and/or portions of the dielectric layer. The fingerprint sensor may also include an electrically conductive layer connected to the ESD electrodes, which may provide a convenient ground plane, for example, for removing ESD energy from the fingerprint sensor. The electrically conductive layer may extend beneath the sensing electrodes.

Abstract: A method for making an IC package preferably includes providing a mold including first and second mold portions, and wherein the first mold portion carries a mold protrusion defining an IC-contact surface with peripheral edges and a bleed-through retention channel positioned inwardly from the peripheral edges. The method also preferably includes closing the first and second mold portions around the IC and injecting encapsulating material into the mold to encapsulate the IC and make the IC package having an exposed portion of the IC adjacent the mold protrusion. Morever, the bleed-through retention channel retains any encapsulating material bleeding beneath the peripheral edges of the IC contact surface, and prevents the encapsulating material from reaching further onto the exposed portion of the IC. The method may also include releasing the IC package with the exposed portion from the mold.

Abstract: An IC package preferably includes an IC and encapsulating material surrounding the IC, with the encapsulating material having an opening therein to define an exposed portion of the IC. Vestigial portions of encapsulating material may be left on the exposed portion of the IC and spaced inwardly from a periphery of the opening based upon molding using a mold protrusion which includes a bleed-through retention channel positioned inwardly from peripheral edges. The channel collects and retains any bleed-through of the encapsulating material. The IC package may further include a leadframe carrying the IC. The leadframe may include a die pad, finger portions, and a plurality of die pad support bars. The die pad may be downset below a level of the finger portions. Each of the die pad support bars may be resiliently deformed to accommodate the downset of the die pad. Low stress encapsulating material and adhesive may also be included in the IC package.

Abstract: A fingerprint sensor may include a plurality of electrostatic discharge (ESD) electrodes carried by a dielectric layer of a fingerprint sensing portion. The fingerprint sensing portion is for sensing a fingerprint of a user. The fingerprint sensing portion may include the dielectric layer, and, in some embodiments, may also include an array of sensing electrodes also carried by the dielectric layer. Accordingly, each ESD electrode may be interposed between adjacent sensing electrodes. The ESD electrodes attract ESD events and dissipate the energy therein to avoid damaging adjacent sensing electrodes and/or portions of the dielectric layer. The fingerprint sensor may also include an electrically conductive layer connected to the ESD electrodes, which may provide a convenient ground plane, for example, for removing ESD energy from the fingerprint sensor. The electrically conductive layer may extend beneath the sensing electrodes.

Abstract: A fingerprint sensor package includes a fingerprint sensing integrated circuit within a housing and comprising a plurality of electric field sensing electrodes and processing circuitry connected thereto. At least one external electrode is carried by the housing for finger contact. An electrostatic discharge (ESD) circuit is provided within the housing and is connected to the at least one external electrode. An isolation circuit is connected to the at least one line of the processing circuitry for external connection. The external electrode and ESD circuit, as well as the line isolation circuit protect the integrated circuit against damage by voltage transients, such as ESD. The at least one external electrode may include first and second external electrodes. The first electrode may be connected to the electrostatic discharge circuit.

Abstract: An IC package preferably includes an IC and encapsulating material surrounding the IC, with the encapsulating material having an opening therein to define an exposed portion of the IC. Vestigial portions of encapsulating material may be left on the exposed portion of the IC and spaced inwardly from a periphery of the opening based upon molding using a mold protrusion which includes a bleed-through retention channel positioned inwardly from peripheral edges. The channel collects and retains any bleed-through of the encapsulating material. The IC package may further include a leadframe carrying the IC. The leadframe may include a die pad, finger portions, and a plurality of die pad support bars. The die pad may be downset below a level of the finger portions. Each of the die pad support bars may be resilient deformed to accommodate the downset of the die pad. Low stress encapsulating material and adhesive may also be included in the IC package.

Abstract: A method for making an IC package preferably includes providing a mold including first and second mold portions, and wherein the first mold portion carries a mold protrusion defining an IC-contact surface with peripheral edges and a bleed-through retention channel positioned inwardly from the peripheral edges. The method also preferably includes closing the first and second mold portions around the IC and injecting encapsulating material into the mold to encapsulate the IC and make the IC package having an exposed portion of the IC adjacent the mold protrusion. Morever, the bleed-through retention channel retains any encapsulating material bleeding beneath the peripheral edges of the IC contact surface, and prevents the encapsulating material from reaching further onto the exposed portion of the IC. The method may also include releasing the IC package with the exposed portion from the mold.

Abstract: A fingerprint sensor includes an integrated circuit die and a protective covering of a z-axis anisotropic dielectric material. The die includes a conductive layer defining an array of electric field sensing electrodes. The z-axis anisotropic dielectric layer focusses an electric field at each of the electric field sensing electrodes. In other words, the dielectric covering may be relatively thick, but not result in defocussing of the electric fields propagating through the dielectric covering because of the z-axis anisotropy of the material. The z-axis anisotropic dielectric layer may be provided by a plurality of oriented dielectric particles in a cured matrix. For example, the z-axis anisotropic dielectric layer may comprise barium titanate in a polyimide matrix. The conductive layer preferably comprises a plurality of capacitive coupling pads for permitting capacitive coupling with the integrated circuit die.

Abstract: A fingerprint and token sensor system includes an array of fingerprint sensing elements for generating signals related to a fingerprint based upon a finger being positioned adjacent the sensing elements, and a token for also causing the sensing elements to generate signals related to a token message based upon the token being positioned adjacent the sensing elements. Accordingly, the single sensor may be used for both fingerprints and for reading data from a token for range of useful purposes. Each fingerprint sensing element may preferably include an electric field sensing electrode, and a shield associated with a respective electric field sensing electrode. A drive circuit may be connected to the array of electric field sensing electrodes for driving same. The sensor is preferably in the form of an integrated circuit and includes a substrate adjacent the array of fingerprint sensing elements.

Abstract: A fingerprint and token sensor system includes an array of fingerprint sensing elements for generating signals related to a fingerprint based upon a finger being positioned adjacent the sensing elements, and a token for also causing the sensing elements to generate signals related to a token message based upon the token being positioned adjacent the sensing elements. Accordingly, the single sensor may be used for both fingerprints and for reading data from a token for range of useful purposes. Each fingerprint sensing element may preferably include an electric field sensing electrode, and a shield associated with a respective electric field sensing electrode. A drive circuit may be connected to the array of electric field sensing electrodes for driving same. The sensor is preferably in the form of an integrated circuit and includes a substrate adjacent the array of fingerprint sensing elements.

Abstract: A wafer level hermetically packaged integrated circuit has a protective cover wafer bonded to a semiconductor device substrate wafer. The substrate wafer may contain a cavity. The cover wafer seals integrated circuits and other devices including but not limited to air bridge structures, resonant beams, surface acoustic wave (SAW) devices, trimmable resistors, and micromachines. Some devices, such as SAWs, are formed on the surface of cavities formed in the protective cover wafer. Die are separated to complete the process.

Abstract: A method is for making a chip package of a type including a carrier and a chip connected thereto using optical alignment techniques. One method includes the steps of: providing a transparent film having chip alignment and carrier alignment indicia thereon, optically detecting the chip through the transparent film and aligning the transparent film and the chip based upon the chip alignment indicia. Similarly, the method may include optically detecting the carrier through the transparent film and aligning the transparent film and the carrier based upon the carrier alignment indicia. In addition, the method further includes securing the chip, transparent film and carrier together, such as by providing a thermoplastic transparent film which may heated for adhesively securing the components. The transparent film may be a transparent z-axis conductive film, or a dielectric transparent film.

Abstract: An integrated circuit device, such as a fingerprint sensing device, includes an integrated circuit die, a body of encapsulating material surrounding the integrated circuit die and having an opening therein exposing a portion of the integrated circuit die, and an electrically conductive member or frame being mounted to the body of encapsulating material adjacent the opening therein. The electrically conductive member may preferably be positioned so as to define at least a portion of a frame for the opening in the body of encapsulating material. The electrically conductive member may be adhesively secured to the integrated circuit die. Accordingly, the adhesive and electrically conductive member may serve as a seal to the interface between the body of encapsulating material and the die. The electrically conductive member may define a frame that surrounds a body of removable material during an intermediate stage in manufacturing.